File: UniformTSDFVolume.cpp

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// ----------------------------------------------------------------------------
// -                        Open3D: www.open3d.org                            -
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// The MIT License (MIT)
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// Copyright (c) 2018-2021 www.open3d.org
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// Permission is hereby granted, free of charge, to any person obtaining a copy
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#include "open3d/pipelines/integration/UniformTSDFVolume.h"

#include <sstream>

#include "open3d/camera/PinholeCameraIntrinsic.h"
#include "open3d/data/Dataset.h"
#include "open3d/geometry/RGBDImage.h"
#include "open3d/io/ImageIO.h"
#include "open3d/utility/FileSystem.h"
#include "open3d/visualization/utility/DrawGeometry.h"
#include "tests/Tests.h"

namespace open3d {
namespace tests {

bool ReadPoses(const std::string& trajectory_path,
               std::vector<Eigen::Matrix4d>& poses) {
    FILE* f = utility::filesystem::FOpen(trajectory_path, "r");
    if (f == NULL) {
        utility::LogWarning("Read poses failed: unable to open file: {}",
                            trajectory_path);
        return false;
    }
    char line_buffer[DEFAULT_IO_BUFFER_SIZE];
    Eigen::Matrix4d pose;

    auto read_pose = [&pose, &line_buffer, f]() -> bool {
        // Read meta line
        if (!fgets(line_buffer, DEFAULT_IO_BUFFER_SIZE, f)) {
            return false;
        }
        // Read 4x4 matrix
        for (size_t row = 0; row < 4; ++row) {
            if (!fgets(line_buffer, DEFAULT_IO_BUFFER_SIZE, f)) {
                return false;
            }
            if (sscanf(line_buffer, "%lf %lf %lf %lf", &pose(row, 0),
                       &pose(row, 1), &pose(row, 2), &pose(row, 3)) != 4) {
                return false;
            }
        }
        return true;
    };

    while (read_pose()) {
        // Copy to poses
        poses.push_back(pose);
    }

    fclose(f);
    return true;
}

TEST(UniformTSDFVolume, Constructor) {
    double length = 4.0;
    int resolution = 128;
    double sdf_trunc = 0.04;
    auto color_type = pipelines::integration::TSDFVolumeColorType::RGB8;
    pipelines::integration::UniformTSDFVolume tsdf_volume(
            length, resolution, sdf_trunc,
            pipelines::integration::TSDFVolumeColorType::RGB8);

    // TSDFVolume base class attributes
    EXPECT_EQ(tsdf_volume.voxel_length_, length / resolution);
    EXPECT_EQ(tsdf_volume.sdf_trunc_, sdf_trunc);
    EXPECT_EQ(tsdf_volume.color_type_, color_type);

    // UniformTSDFVolume attributes
    ExpectEQ(tsdf_volume.origin_, Eigen::Vector3d(0, 0, 0));
    EXPECT_EQ(tsdf_volume.length_, length);
    EXPECT_EQ(tsdf_volume.resolution_, resolution);
    EXPECT_EQ(tsdf_volume.voxel_num_, resolution * resolution * resolution);
    EXPECT_EQ(int(tsdf_volume.voxels_.size()), tsdf_volume.voxel_num_);
}

TEST(UniformTSDFVolume, RealData) {
    // Poses
    data::SampleRedwoodRGBDImages redwood_data;
    std::string trajectory_path = redwood_data.GetOdometryLogPath();
    std::vector<Eigen::Matrix4d> poses;
    if (!ReadPoses(trajectory_path, poses)) {
        throw std::runtime_error("Cannot read trajectory file");
    }

    // Extrinsics
    std::vector<Eigen::Matrix4d> extrinsics;
    for (const auto& pose : poses) {
        extrinsics.push_back(pose.inverse());
    }

    // Intrinsics
    camera::PinholeCameraIntrinsic intrinsic(
            camera::PinholeCameraIntrinsicParameters::PrimeSenseDefault);

    // TSDF init
    pipelines::integration::UniformTSDFVolume tsdf_volume(
            4.0, 100, 0.04, pipelines::integration::TSDFVolumeColorType::RGB8);

    // Integrate RGBD frames
    for (size_t i = 0; i < poses.size(); ++i) {
        // Color
        geometry::Image im_color;
        io::ReadImage(redwood_data.GetColorPaths()[i], im_color);

        // Depth
        geometry::Image im_depth;
        io::ReadImage(redwood_data.GetDepthPaths()[i], im_depth);

        // Integrate
        std::shared_ptr<geometry::RGBDImage> im_rgbd =
                geometry::RGBDImage::CreateFromColorAndDepth(
                        im_color, im_depth, /*depth_scale*/ 1000.0,
                        /*depth_func*/ 4.0, /*convert_rgb_to_intensity*/ false);
        tsdf_volume.Integrate(*im_rgbd, intrinsic, extrinsics[i]);
    }

    // These hard-coded values are for unit test only. They are used to make
    // sure that after code refactoring, the numerical values still stay the
    // same. However, using different parameters or algorithmtic improvements
    // could invalidate these reference values. We use a custom threshold 0.1
    // to account for acccumulative floating point errors.

    // Extract mesh
    std::shared_ptr<geometry::TriangleMesh> mesh =
            tsdf_volume.ExtractTriangleMesh();
    EXPECT_EQ(mesh->vertices_.size(), 3198u);
    EXPECT_EQ(mesh->triangles_.size(), 4402u);
    Eigen::Vector3d color_sum(0, 0, 0);
    for (const Eigen::Vector3d& color : mesh->vertex_colors_) {
        color_sum += color;
    }
    ExpectEQ(color_sum, Eigen::Vector3d(2703.841944, 2561.480949, 2481.503805),
             /*threshold*/ 0.1);
    // Uncomment to visualize
    // visualization::DrawGeometries({mesh});

    // Extract point cloud
    std::shared_ptr<geometry::PointCloud> pcd = tsdf_volume.ExtractPointCloud();
    EXPECT_EQ(pcd->points_.size(), 2227u);
    EXPECT_EQ(pcd->colors_.size(), 2227u);
    color_sum << 0, 0, 0;
    for (const Eigen::Vector3d& color : pcd->colors_) {
        color_sum += color;
    }
    ExpectEQ(color_sum, Eigen::Vector3d(1877.673116, 1862.126057, 1862.190616),
             /*threshold*/ 0.1);
    Eigen::Vector3d normal_sum(0, 0, 0);
    for (const Eigen::Vector3d& normal : pcd->normals_) {
        normal_sum += normal;
    }
    ExpectEQ(normal_sum, Eigen::Vector3d(-161.569098, -95.969433, -1783.167177),
             /*threshold*/ 0.1);

    // Extract voxel cloud
    std::shared_ptr<geometry::PointCloud> voxel_pcd =
            tsdf_volume.ExtractVoxelPointCloud();
    EXPECT_EQ(voxel_pcd->points_.size(), 4488u);
    EXPECT_EQ(voxel_pcd->colors_.size(), 4488u);
    color_sum << 0, 0, 0;
    for (const Eigen::Vector3d& color : voxel_pcd->colors_) {
        color_sum += color;
    }
    ExpectEQ(color_sum, Eigen::Vector3d(2096.428416, 2096.428416, 2096.428416),
             /*threshold*/ 0.1);
}

}  // namespace tests
}  // namespace open3d