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Vision-and-Language Navigation in Continuous Environments using Habitat

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Vision-and-Language Navigation in Continuous Environments (VLN-CE)

Project WebsiteVLN-CE ChallengeRxR-Habitat Challenge

Official implementations:

  • Beyond the Nav-Graph: Vision-and-Language Navigation in Continuous Environments (paper)
  • Waypoint Models for Instruction-guided Navigation in Continuous Environments (paper, README)

Vision and Language Navigation in Continuous Environments (VLN-CE) is an instruction-guided navigation task with crowdsourced instructions, realistic environments, and unconstrained agent navigation. This repo is a launching point for interacting with the VLN-CE task and provides both baseline agents and training methods. Both the Room-to-Room (R2R) and the Room-Across-Room (RxR) datasets are supported. VLN-CE is implemented using the Habitat platform.

VLN-CE comparison to VLN

Setup

This project is developed with Python 3.6. If you are using miniconda or anaconda, you can create an environment:

conda create -n vlnce python=3.6
conda activate vlnce

VLN-CE uses Habitat-Sim 0.1.7 which can be built from source or installed from conda:

conda install -c aihabitat -c conda-forge habitat-sim=0.1.7 headless

Then install Habitat-Lab:

git clone --branch v0.1.7 [email protected]:facebookresearch/habitat-lab.git
cd habitat-lab
# installs both habitat and habitat_baselines
python -m pip install -r requirements.txt
python -m pip install -r habitat_baselines/rl/requirements.txt
python -m pip install -r habitat_baselines/rl/ddppo/requirements.txt
python setup.py develop --all

Now you can install VLN-CE:

git clone [email protected]:jacobkrantz/VLN-CE.git
cd VLN-CE
python -m pip install -r requirements.txt

Data

Scenes: Matterport3D

Matterport3D (MP3D) scene reconstructions are used. The official Matterport3D download script (download_mp.py) can be accessed by following the instructions on their project webpage. The scene data can then be downloaded:

# requires running with python 2.7
python download_mp.py --task habitat -o data/scene_datasets/mp3d/

Extract such that it has the form data/scene_datasets/mp3d/{scene}/{scene}.glb. There should be 90 scenes.

Episodes: Room-to-Room (R2R)

The R2R_VLNCE dataset is a port of the Room-to-Room (R2R) dataset created by Anderson et al for use with the Matterport3DSimulator (MP3D-Sim). For details on porting to 3D reconstructions, please see our paper. R2R_VLNCE_v1-3 is a minimal version of the dataset and R2R_VLNCE_v1-3_preprocessed runs baseline models out of the box. See the dataset page for format, contents, and a changelog. We encourage use of the most recent version (v1-3).

Dataset Extract path Size
R2R_VLNCE_v1-3.zip data/datasets/R2R_VLNCE_v1-3 3 MB
R2R_VLNCE_v1-3_preprocessed.zip data/datasets/R2R_VLNCE_v1-3_preprocessed 250 MB

Downloading via CLI:

# R2R_VLNCE_v1-3
gdown https://drive.google.com/uc?id=1T9SjqZWyR2PCLSXYkFckfDeIs6Un0Rjm
# R2R_VLNCE_v1-3_preprocessed
gdown https://drive.google.com/uc?id=1fo8F4NKgZDH-bPSdVU3cONAkt5EW-tyr
Encoder Weights

Baseline models encode depth observations using a ResNet pre-trained on PointGoal navigation. Those weights can be downloaded from here (672M). Extract the contents to data/ddppo-models/{model}.pth.

Episodes: Room-Across-Room (RxR)

Download: RxR_VLNCE_v0.zip

About the Room-Across-Room dataset (RxR):

  • multilingual instructions (English, Hindi, Telugu)
  • an order of magnitude larger than existing datasets
  • varied paths to break a shortest-path-to-goal assumption

RxR was ported to continuous environments originally for the RxR-Habitat Challenge. The dataset has train, val_seen, val_unseen, and test_challenge splits with both Guide and Follower trajectories ported. The starter code expects files in this structure:

data/datasets
├─ RxR_VLNCE_v0
|   ├─ train
|   |    ├─ train_guide.json.gz
|   |    ├─ train_guide_gt.json.gz
|   |    ├─ train_follower.json.gz
|   |    ├─ train_follower_gt.json.gz
|   ├─ val_seen
|   |    ├─ val_seen_guide.json.gz
|   |    ├─ val_seen_guide_gt.json.gz
|   |    ├─ val_seen_follower.json.gz
|   |    ├─ val_seen_follower_gt.json.gz
|   ├─ val_unseen
|   |    ├─ val_unseen_guide.json.gz
|   |    ├─ val_unseen_guide_gt.json.gz
|   |    ├─ val_unseen_follower.json.gz
|   |    ├─ val_unseen_follower_gt.json.gz
|   ├─ test_challenge
|   |    ├─ test_challenge_guide.json.gz
|   ├─ text_features
|   |    ├─ ...

The baseline models for RxR-Habitat use precomputed BERT instruction features which can be downloaded from here and saved to data/datasets/RxR_VLNCE_v0/text_features/rxr_{split}/{instruction_id}_{language}_text_features.npz.

RxR-Habitat Challenge

RxR Challenge Teaser GIF

NEW: The 2023 RxR-Habitat Challenge is live!

The RxR-Habitat is hosted at the CVPR 2023 Embodied AI workshop set for June 19th, 2023. The leaderboard opens for challenge submissions on March 1. For official guidelines, please visit: ai.google.com/research/rxr/habitat. We encourage submissions on this dificult task!

The RxR-Habitat Challenge is hosted by Oregon State University, Google Research, and Meta AI. This is the third year of the RxR-Habitat Challenge which previously appeared at the 2021 and 2022 CVPR EAI workshop.

Timeline

Event Date
Challenge Launch Mar 17, 2023
Leaderboard Open Mar 20, 2023
Leaderboard Closes May 15, 2023
Workshop and Winners Announcement Jun 19, 2023

Generating Submissions

Submissions are made by running an agent locally and submitting a jsonlines file (.jsonl) containing the agent's trajectories. Starter code for generating this file is provided in the function BaseVLNCETrainer.inference(). Here is an example of generating predictions for English using the Cross-Modal Attention baseline:

python run.py \
  --exp-config vlnce_baselines/config/rxr_baselines/rxr_cma_en.yaml \
  --run-type inference

If you use different models for different languages, you can merge their predictions with scripts/merge_inference_predictions.py. Submissions are only accepted that contain all episodes from all three languages in the test-challenge split. Starter code for this challenge was originally hosted in the rxr-habitat-challenge branch but is now integrated in master.

Required Task Configurations

As specified in the challenge webpage, submissions to the official challenge must have an action space of 30 degree turn angles, a 0.25m step size, and look up / look down actions of 30 degrees. The agent is given a 480x640 RGBD observation space. An example task configuration is given here which loads the English portion of the dataset.

The CMA baseline model (config) is an example of a valid submission. Existing waypoint models are not valid due to their panoramic observation space. Such models would need to be adapted to the challenge configuration.

Baseline Model

The official baseline for the RxR-Habitat Challenge is a monolingual cross-modal attention (CMA) model, labeled Monolingual CMA Baseline on the leaderboard. Configuration files for re-training or evaluating this model can be found in this folder under the name rxr_cma_{en|hi|te}.yaml. Weights for the pre-trained models: [en hi te] (196MB each).

Citing RxR-Habitat Challenge

To cite the challenge, please cite the following papers (RxR and VLN-CE):

@inproceedings{ku2020room,
  title={Room-Across-Room: Multilingual Vision-and-Language Navigation with Dense Spatiotemporal Grounding},
  author={Ku, Alexander and Anderson, Peter and Patel, Roma and Ie, Eugene and Baldridge, Jason},
  booktitle={Proceedings of the 2020 Conference on Empirical Methods in Natural Language Processing (EMNLP)},
  pages={4392--4412},
  year={2020}
}

@inproceedings{krantz_vlnce_2020,
  title={Beyond the Nav-Graph: Vision and Language Navigation in Continuous Environments},
  author={Jacob Krantz and Erik Wijmans and Arjun Majundar and Dhruv Batra and Stefan Lee},
  booktitle={European Conference on Computer Vision (ECCV)},
  year={2020}
 }

Questions?

Feel free to contact the challenge organizers with any questions, comments, or concerns. The corresponding organizer is Jacob Krantz (@jacobkrantz). You can also open an issue with [RxR-Habitat] in the title, which will also notify us.

VLN-CE Challenge (R2R Data)

The VLN-CE Challenge is live and taking submissions for public test set evaluation. This challenge uses the R2R data ported in the original VLN-CE paper.

To submit to the leaderboard, you must run your agent locally and submit a JSON file containing the generated agent trajectories. Starter code for generating this JSON file is provided in the function BaseVLNCETrainer.inference(). Here is an example of generating this file using the pretrained Cross-Modal Attention baseline:

python run.py \
  --exp-config vlnce_baselines/config/r2r_baselines/test_set_inference.yaml \
  --run-type inference

Predictions must be in a specific format. Please visit the challenge webpage for guidelines.

Baseline Performance

The baseline model for the VLN-CE task is the cross-modal attention model trained with progress monitoring, DAgger, and augmented data (CMA_PM_DA_Aug). As evaluated on the leaderboard, this model achieves:

Split TL NE OS SR SPL
Test 8.85 7.91 0.36 0.28 0.25
Val Unseen 8.27 7.60 0.36 0.29 0.27
Val Seen 9.06 7.21 0.44 0.34 0.32

This model was originally presented with a val_unseen performance of 0.30 SPL, however the leaderboard evaluates this same model at 0.27 SPL. The model was trained and evaluated on a hardware + Habitat build that gave slightly different results, as is the case for the other paper experiments. Going forward, the leaderboard contains the performance metrics that should be used for official comparison. In our tests, the installation procedure for this repo gives nearly identical evaluation to the leaderboard, but we recognize that compute hardware along with the version and build of Habitat are factors to reproducibility.

For push-button replication of all VLN-CE experiments, see here.

Starter Code

The run.py script controls training and evaluation for all models and datasets:

python run.py \
  --exp-config path/to/experiment_config.yaml \
  --run-type {train | eval | inference}

For example, a random agent can be evaluated on 10 val-seen episodes of R2R using this command:

python run.py --exp-config vlnce_baselines/config/r2r_baselines/nonlearning.yaml --run-type eval

For lists of modifiable configuration options, see the default task config and experiment config files.

Training Agents

The DaggerTrainer class is the standard trainer and supports teacher forcing or dataset aggregation (DAgger). This trainer saves trajectories consisting of RGB, depth, ground-truth actions, and instructions to disk to avoid time spent in simulation.

The RecollectTrainer class performs teacher forcing using the ground truth trajectories provided in the dataset rather than a shortest path expert. Also, this trainer does not save episodes to disk, instead opting to recollect them in simulation.

Both trainers inherit from BaseVLNCETrainer.

Evaluating Agents

Evaluation on validation splits can be done by running python run.py --exp-config path/to/experiment_config.yaml --run-type eval. If EVAL.EPISODE_COUNT == -1, all episodes will be evaluated. If EVAL_CKPT_PATH_DIR is a directory, each checkpoint will be evaluated one at a time.

Cuda

Cuda will be used by default if it is available. We find that one GPU for the model and several GPUs for simulation is favorable.

SIMULATOR_GPU_IDS: [0]  # list of GPU IDs to run simulations
TORCH_GPU_ID: 0  # GPU for pytorch-related code (the model)
NUM_ENVIRONMENTS: 1  # Each GPU runs NUM_ENVIRONMENTS environments

The simulator and torch code do not need to run on the same device. For faster training and evaluation, we recommend running with as many NUM_ENVIRONMENTS as will fit on your GPU while assuming 1 CPU core per env.

License

The VLN-CE codebase is MIT licensed. Trained models and task datasets are considered data derived from the mp3d scene dataset. Matterport3D based task datasets and trained models are distributed with Matterport3D Terms of Use and under CC BY-NC-SA 3.0 US license.

Citing

If you use VLN-CE in your research, please cite the following paper:

@inproceedings{krantz_vlnce_2020,
  title={Beyond the Nav-Graph: Vision and Language Navigation in Continuous Environments},
  author={Jacob Krantz and Erik Wijmans and Arjun Majundar and Dhruv Batra and Stefan Lee},
  booktitle={European Conference on Computer Vision (ECCV)},
  year={2020}
 }

If you use the RxR-Habitat data, please additionally cite the following paper:

@inproceedings{ku2020room,
  title={Room-Across-Room: Multilingual Vision-and-Language Navigation with Dense Spatiotemporal Grounding},
  author={Ku, Alexander and Anderson, Peter and Patel, Roma and Ie, Eugene and Baldridge, Jason},
  booktitle={Proceedings of the 2020 Conference on Empirical Methods in Natural Language Processing (EMNLP)},
  pages={4392--4412},
  year={2020}
}