planning_validator.cpp

// Copyright 2022 Tier IV, Inc.
//
// 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 "planning_validator/planning_validator.hpp"

#include "planning_validator/utils.hpp"

#include <motion_utils/trajectory/trajectory.hpp>
#include <tier4_autoware_utils/tier4_autoware_utils.hpp>

#include <memory>
#include <string>
#include <utility>

namespace planning_validator
{
using diagnostic_msgs::msg::DiagnosticStatus;

PlanningValidator::PlanningValidator(const rclcpp::NodeOptions & options)
: Node("planning_validator", options)
{
  using std::placeholders::_1;

  sub_kinematics_ = create_subscription<Odometry>(
    "~/input/kinematics", 1,
    [this](const Odometry::ConstSharedPtr msg) { current_kinematics_ = msg; });
  sub_traj_ = create_subscription<Trajectory>(
    "~/input/trajectory", 1, std::bind(&PlanningValidator::onTrajectory, this, _1));

  pub_traj_ = create_publisher<Trajectory>("~/output/trajectory", 1);
  pub_status_ = create_publisher<PlanningValidatorStatus>("~/output/validation_status", 1);
  pub_markers_ = create_publisher<visualization_msgs::msg::MarkerArray>("~/output/markers", 1);

  debug_pose_publisher_ = std::make_shared<PlanningValidatorDebugMarkerPublisher>(this);

  setupParameters();

  if (publish_diag_) {
    setupDiag();
  }

  logger_configure_ = std::make_unique<tier4_autoware_utils::LoggerLevelConfigure>(this);
}

void PlanningValidator::setupParameters()
{
  const auto type = declare_parameter<int>("invalid_trajectory_handling_type");
  if (type == 0) {
    invalid_trajectory_handling_type_ = InvalidTrajectoryHandlingType::PUBLISH_AS_IT_IS;
  } else if (type == 1) {
    invalid_trajectory_handling_type_ = InvalidTrajectoryHandlingType::STOP_PUBLISHING;
  } else if (type == 2) {
    invalid_trajectory_handling_type_ = InvalidTrajectoryHandlingType::USE_PREVIOUS_RESULT;
  } else {
    throw std::invalid_argument{
      "unsupported invalid_trajectory_handling_type (" + std::to_string(type) + ")"};
  }
  publish_diag_ = declare_parameter<bool>("publish_diag");
  diag_error_count_threshold_ = declare_parameter<int>("diag_error_count_threshold");
  display_on_terminal_ = declare_parameter<bool>("display_on_terminal");

  {
    auto & p = validation_params_;
    const std::string t = "thresholds.";
    p.interval_threshold = declare_parameter<double>(t + "interval");
    p.relative_angle_threshold = declare_parameter<double>(t + "relative_angle");
    p.curvature_threshold = declare_parameter<double>(t + "curvature");
    p.lateral_acc_threshold = declare_parameter<double>(t + "lateral_acc");
    p.longitudinal_max_acc_threshold = declare_parameter<double>(t + "longitudinal_max_acc");
    p.longitudinal_min_acc_threshold = declare_parameter<double>(t + "longitudinal_min_acc");
    p.steering_threshold = declare_parameter<double>(t + "steering");
    p.steering_rate_threshold = declare_parameter<double>(t + "steering_rate");
    p.velocity_deviation_threshold = declare_parameter<double>(t + "velocity_deviation");
    p.distance_deviation_threshold = declare_parameter<double>(t + "distance_deviation");
  }

  try {
    vehicle_info_ = vehicle_info_util::VehicleInfoUtil(*this).getVehicleInfo();
  } catch (...) {
    RCLCPP_ERROR(get_logger(), "failed to get vehicle info. use default value.");
    vehicle_info_.front_overhang_m = 0.5;
    vehicle_info_.wheel_base_m = 4.0;
  }
}

void PlanningValidator::setStatus(
  DiagnosticStatusWrapper & stat, const bool & is_ok, const std::string & msg)
{
  if (is_ok) {
    stat.summary(DiagnosticStatus::OK, "validated.");
  } else if (validation_status_.invalid_count < diag_error_count_threshold_) {
    const auto warn_msg = msg + " (invalid count is less than error threshold: " +
                          std::to_string(validation_status_.invalid_count) + " < " +
                          std::to_string(diag_error_count_threshold_) + ")";
    stat.summary(DiagnosticStatus::WARN, warn_msg);
  } else {
    stat.summary(DiagnosticStatus::ERROR, msg);
  }
}

void PlanningValidator::setupDiag()
{
  auto & d = diag_updater_;
  d.setHardwareID("planning_validator");

  std::string ns = "trajectory_validation_";
  d.add(ns + "finite", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_finite_value, "infinite value is found");
  });
  d.add(ns + "interval", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_interval, "points interval is too long");
  });
  d.add(ns + "relative_angle", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_relative_angle, "relative angle is too large");
  });
  d.add(ns + "curvature", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_curvature, "curvature is too large");
  });
  d.add(ns + "lateral_acceleration", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_lateral_acc, "lateral acceleration is too large");
  });
  d.add(ns + "acceleration", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_longitudinal_max_acc, "acceleration is too large");
  });
  d.add(ns + "deceleration", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_longitudinal_min_acc, "deceleration is too large");
  });
  d.add(ns + "steering", [&](auto & stat) {
    setStatus(stat, validation_status_.is_valid_steering, "expected steering is too large");
  });
  d.add(ns + "steering_rate", [&](auto & stat) {
    setStatus(
      stat, validation_status_.is_valid_steering_rate, "expected steering rate is too large");
  });
  d.add(ns + "velocity_deviation", [&](auto & stat) {
    setStatus(
      stat, validation_status_.is_valid_velocity_deviation, "velocity deviation is too large");
  });
}

bool PlanningValidator::isDataReady()
{
  const auto waiting = [this](const auto s) {
    RCLCPP_INFO_SKIPFIRST_THROTTLE(get_logger(), *get_clock(), 5000, "waiting for %s", s);
    return false;
  };

  if (!current_kinematics_) {
    return waiting("current_kinematics_");
  }
  if (!current_trajectory_) {
    return waiting("current_trajectory_");
  }
  return true;
}

void PlanningValidator::onTrajectory(const Trajectory::ConstSharedPtr msg)
{
  current_trajectory_ = msg;

  if (!isDataReady()) return;

  debug_pose_publisher_->clearMarkers();

  validate(*current_trajectory_);

  diag_updater_.force_update();

  publishTrajectory();

  // for debug
  publishDebugInfo();
  displayStatus();
}

void PlanningValidator::publishTrajectory()
{
  // Validation check is all green. Publish the trajectory.
  if (isAllValid(validation_status_)) {
    pub_traj_->publish(*current_trajectory_);
    previous_published_trajectory_ = current_trajectory_;
    return;
  }

  //  ----- invalid factor is found. Publish previous trajectory. -----

  if (invalid_trajectory_handling_type_ == InvalidTrajectoryHandlingType::PUBLISH_AS_IT_IS) {
    pub_traj_->publish(*current_trajectory_);
    RCLCPP_ERROR(get_logger(), "Caution! Invalid Trajectory published.");
    return;
  }

  if (invalid_trajectory_handling_type_ == InvalidTrajectoryHandlingType::STOP_PUBLISHING) {
    RCLCPP_ERROR(get_logger(), "Invalid Trajectory detected. Trajectory is not published.");
    return;
  }

  if (invalid_trajectory_handling_type_ == InvalidTrajectoryHandlingType::USE_PREVIOUS_RESULT) {
    if (previous_published_trajectory_) {
      pub_traj_->publish(*previous_published_trajectory_);
      RCLCPP_ERROR(get_logger(), "Invalid Trajectory detected. Use previous trajectory.");
      return;
    }
  }

  // trajectory is not published.
  RCLCPP_ERROR(
    get_logger(),
    "Invalid Trajectory detected, no valid trajectory found in the past. Trajectory is not "
    "published.");
  return;
}

void PlanningValidator::publishDebugInfo()
{
  validation_status_.stamp = get_clock()->now();
  pub_status_->publish(validation_status_);

  if (!isAllValid(validation_status_)) {
    geometry_msgs::msg::Pose front_pose = current_kinematics_->pose.pose;
    shiftPose(front_pose, vehicle_info_.front_overhang_m + vehicle_info_.wheel_base_m);
    debug_pose_publisher_->pushVirtualWall(front_pose);
    debug_pose_publisher_->pushWarningMsg(front_pose, "INVALID PLANNING");
  }
  debug_pose_publisher_->publish();
}

void PlanningValidator::validate(const Trajectory & trajectory)
{
  if (trajectory.points.size() < 2) {
    RCLCPP_ERROR(get_logger(), "trajectory size is less than 2. Cannot validate.");
    return;
  }

  auto & s = validation_status_;

  s.is_valid_finite_value = checkValidFiniteValue(trajectory);
  s.is_valid_interval = checkValidInterval(trajectory);
  s.is_valid_longitudinal_max_acc = checkValidMaxLongitudinalAcceleration(trajectory);
  s.is_valid_longitudinal_min_acc = checkValidMinLongitudinalAcceleration(trajectory);
  s.is_valid_velocity_deviation = checkValidVelocityDeviation(trajectory);
  s.is_valid_distance_deviation = checkValidDistanceDeviation(trajectory);

  // use resampled trajectory because the following metrics can not be evaluated for closed points.
  // Note: do not interpolate to keep original trajectory shape.
  constexpr auto min_interval = 1.0;
  const auto resampled = resampleTrajectory(trajectory, min_interval);

  s.is_valid_relative_angle = checkValidRelativeAngle(resampled);
  s.is_valid_curvature = checkValidCurvature(resampled);
  s.is_valid_lateral_acc = checkValidLateralAcceleration(resampled);
  s.is_valid_steering = checkValidSteering(resampled);
  s.is_valid_steering_rate = checkValidSteeringRate(resampled);

  s.invalid_count = isAllValid(s) ? 0 : s.invalid_count + 1;
}

bool PlanningValidator::checkValidFiniteValue(const Trajectory & trajectory)
{
  for (const auto & p : trajectory.points) {
    if (!checkFinite(p)) return false;
  }
  return true;
}

bool PlanningValidator::checkValidInterval(const Trajectory & trajectory)
{
  const auto [max_interval_distance, i] = calcMaxIntervalDistance(trajectory);
  validation_status_.max_interval_distance = max_interval_distance;

  if (max_interval_distance > validation_params_.interval_threshold) {
    if (i > 0) {
      const auto & p = trajectory.points;
      debug_pose_publisher_->pushPoseMarker(p.at(i - 1), "trajectory_interval");
      debug_pose_publisher_->pushPoseMarker(p.at(i), "trajectory_interval");
    }
    return false;
  }

  return true;
}

bool PlanningValidator::checkValidRelativeAngle(const Trajectory & trajectory)
{
  const auto [max_relative_angle, i] = calcMaxRelativeAngles(trajectory);
  validation_status_.max_relative_angle = max_relative_angle;

  if (max_relative_angle > validation_params_.relative_angle_threshold) {
    const auto & p = trajectory.points;
    if (i < p.size() - 3) {
      debug_pose_publisher_->pushPoseMarker(p.at(i), "trajectory_relative_angle", 0);
      debug_pose_publisher_->pushPoseMarker(p.at(i + 1), "trajectory_relative_angle", 1);
      debug_pose_publisher_->pushPoseMarker(p.at(i + 2), "trajectory_relative_angle", 2);
    }
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidCurvature(const Trajectory & trajectory)
{
  const auto [max_curvature, i] = calcMaxCurvature(trajectory);
  validation_status_.max_curvature = max_curvature;
  if (max_curvature > validation_params_.curvature_threshold) {
    const auto & p = trajectory.points;
    if (i > 0 && i < p.size() - 1) {
      debug_pose_publisher_->pushPoseMarker(p.at(i - 1), "trajectory_curvature");
      debug_pose_publisher_->pushPoseMarker(p.at(i), "trajectory_curvature");
      debug_pose_publisher_->pushPoseMarker(p.at(i + 1), "trajectory_curvature");
    }
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidLateralAcceleration(const Trajectory & trajectory)
{
  const auto [max_lateral_acc, i] = calcMaxLateralAcceleration(trajectory);
  validation_status_.max_lateral_acc = max_lateral_acc;
  if (max_lateral_acc > validation_params_.lateral_acc_threshold) {
    debug_pose_publisher_->pushPoseMarker(trajectory.points.at(i), "lateral_acceleration");
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidMinLongitudinalAcceleration(const Trajectory & trajectory)
{
  const auto [min_longitudinal_acc, i] = getMinLongitudinalAcc(trajectory);
  validation_status_.min_longitudinal_acc = min_longitudinal_acc;

  if (min_longitudinal_acc < validation_params_.longitudinal_min_acc_threshold) {
    debug_pose_publisher_->pushPoseMarker(trajectory.points.at(i).pose, "min_longitudinal_acc");
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidMaxLongitudinalAcceleration(const Trajectory & trajectory)
{
  const auto [max_longitudinal_acc, i] = getMaxLongitudinalAcc(trajectory);
  validation_status_.max_longitudinal_acc = max_longitudinal_acc;

  if (max_longitudinal_acc > validation_params_.longitudinal_max_acc_threshold) {
    debug_pose_publisher_->pushPoseMarker(trajectory.points.at(i).pose, "max_longitudinal_acc");
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidSteering(const Trajectory & trajectory)
{
  const auto [max_steering, i] = calcMaxSteeringAngles(trajectory, vehicle_info_.wheel_base_m);
  validation_status_.max_steering = max_steering;

  if (max_steering > validation_params_.steering_threshold) {
    debug_pose_publisher_->pushPoseMarker(trajectory.points.at(i).pose, "max_steering");
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidSteeringRate(const Trajectory & trajectory)
{
  const auto [max_steering_rate, i] = calcMaxSteeringRates(trajectory, vehicle_info_.wheel_base_m);
  validation_status_.max_steering_rate = max_steering_rate;

  if (max_steering_rate > validation_params_.steering_rate_threshold) {
    debug_pose_publisher_->pushPoseMarker(trajectory.points.at(i).pose, "max_steering_rate");
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidVelocityDeviation(const Trajectory & trajectory)
{
  // TODO(horibe): set appropriate thresholds for index search
  const auto idx = motion_utils::findFirstNearestIndexWithSoftConstraints(
    trajectory.points, current_kinematics_->pose.pose);

  validation_status_.velocity_deviation = std::abs(
    trajectory.points.at(idx).longitudinal_velocity_mps -
    current_kinematics_->twist.twist.linear.x);

  if (validation_status_.velocity_deviation > validation_params_.velocity_deviation_threshold) {
    return false;
  }
  return true;
}

bool PlanningValidator::checkValidDistanceDeviation(const Trajectory & trajectory)
{
  // TODO(horibe): set appropriate thresholds for index search
  const auto idx = motion_utils::findFirstNearestIndexWithSoftConstraints(
    trajectory.points, current_kinematics_->pose.pose);

  validation_status_.distance_deviation =
    tier4_autoware_utils::calcDistance2d(trajectory.points.at(idx), current_kinematics_->pose.pose);

  if (validation_status_.distance_deviation > validation_params_.distance_deviation_threshold) {
    return false;
  }
  return true;
}

bool PlanningValidator::isAllValid(const PlanningValidatorStatus & s)
{
  return s.is_valid_finite_value && s.is_valid_interval && s.is_valid_relative_angle &&
         s.is_valid_curvature && s.is_valid_lateral_acc && s.is_valid_longitudinal_max_acc &&
         s.is_valid_longitudinal_min_acc && s.is_valid_steering && s.is_valid_steering_rate &&
         s.is_valid_velocity_deviation && s.is_valid_distance_deviation;
}

void PlanningValidator::displayStatus()
{
  if (!display_on_terminal_) return;

  const auto warn = [this](const bool status, const std::string & msg) {
    if (!status) {
      RCLCPP_WARN(get_logger(), "%s", msg.c_str());
    }
  };

  const auto & s = validation_status_;

  warn(s.is_valid_curvature, "planning trajectory curvature is too large!!");
  warn(s.is_valid_distance_deviation, "planning trajectory is too far from ego!!");
  warn(s.is_valid_finite_value, "planning trajectory has invalid value!!");
  warn(s.is_valid_interval, "planning trajectory interval is too long!!");
  warn(s.is_valid_lateral_acc, "planning trajectory lateral acceleration is too high!!");
  warn(s.is_valid_longitudinal_max_acc, "planning trajectory acceleration is too high!!");
  warn(s.is_valid_longitudinal_min_acc, "planning trajectory deceleration is too high!!");
  warn(s.is_valid_relative_angle, "planning trajectory yaw angle varies too fast!!");
  warn(s.is_valid_steering, "planning trajectory expected steering angle is too high!!");
  warn(s.is_valid_steering_rate, "planning trajectory expected steering angle rate is too high!!");
  warn(s.is_valid_velocity_deviation, "planning trajectory velocity deviation is too high!!");
}

}  // namespace planning_validator

#include <rclcpp_components/register_node_macro.hpp>
RCLCPP_COMPONENTS_REGISTER_NODE(planning_validator::PlanningValidator)