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Matterport3D Simulator

AI Research Platform for Reinforcement Learning from Real Panoramic Images.

The Matterport3D Simulator enables development of AI agents that interact with real 3D environments using visual information (RGB-D images). It is primarily intended for research in deep reinforcement learning, at the intersection of computer vision, natural language processing and robotics.

Concept

Visit the main website to view a demo.

NEW February 2019: We have released several updates. The simulator is now dockerized, it supports batches of agents instead of just a single agent, and it is far more efficient (faster) than before. Also, it now outputs depth maps as well as RGB images. As a consequence, there are some changes to the original API (mainly, all inputs and outputs are now batched). Therefore, to mark the first release we have tagged it as v0.1 for any users that don't want to change to the new version.

Features

Reference

The Matterport3D Simulator and the Room-to-Room (R2R) navigation dataset are described in:

If you use the simulator or our dataset, please cite our paper (CVPR 2018 spotlight oral):

Bibtex:

@inproceedings{mattersim,
  title={{Vision-and-Language Navigation}: Interpreting visually-grounded navigation instructions in real environments},
  author={Peter Anderson and Qi Wu and Damien Teney and Jake Bruce and Mark Johnson and Niko S{\"u}nderhauf and Ian Reid and Stephen Gould and Anton van den Hengel},
  booktitle={Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR)},
  year={2018}
}

Simulator Data

Matterport3D Simulator is based on densely sampled 360-degree indoor RGB-D images from the Matterport3D dataset. The dataset consists of 90 different indoor environments, including homes, offices, churches and hotels. Each environment contains full 360-degree RGB-D scans from between 8 and 349 viewpoints, spread on average 2.25m apart throughout the entire walkable floorplan of the scene.

Actions

At each viewpoint location, the agent can pan and elevate the camera. The agent can also choose to move between viewpoints. The precise details of the agent's observations and actions are described below and in the paper.

Room-to-Room (R2R) Navigation Task

The simulator includes the training data and evaluation metrics for the Room-to-Room (R2R) Navigation task, which requires an autonomous agent to follow a natural language navigation instruction to navigate to a goal location in a previously unseen building. Please refer to specific instructions to setup and run this task. There is a test server and leaderboard available at EvalAI.

Installation / Build Instructions

We recommend using our Dockerfile to install the simulator. The simulator can also be built without docker but satisfying the project dependencies may be more difficult.

Prerequisites

Clone Repo

Clone the Matterport3DSimulator repository:

# Make sure to clone with --recursive
git clone --recursive https://github.com/peteanderson80/Matterport3DSimulator.git
cd Matterport3DSimulator

If you didn't clone with the --recursive flag, then you'll need to manually clone the pybind submodule from the top-level directory:

git submodule update --init --recursive

Dataset Download

To use the simulator you must first download the Matterport3D Dataset which is available after requesting access here. The download script that will be provided allows for downloading of selected data types. At minimum you must download the matterport_skybox_images. If you wish to use depth outputs then also download undistorted_depth_images and undistorted_camera_parameters.

Set an environment variable to the location of the unzipped dataset, where <PATH> is the full absolute path (not a relative path or symlink) to the directory containing the individual matterport scan directories (17DRP5sb8fy, 2t7WUuJeko7, etc):

export MATTERPORT_DATA_DIR=<PATH>

Note that if <PATH> is a remote sshfs mount, you will need to mount it with the -o allow_root option or the docker container won't be able to access this directory.

Building using Docker

Build the docker image:

docker build -t mattersim:9.2-devel-ubuntu18.04 .

Run the docker container, mounting both the git repo and the dataset:

nvidia-docker run -it --mount type=bind,source=$MATTERPORT_DATA_DIR,target=/root/mount/Matterport3DSimulator/data/v1/scans --volume `pwd`:/root/mount/Matterport3DSimulator mattersim:9.2-devel-ubuntu18.04

Now (from inside the docker container), build the simulator code:

cd /root/mount/Matterport3DSimulator
mkdir build && cd build
cmake -DEGL_RENDERING=ON ..
make
cd ../

Rendering Options (GPU, CPU, off-screen)

Note that there are three rendering options, which are selected using cmake options during the build process (by varying line 3 in the build commands immediately above):

The recommended (fast) approach for training agents is using off-screen GPU rendering (EGL).

Dataset Preprocessing

To make data loading faster and to reduce memory usage we preprocess the matterport_skybox_images by downscaling and combining all cube faces into a single image. While still inside the docker container, run the following script:

./scripts/downsize_skybox.py

This will take a while depending on the number of processes used (which is a setting in the script).

After completion, the matterport_skybox_images subdirectories in the dataset will contain image files with filename format <PANO_ID>_skybox_small.jpg. By default images are downscaled by 50% and 20 processes are used.

Depth Outputs

If you need depth outputs as well as RGB (via sim.setDepthEnabled(True)), precompute matching depth skybox images by running this script:

./scripts/depth_to_skybox.py

Depth skyboxes are generated from the undistorted_depth_images using a simple blending approach. As the depth images contain many missing values (corresponding to shiny, bright, transparent, and distant surfaces, which are common in the dataset) we apply a simple crossbilateral filter based on the NYUv2 code to fill all but the largest holes. A couple of things to keep in mind:

Running Tests

Now (still from inside the docker container), run the unit tests:

./build/tests ~Timing

Assuming all tests pass, sim_imgs will now contain some test images rendered by the simulator. You may also wish to test the rendering frame rate. The following command will try to load all the Matterport environments into memory (requiring around 50 GB memory), and then some information about the rendering frame rate (at 640x480 resolution, RGB outputs only) will be printed to stdout:

./build/tests Timing

The timing test must be run individually from the other tests to get accurate results. Not that the Timing test will fail if there is insufficient memory. As long as all the other tests pass (i.e., ./build/tests ~Timing) then the install is good. Refer to the Catch documentation for unit test configuration options.

Now exit the docker container:

exit

Interactive Demo

To run an interactive demo, after completing the Installation / Build Instructions above, run the docker container while sharing the host's X server and DISPLAY environment variable with the container:

xhost +
nvidia-docker run -it -e DISPLAY -v /tmp/.X11-unix:/tmp/.X11-unix --mount type=bind,source=$MATTERPORT_DATA_DIR,target=/root/mount/Matterport3DSimulator/data/v1/scans,readonly --volume `pwd`:/root/mount/Matterport3DSimulator mattersim:9.2-devel-ubuntu18.04
cd /root/mount/Matterport3DSimulator

If you get an error like Error: BadShmSeg (invalid shared segment parameter) 128 you may also need to include -e="QT_X11_NO_MITSHM=1" in the docker run command above.

Commands for running both python and C++ demos are provided below. These are very simple demos designed to illustrate the use of the simulator in python and C++. By default, these demos have depth rendering off. Check the code and turn it on if you have preprocessed the depth outputs and want to see depth as well (see Depth Outputs above). These demos should work regardless of which rendering option was used when building the simulator.

Python demo:

python3 src/driver/driver.py

C++ demo:

build/mattersim_main

The javascript code in the web directory can also be used as an interactive demo, or to generate videos from the simulator in first-person view, or as an interface on Amazon Mechanical Turk to collect natural language instruction data.

Building without Docker

The simulator can be built outside of a docker container using the cmake build commands described above. However, this is not the recommended approach, as all dependencies will need to be installed locally and may conflict with existing libraries. The main requirements are:

Optional dependences (depending on the cmake rendering options):

The provided Dockerfile contains install commands for most of these libraries. For example, to install OpenGL and related libraries:

sudo apt-get install libjsoncpp-dev libepoxy-dev libglm-dev libosmesa6 libosmesa6-dev libglew-dev

Simulator API

The simulator API in Python exactly matches the extensively commented MatterSim.hpp C++ header file, but using python lists in place of C++ std::vectors etc. In general, there are various functions beginning with set that set the agent and simulator configuration (such as batch size, rendering parameters, enabling depth output etc). For training agents, we recommend setting setPreloadingEnabled(True), setBatchSize(X) and setCacheSize(2X), where X is the desired batch size, e.g.:

import MatterSim
sim = MatterSim.Simulator()
sim.setCameraResolution(640, 480)
sim.setPreloadingEnabled(True)
sim.setDepthEnabled(True)
sim.setBatchSize(100)
sim.setCacheSize(200) # cacheSize 200 uses about 1.2GB of GPU memory for caching pano textures

When preloading is enabled, all the pano images will be loaded into memory before starting. Preloading takes several minutes and requires around 50G memory for RGB output (about 80G if depth output is enabled), but rendering is much faster.

To start the simulator, call initialize followed by the newEpisode function, which takes as arguments a list of scanIds, a list of viewpoint ids, a list of headings (in radians), and a list of camera elevations (in radians), e.g.:

sim.initialize()
# Assuming batchSize = 1
sim.newEpisode(['2t7WUuJeko7'], ['1e6b606b44df4a6086c0f97e826d4d15'], [0], [0])

Heading is defined from the y-axis with the z-axis up (turning right is positive). Camera elevation is measured from the horizon defined by the x-y plane (up is positive). There is also a newRandomEpisode function which only requires a list of scanIds, and randomly determines a viewpoint and heading (with zero camera elevation).

Interaction with the simulator is through the makeAction function, which takes as arguments a list of navigable location indices, a list of heading changes (in radians) and a list of elevation changes (in radians). The navigable location indices select which nearby camera viewpoint the agent should move to. By default, only camera viewpoints that are within the agent's current field of view are considered navigable, unless restricted navigation is turned off (i.e., the agent can't move backwards, for example). For agent n, navigable locations are given by getState()[n].navigableLocations. Index 0 always contains the current viewpoint (i.e., the agent always has the option to stay in the same place). As the navigation graph is irregular, the remaining viewpoints are sorted by their angular distance from the centre of the image, so index 1 (if available) will approximate moving directly forward. For example, to turn 30 degrees left without moving (keeping camera elevation unchanged):

sim.makeAction([0], [-0.523599], [0])

At any time the simulator state can be returned by calling getState. The returned state contains a list of objects (one for each agent in the batch), with attributes as in the following example:

[
  {
    "scanId" : "2t7WUuJeko7"  // Which building the agent is in
    "step" : 5,               // Number of frames since the last newEpisode() call
    "rgb" : <image>,          // 8 bit image (in BGR channel order), access with np.array(rgb, copy=False)
    "depth" : <image>,        // 16 bit single-channel image containing the pixel's distance in the z-direction from the camera center 
                              // (not the euclidean distance from the camera center), 0.25 mm per value (divide by 4000 to get meters). 
                              // A zero value denotes 'no reading'. Access with np.array(depth, copy=False)
    "location" : {            // The agent's current 3D location
        "viewpointId" : "1e6b606b44df4a6086c0f97e826d4d15",  // Viewpoint identifier
        "ix" : 5,                                            // Viewpoint index, used by simulator
        "x" : 3.59775996208,                                 // 3D position in world coordinates
        "y" : -0.837355971336,
        "z" : 1.68884003162,
        "rel_heading" : 0,                                   // Robot relative coords to this location
        "rel_elevation" : 0,
        "rel_distance" : 0
    }
    "heading" : 3.141592,     // Agent's current camera heading in radians
    "elevation" : 0,          // Agent's current camera elevation in radians
    "viewIndex" : 0,          // Index of the agent's current viewing angle [0-35] (only valid with discretized viewing angles)
                              // [0-11] is looking down, [12-23] is looking at horizon, is [24-35] looking up
    "navigableLocations": [   // List of viewpoints you can move to. Index 0 is always the current viewpoint, i.e. don't move.
        {                     // The remaining valid viewpoints are sorted by their angular distance from the image centre.
            "viewpointId" : "1e6b606b44df4a6086c0f97e826d4d15",  // Viewpoint identifier
            "ix" : 5,                                            // Viewpoint index, used by simulator
            "x" : 3.59775996208,                                 // 3D position in world coordinates
            "y" : -0.837355971336,
            "z" : 1.68884003162,
            "rel_heading" : 0,                                   // Robot relative coords to this location
            "rel_elevation" : 0,
            "rel_distance" : 0
        },
        {
            "viewpointId" : "1e3a672fa1d24d668866455162e5b58a",  // Viewpoint identifier
            "ix" : 14,                                           // Viewpoint index, used by simulator
            "x" : 4.03619003296,                                 // 3D position in world coordinates
            "y" : 1.11550998688,
            "z" : 1.65892004967,
            "rel_heading" : 0.220844170027,                      // Robot relative coords to this location
            "rel_elevation" : -0.0149478448723,
            "rel_distance" : 2.00169944763
        },
        {...}
    ]
  }
]

Refer to src/driver/driver.py for example usage. To build html docs for C++ classes in the doxygen directory, run this command and navigate in your browser to doxygen/html/index.html:

doxygen

Precomputing ResNet Image Features

In our initial work using this simulator, we discretized heading and elevation into 30 degree increments, and precomputed image features for each view. Now that the simulator is much faster, this is no longer necessary, but for completeness we include the details of this setting below.

We generate image features using Caffe. To replicate our approach, first download and save some Caffe ResNet-152 weights into the models directory. We experiment with weights pretrained on ImageNet, and also weights finetuned on the Places365 dataset. The script scripts/precompute_features.py can then be used to precompute ResNet-152 features. Features are saved in tsv format in the img_features directory.

Alternatively, skip the generation and just download and extract our tsv files into the img_features directory:

Directory Structure

Other directories are mostly self-explanatory.

License

The Matterport3D dataset, and data derived from it, is released under the Matterport3D Terms of Use. Our code is released under the MIT license.

Acknowledgements

We would like to thank Matterport for allowing the Matterport3D dataset to be used by the academic community. This project is supported by a Facebook ParlAI Research Award and by the Australian Centre for Robotic Vision.

Contributing

We welcome contributions from the community. All submissions require review and in most cases would require tests.