pxmlw6n2f/Gazebo_Distributed_TCP/test/integration/gpu_laser.cc

/*
 * Copyright (C) 2012 Open Source Robotics Foundation
 *
 * 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.
 *
*/

#include "gazebo/test/ServerFixture.hh"
#include "gazebo/sensors/sensors.hh"

#define LASER_TOL 1e-4
#define DOUBLE_TOL 1e-6

// vertical range values seem to be less accurate
#define VERTICAL_LASER_TOL 1e-3

using namespace gazebo;
class GPURaySensorTest : public ServerFixture
{
};

void OnNewLaserFrame(int *_scanCounter, float *_scanDest,
                  const float *_scan,
                  unsigned int _width, unsigned int _height,
                  unsigned int _depth,
                  const std::string &/*_format*/)
{
  memcpy(_scanDest, _scan, _width * _height * _depth);
  *_scanCounter += 1;
}

/////////////////////////////////////////////////
/// \brief Test GPU ray sensor range values,
/// Adapted from LaserUnitBox test in laser.cc
TEST_F(GPURaySensorTest, LaserUnitBox)
{
  // Test GPU ray sensors with 3 boxes in the world.
  // First GPU ray sensor at identity orientation, second at 90 degree roll
  // First place 2 of 3 boxes within range and verify range values.
  // then move all 3 boxes out of range and verify range values
  Load("worlds/empty_test.world");

  // Make sure the render engine is available.
  if (rendering::RenderEngine::Instance()->GetRenderPathType() ==
      rendering::RenderEngine::NONE)
  {
    gzerr << "No rendering engine, unable to run gpu laser test\n";
    return;
  }

  std::string modelName = "gpu_ray_model";
  std::string raySensorName = "gpu_ray_sensor";
  double hMinAngle = -M_PI/2.0;
  double hMaxAngle = M_PI/2.0;
  double minRange = 0.1;
  double maxRange = 5.0;
  double rangeResolution = 0.02;
  unsigned int samples = 320;
  math::Pose testPose(math::Vector3(0, 0, 0.1),
      math::Quaternion(0, 0, 0));

  // Spawn another gpu ray sensor at 90 degree roll
  std::string modelName2 = "gpu_ray_model_roll";
  std::string raySensorName2 = "gpu_ray_sensor_roll";
  math::Pose testPose2(math::Vector3(0, 0, 0.1),
      math::Quaternion(M_PI/2.0, 0, 0));

  SpawnGpuRaySensor(modelName, raySensorName, testPose.pos,
      testPose.rot.GetAsEuler(), hMinAngle, hMaxAngle, minRange, maxRange,
      rangeResolution, samples);

  SpawnGpuRaySensor(modelName2, raySensorName2, testPose2.pos,
      testPose2.rot.GetAsEuler(), hMinAngle, hMaxAngle, minRange, maxRange,
      rangeResolution, samples);

  std::string box01 = "box_01";
  std::string box02 = "box_02";
  std::string box03 = "box_03";

  physics::WorldPtr world = physics::get_world("default");
  ASSERT_TRUE(world != NULL);
  world->GetPhysicsEngine()->SetGravity(math::Vector3(0, 0, 0));

  // box in front of ray sensor 1 and 2
  math::Pose box01Pose(math::Vector3(1, 0, 0.5), math::Quaternion(0, 0, 0));
  // box on the right of ray sensor 1
  math::Pose box02Pose(math::Vector3(0, -1, 0.5), math::Quaternion(0, 0, 0));
  // box on the left of the ray sensor 1 but out of range
  math::Pose box03Pose(math::Vector3(0, maxRange + 1, 0.5),
      math::Quaternion(0, 0, 0));

  SpawnBox(box01, math::Vector3(1, 1, 1), box01Pose.pos,
      box01Pose.rot.GetAsEuler());

  SpawnBox(box02, math::Vector3(1, 1, 1), box02Pose.pos,
      box02Pose.rot.GetAsEuler());

  SpawnBox(box03, math::Vector3(1, 1, 1), box03Pose.pos,
      box03Pose.rot.GetAsEuler());

  sensors::SensorPtr sensor = sensors::get_sensor(raySensorName);
  sensors::GpuRaySensorPtr raySensor =
    std::dynamic_pointer_cast<sensors::GpuRaySensor>(sensor);

  sensors::SensorPtr sensor2 = sensors::get_sensor(raySensorName2);
  sensors::GpuRaySensorPtr raySensor2 =
    std::dynamic_pointer_cast<sensors::GpuRaySensor>(sensor2);

  // Make sure the above dynamic cast worked.
  EXPECT_TRUE(raySensor != NULL);
  EXPECT_TRUE(raySensor2 != NULL);

  raySensor->SetActive(true);
  raySensor2->SetActive(true);

  // Verify ray sensor 1 range readings
  // listen to new laser frames
  float *scan = new float[raySensor->RayCount()
      * raySensor->VerticalRayCount() * 3];
  int scanCount = 0;
  event::ConnectionPtr c =
    raySensor->ConnectNewLaserFrame(
        std::bind(&::OnNewLaserFrame, &scanCount, scan,
          std::placeholders::_1, std::placeholders::_2, std::placeholders::_3,
          std::placeholders::_4, std::placeholders::_5));

  // wait for a few laser scans
  int i = 0;
  while (scanCount < 10 && i < 300)
  {
    common::Time::MSleep(10);
    i++;
  }
  EXPECT_LT(i, 300);

  int mid = samples / 2;
  double unitBoxSize = 1.0;
  double expectedRangeAtMidPoint = box01Pose.pos.x - unitBoxSize/2;

  // ray sensor 1 should see box01 and box02
  EXPECT_NEAR(raySensor->Range(mid), expectedRangeAtMidPoint, LASER_TOL);
  EXPECT_NEAR(raySensor->Range(0), expectedRangeAtMidPoint, LASER_TOL);

  EXPECT_DOUBLE_EQ(raySensor->Range(samples-1), GZ_DBL_INF);

  // Verify ray sensor 2 range readings
  // listen to new laser frames
  float *scan2 = new float[raySensor2->RayCount()
      * raySensor2->VerticalRayCount() * 3];
  int scanCount2 = 0;
  event::ConnectionPtr c2 =
    raySensor->ConnectNewLaserFrame(
        std::bind(&::OnNewLaserFrame, &scanCount2, scan2,
          std::placeholders::_1, std::placeholders::_2, std::placeholders::_3,
          std::placeholders::_4, std::placeholders::_5));

  // wait for a few laser scans
  i = 0;
  scanCount2 = 0;
  while (scanCount2 < 10 && i < 300)
  {
    common::Time::MSleep(10);
    i++;
  }
  EXPECT_LT(i, 300);

  // Only box01 should be visible to ray sensor 2
  EXPECT_NEAR(raySensor2->Range(mid), expectedRangeAtMidPoint, LASER_TOL);
  EXPECT_DOUBLE_EQ(raySensor2->Range(0), GZ_DBL_INF);
  EXPECT_DOUBLE_EQ(raySensor->Range(samples-1), GZ_DBL_INF);

  // Move all boxes out of range
  world->GetModel(box01)->SetWorldPose(
      math::Pose(math::Vector3(maxRange + 1, 0, 0), math::Quaternion(0, 0, 0)));
  world->GetModel(box02)->SetWorldPose(
      math::Pose(math::Vector3(0, -(maxRange + 1), 0),
      math::Quaternion(0, 0, 0)));

  // wait for a few more laser scans
  i = 0;
  scanCount = 0;
  scanCount2 = 0;
  while ((scanCount < 10 ||scanCount2 < 10) && i < 300)
  {
    common::Time::MSleep(10);
    i++;
  }
  EXPECT_LT(i, 300);

  for (int i = 0; i < raySensor->RayCount(); ++i)
    EXPECT_DOUBLE_EQ(raySensor->Range(i), GZ_DBL_INF);

  for (int i = 0; i < raySensor->RayCount(); ++i)
    EXPECT_DOUBLE_EQ(raySensor2->Range(i), GZ_DBL_INF);

  raySensor->DisconnectNewLaserFrame(c);
  raySensor2->DisconnectNewLaserFrame(c2);

  delete [] scan;
  delete [] scan2;
}

/////////////////////////////////////////////////
/// \brief Spawn multiple GPU ray sensors with same name.
/// Verify that it doesn't crash.
TEST_F(GPURaySensorTest, NameCollision)
{
  // Test GPU ray sensors with 3 boxes in the world.
  // First GPU ray sensor at identity orientation, second at 90 degree roll
  // First place 2 of 3 boxes within range and verify range values.
  // then move all 3 boxes out of range and verify range values
  Load("worlds/empty_test.world");

  // Make sure the render engine is available.
  if (rendering::RenderEngine::Instance()->GetRenderPathType() ==
      rendering::RenderEngine::NONE)
  {
    gzerr << "No rendering engine, unable to run gpu laser test\n";
    return;
  }

  std::string modelName = "gpu_ray_model";
  std::string raySensorName = "gpu_ray_sensor";
  double hMinAngle = -M_PI/2.0;
  double hMaxAngle = M_PI/2.0;
  double minRange = 0.1;
  double maxRange = 5.0;
  double rangeResolution = 0.02;
  unsigned int samples = 320;
  math::Pose testPose(math::Vector3(0, 0, 0.1),
      math::Quaternion(0, 0, 0));

  // Spawn another gpu ray sensor at 90 degree roll
  std::string modelName2 = "gpu_ray_model_roll";
  std::string raySensorName2 = "gpu_ray_sensor";
  math::Pose testPose2(math::Vector3(0, 0, 0.1),
      math::Quaternion(M_PI/2.0, 0, 0));

  SpawnGpuRaySensor(modelName, raySensorName, testPose.pos,
      testPose.rot.GetAsEuler(), hMinAngle, hMaxAngle, minRange, maxRange,
      rangeResolution, samples);

  SpawnGpuRaySensor(modelName2, raySensorName2, testPose2.pos,
      testPose2.rot.GetAsEuler(), hMinAngle, hMaxAngle, minRange, maxRange,
      rangeResolution, samples);

  std::string box01 = "box_01";
  std::string box02 = "box_02";
  std::string box03 = "box_03";

  physics::WorldPtr world = physics::get_world("default");
  ASSERT_TRUE(world != NULL);
  world->GetPhysicsEngine()->SetGravity(math::Vector3(0, 0, 0));

  // box in front of ray sensor 1 and 2
  math::Pose box01Pose(math::Vector3(1, 0, 0.5), math::Quaternion(0, 0, 0));
  // box on the right of ray sensor 1
  math::Pose box02Pose(math::Vector3(0, -1, 0.5), math::Quaternion(0, 0, 0));
  // box on the left of the ray sensor 1 but out of range
  math::Pose box03Pose(math::Vector3(0, maxRange + 1, 0.5),
      math::Quaternion(0, 0, 0));

  SpawnBox(box01, math::Vector3(1, 1, 1), box01Pose.pos,
      box01Pose.rot.GetAsEuler());

  SpawnBox(box02, math::Vector3(1, 1, 1), box02Pose.pos,
      box02Pose.rot.GetAsEuler());

  SpawnBox(box03, math::Vector3(1, 1, 1), box03Pose.pos,
      box03Pose.rot.GetAsEuler());

  sensors::SensorPtr sensor = sensors::get_sensor(raySensorName);
  sensors::GpuRaySensorPtr raySensor =
    std::dynamic_pointer_cast<sensors::GpuRaySensor>(sensor);

  sensors::SensorPtr sensor2 = sensors::get_sensor(raySensorName2);
  sensors::GpuRaySensorPtr raySensor2 =
    std::dynamic_pointer_cast<sensors::GpuRaySensor>(sensor2);

  // Make sure the above dynamic cast worked.
  EXPECT_TRUE(raySensor != NULL);
  EXPECT_TRUE(raySensor2 != NULL);
}

/////////////////////////////////////////////////
/// \brief Test GPU ray sensor interaction with terrain
TEST_F(GPURaySensorTest, Heightmap)
{
  Load("worlds/gpu_laser_heightmap.world");

  // Make sure the render engine is available.
  if (rendering::RenderEngine::Instance()->GetRenderPathType() ==
      rendering::RenderEngine::NONE)
  {
    gzerr << "No rendering engine, unable to run gpu laser test\n";
    return;
  }

  // Get a pointer to the gpu laser sensor
  std::string gpuLaserName = "gpu_laser_sensor";
  int t = 0;
  while (sensors::get_sensor(gpuLaserName) == NULL && t < 100)
  {
    common::Time::MSleep(100);
    ++t;
  }
  ASSERT_LT(t, 100);
  sensors::SensorPtr sensor = sensors::get_sensor(gpuLaserName);
  sensors::GpuRaySensorPtr raySensor =
    std::dynamic_pointer_cast<sensors::GpuRaySensor>(sensor);

  EXPECT_TRUE(raySensor != NULL);

  // listen to new laser frames
  float *scan = new float[raySensor->RayCount()
      * raySensor->VerticalRayCount() * 3];
  int scanCount = 0;
  event::ConnectionPtr c =
    raySensor->ConnectNewLaserFrame(
        std::bind(&::OnNewLaserFrame, &scanCount, scan,
          std::placeholders::_1, std::placeholders::_2, std::placeholders::_3,
          std::placeholders::_4, std::placeholders::_5));

  // wait for a few laser scans
  int i = 0;
  while (scanCount < 10 && i < 300)
  {
    common::Time::MSleep(10);
    i++;
  }
  EXPECT_LT(i, 300);

  // Verify initial laser range readings. Nothing should be intersecting
  double maxRange = 10;
  EXPECT_NEAR(raySensor->RangeMax(), maxRange, LASER_TOL);

  for (int i = 0; i < raySensor->RayCount(); ++i)
    EXPECT_DOUBLE_EQ(raySensor->Range(i), GZ_DBL_INF);

  // Move laser model very close to terrain, it should now returns range values
  // that are less than half the max range
  std::string gpuLaserModelName = "gpu_laser";
  physics::WorldPtr world = physics::get_world("default");
  ASSERT_TRUE(world != NULL);
  world->GetModel(gpuLaserModelName)->SetWorldPose(
      math::Pose(math::Vector3(13.2, 0, 0.035), math::Quaternion(0, 0, 0)));

  // wait for a few laser scans
  i = 0;
  scanCount = 0;
  while (scanCount < 10 && i < 300)
  {
    common::Time::MSleep(10);
    i++;
  }
  EXPECT_LT(i, 300);

  for (int i = 0; i < raySensor->RayCount(); ++i)
    EXPECT_TRUE(raySensor->Range(i) < maxRange / 2.0);

  raySensor->DisconnectNewLaserFrame(c);

  delete [] scan;
}

/////////////////////////////////////////////////
/// \brief Test GPU ray sensor vertical component
TEST_F(GPURaySensorTest, LaserVertical)
{
  // issue #946
  #ifdef __APPLE__
    return;
  #endif

  // Test a ray sensor that has a vertical range component.
  // Place a box within range and verify range values,
  // then move the box out of range and verify range values

  Load("worlds/empty_test.world");

  // Make sure the render engine is available.
  if (rendering::RenderEngine::Instance()->GetRenderPathType() ==
      rendering::RenderEngine::NONE)
  {
    gzerr << "No rendering engine, unable to run gpu laser test\n";
    return;
  }

  std::string modelName = "gpu_ray_model";
  std::string raySensorName = "gpu_ray_sensor";
  double hMinAngle = -M_PI/4.0;
  double hMaxAngle = M_PI/4.0;
  double vMinAngle = -M_PI/4.0;
  double vMaxAngle = M_PI/4.0;
  double minRange = 0.1;
  double maxRange = 5.0;
  double rangeResolution = 0.02;
  unsigned int samples = 640;
  unsigned int vSamples = 25;
  double vAngleStep = (vMaxAngle - vMinAngle) / (vSamples-1);
  ignition::math::Pose3d testPose(ignition::math::Vector3d(0.25, 0, 0.5),
      ignition::math::Quaterniond::Identity);

  SpawnGpuRaySensorVertical(modelName, raySensorName, testPose.Pos(),
      testPose.Rot().Euler(), hMinAngle, hMaxAngle, vMinAngle, vMaxAngle,
      minRange, maxRange, rangeResolution, samples, vSamples, 1, 1);

  sensors::SensorPtr sensor = sensors::get_sensor(raySensorName);
  sensors::GpuRaySensorPtr raySensor =
    std::dynamic_pointer_cast<sensors::GpuRaySensor>(sensor);

  EXPECT_TRUE(raySensor != nullptr);

  physics::WorldPtr world = physics::get_world("default");
  ASSERT_TRUE(world != nullptr);
  world->GetPhysicsEngine()->SetGravity(ignition::math::Vector3d::Zero);

  std::string box01 = "box_01";

  // box in front of ray sensor
  ignition::math::Pose3d box01Pose(ignition::math::Vector3d(1, 0, 0.5),
      ignition::math::Quaterniond::Identity);

  SpawnBox(box01, ignition::math::Vector3d::One, box01Pose.Pos(),
      box01Pose.Rot().Euler());

  raySensor->SetActive(true);

  float *scan = new float[raySensor->RayCount()
      * raySensor->VerticalRayCount() * 3];
  int scanCount = 0;
  event::ConnectionPtr c =
    raySensor->ConnectNewLaserFrame(
        std::bind(&::OnNewLaserFrame, &scanCount, scan,
          std::placeholders::_1, std::placeholders::_2, std::placeholders::_3,
          std::placeholders::_4, std::placeholders::_5));

  // wait for a few laser scans
  int iter = 0;
  while (scanCount < 10 && iter < 600)
  {
    common::Time::MSleep(10);
    iter++;
  }
  EXPECT_LT(iter, 600);

  unsigned int mid = samples / 2;
  double unitBoxSize = 1.0;

  double angleStep = vMinAngle;

  // all vertical laser planes should sense box
  for (unsigned int i = 0; i < vSamples; ++i)
  {
    double expectedRangeAtMidPoint = box01Pose.Pos().X() - unitBoxSize/2
        - testPose.Pos().X();
    double expectedRange = expectedRangeAtMidPoint / cos(angleStep);

    EXPECT_NEAR(raySensor->Range(i*samples + mid),
        expectedRange, VERTICAL_LASER_TOL);

    angleStep += vAngleStep;

    // EXPECT_DOUBLE_EQ(raySensor->Range(i*samples), GZ_DBL_INF);
    // EXPECT_DOUBLE_EQ(raySensor->Range(i*samples + samples-1), GZ_DBL_INF);
  }

  // Move box out of range
  world->GetModel(box01)->SetWorldPose(
      ignition::math::Pose3d(ignition::math::Vector3d(maxRange + 1, 0, 0),
      ignition::math::Quaterniond::Identity));

  // wait for a few more laser scans
  iter = 0;
  scanCount = 0;
  while (scanCount < 10 && iter < 300)
  {
    common::Time::MSleep(10);
    iter++;
  }
  EXPECT_LT(iter, 300);

  for (int j = 0; j < raySensor->VerticalRayCount(); ++j)
  {
    for (int i = 0; i < raySensor->RayCount(); ++i)
    {
      EXPECT_DOUBLE_EQ(raySensor->Range(j*raySensor->RayCount() + i),
          IGN_DBL_INF);
    }
  }

  raySensor->DisconnectNewLaserFrame(c);

  delete [] scan;
}

TEST_F(GPURaySensorTest, LaserScanResolution)
{
  // Test gpu ray sensor scan resolution.
  // Orient the sensor to face downwards and verify that the interpolated
  // range values all intersect with ground plane at z = 0;
  Load("worlds/empty.world");

    // Make sure the render engine is available.
  if (rendering::RenderEngine::Instance()->GetRenderPathType() ==
      rendering::RenderEngine::NONE)
  {
    gzerr << "No rendering engine, unable to run gpu laser test\n";
    return;
  }

  std::string modelName = "gpu_ray_model";
  std::string raySensorName = "gpu_ray_sensor";
  // use asymmetric horizontal angles to make test more difficult
  double hMinAngle = -M_PI/4.0;
  double hMaxAngle = M_PI/8.0;
  double vMinAngle = -0.1;
  double vMaxAngle = 0.1;
  double vMidAngle = M_PI/2.0;
  double minRange = 0.01;
  double maxRange = 5.0;
  // Test fails with a smaller rangeResolution (it should be 0.03)
  double rangeResolution = 0.12;
  unsigned int hSamples = 641;
  unsigned int vSamples = 5;
  double hResolution = 3;
  double vResolution = 3;
  double hAngleStep = (hMaxAngle - hMinAngle) / (hSamples*hResolution-1);
  double vAngleStep = (vMaxAngle - vMinAngle) / (vSamples*vResolution-1);
  double z0 = 0.5;
  ignition::math::Pose3d testPose(ignition::math::Vector3d(0.25, 0, z0),
      ignition::math::Quaterniond(0, vMidAngle, 0));

  SpawnGpuRaySensorVertical(modelName, raySensorName, testPose.Pos(),
      testPose.Rot().Euler(), hMinAngle, hMaxAngle, vMinAngle, vMaxAngle,
      minRange, maxRange, rangeResolution, hSamples, vSamples,
      hResolution, vResolution);

  sensors::SensorPtr sensor = sensors::get_sensor(raySensorName);
  sensors::GpuRaySensorPtr raySensor =
    std::dynamic_pointer_cast<sensors::GpuRaySensor>(sensor);

  EXPECT_TRUE(raySensor != nullptr);

  physics::WorldPtr world = physics::get_world("default");
  ASSERT_TRUE(world != nullptr);

  raySensor->SetActive(true);

  float *scan = new float[raySensor->RangeCount()
      * raySensor->VerticalRangeCount() * 3];
  int scanCount = 0;
  event::ConnectionPtr c =
    raySensor->ConnectNewLaserFrame(
        std::bind(&::OnNewLaserFrame, &scanCount, scan,
          std::placeholders::_1, std::placeholders::_2, std::placeholders::_3,
          std::placeholders::_4, std::placeholders::_5));

  // wait for a few laser scans
  int iter = 0;
  while (scanCount < 10 && iter < 300)
  {
    common::Time::MSleep(100);
    iter++;
  }
  EXPECT_LT(iter, 300);

  unsigned int h, v;

  for (v = 0; v < vSamples * vResolution; ++v)
  {
    for (h = 0; h < hSamples * hResolution; ++h)
    {
      // pitch angle
      double p = vMinAngle + v*vAngleStep;
      // yaw angle
      double y = hMinAngle + h*hAngleStep;
      double R = raySensor->Range(v*hSamples*hResolution + h);

      ignition::math::Quaterniond rot(0.0, -p, y);
      ignition::math::Vector3d axis = testPose.Rot() * rot *
          ignition::math::Vector3d::UnitX;
      ignition::math::Vector3d intersection = (axis * R) + testPose.Pos();

      EXPECT_NEAR(intersection.Z(), 0.0, rangeResolution);
    }
  }

  raySensor->DisconnectNewLaserFrame(c);

  delete [] scan;
}

int main(int argc, char **argv)
{
  ::testing::InitGoogleTest(&argc, argv);
  return RUN_ALL_TESTS();
}