wpilibNewCommands/src/test/native/cpp/frc2/command/MecanumControllerCommandTest.cpp

/*----------------------------------------------------------------------------*/
/* Copyright (c) 2019-2020 FIRST. All Rights Reserved.                        */
/* Open Source Software - may be modified and shared by FRC teams. The code   */
/* must be accompanied by the FIRST BSD license file in the root directory of */
/* the project.                                                               */
/*----------------------------------------------------------------------------*/

#include <frc2/Timer.h>
#include <frc2/command/MecanumControllerCommand.h>
#include <frc2/command/Subsystem.h>

#include <iostream>

#include <frc/controller/PIDController.h>
#include <frc/controller/ProfiledPIDController.h>
#include <frc/geometry/Rotation2d.h>
#include <frc/geometry/Translation2d.h>
#include <frc/kinematics/MecanumDriveKinematics.h>
#include <frc/kinematics/MecanumDriveOdometry.h>
#include <frc/trajectory/TrajectoryGenerator.h>
#include <wpi/math>

#include "gtest/gtest.h"

#define EXPECT_NEAR_UNITS(val1, val2, eps) \
  EXPECT_LE(units::math::abs(val1 - val2), eps)

class MecanumControllerCommandTest : public ::testing::Test {
  using radians_per_second_squared_t =
      units::compound_unit<units::radians,
                           units::inverse<units::squared<units::second>>>;

 protected:
  frc2::Timer m_timer;
  frc::Rotation2d m_angle{0_rad};

  units::meters_per_second_t m_frontLeftSpeed = 0.0_mps;
  units::meters_per_second_t m_rearLeftSpeed = 0.0_mps;
  units::meters_per_second_t m_frontRightSpeed = 0.0_mps;
  units::meters_per_second_t m_rearRightSpeed = 0.0_mps;

  frc::ProfiledPIDController<units::radians> m_rotController{
      1, 0, 0,
      frc::TrapezoidProfile<units::radians>::Constraints{
          9_rad_per_s, units::unit_t<radians_per_second_squared_t>(3)}};

  static constexpr units::meter_t kxTolerance{1 / 12.0};
  static constexpr units::meter_t kyTolerance{1 / 12.0};
  static constexpr units::radian_t kAngularTolerance{1 / 12.0};

  static constexpr units::meter_t kWheelBase{0.5};
  static constexpr units::meter_t kTrackWidth{0.5};

  frc::MecanumDriveKinematics m_kinematics{
      frc::Translation2d{kWheelBase / 2, kTrackWidth / 2},
      frc::Translation2d{kWheelBase / 2, -kTrackWidth / 2},
      frc::Translation2d{-kWheelBase / 2, kTrackWidth / 2},
      frc::Translation2d{-kWheelBase / 2, -kTrackWidth / 2}};

  frc::MecanumDriveOdometry m_odometry{m_kinematics, 0_rad,
                                       frc::Pose2d{0_m, 0_m, 0_rad}};

  frc::MecanumDriveWheelSpeeds getCurrentWheelSpeeds() {
    return frc::MecanumDriveWheelSpeeds{m_frontLeftSpeed, m_frontRightSpeed,
                                        m_rearLeftSpeed, m_rearRightSpeed};
  }

  frc::Pose2d getRobotPose() {
    m_odometry.UpdateWithTime(m_timer.Get(), m_angle, getCurrentWheelSpeeds());
    return m_odometry.GetPose();
  }
};

TEST_F(MecanumControllerCommandTest, ReachesReference) {
  frc2::Subsystem subsystem{};

  auto waypoints =
      std::vector{frc::Pose2d{0_m, 0_m, 0_rad}, frc::Pose2d{1_m, 5_m, 3_rad}};
  auto trajectory = frc::TrajectoryGenerator::GenerateTrajectory(
      waypoints, {8.8_mps, 0.1_mps_sq});

  auto endState = trajectory.Sample(trajectory.TotalTime());

  auto command = frc2::MecanumControllerCommand(
      trajectory, [&]() { return getRobotPose(); }, m_kinematics,

      frc2::PIDController(0.6, 0, 0), frc2::PIDController(0.6, 0, 0),
      m_rotController, units::meters_per_second_t(8.8),
      [&](units::meters_per_second_t frontLeft,
          units::meters_per_second_t rearLeft,
          units::meters_per_second_t frontRight,
          units::meters_per_second_t rearRight) {
        m_frontLeftSpeed = frontLeft;
        m_rearLeftSpeed = rearLeft;
        m_frontRightSpeed = frontRight;
        m_rearRightSpeed = rearRight;
      },
      {&subsystem});

  m_timer.Reset();
  m_timer.Start();
  command.Initialize();
  while (!command.IsFinished()) {
    command.Execute();
    m_angle = trajectory.Sample(m_timer.Get()).pose.Rotation();
  }
  m_timer.Stop();
  command.End(false);

  EXPECT_NEAR_UNITS(endState.pose.X(), getRobotPose().X(), kxTolerance);
  EXPECT_NEAR_UNITS(endState.pose.Y(), getRobotPose().Y(), kyTolerance);
  EXPECT_NEAR_UNITS(endState.pose.Rotation().Radians(),
                    getRobotPose().Rotation().Radians(), kAngularTolerance);
}
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00			`/----------------------------------------------------------------------------/`
[wpilib] Add X and Y component getters to Pose2d and Transform2d (#2563) pose.Translation().X() and pose.Translation.Y() are common operations, so shortening them to pose.X() and pose.Y() would be convenient. Java uses the getX() convention so that is used instead of X() for Java. 2020-07-02 18:09:36 -07:00			`/* Copyright (c) 2019-2020 FIRST. All Rights Reserved. */`
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00			`/* Open Source Software - may be modified and shared by FRC teams. The code */`
			`/* must be accompanied by the FIRST BSD license file in the root directory of */`
			`/* the project. */`
			`/----------------------------------------------------------------------------/`

			`#include <frc2/Timer.h>`
			`#include <frc2/command/MecanumControllerCommand.h>`
			`#include <frc2/command/Subsystem.h>`

			`#include <iostream>`

			`#include <frc/controller/PIDController.h>`
			`#include <frc/controller/ProfiledPIDController.h>`
			`#include <frc/geometry/Rotation2d.h>`
			`#include <frc/geometry/Translation2d.h>`
			`#include <frc/kinematics/MecanumDriveKinematics.h>`
			`#include <frc/kinematics/MecanumDriveOdometry.h>`
			`#include <frc/trajectory/TrajectoryGenerator.h>`
			`#include <wpi/math>`

			`#include "gtest/gtest.h"`

			`#define EXPECT_NEAR_UNITS(val1, val2, eps) \`
			`EXPECT_LE(units::math::abs(val1 - val2), eps)`

			`class MecanumControllerCommandTest : public ::testing::Test {`
			`using radians_per_second_squared_t =`
			`units::compound_unit<units::radians,`
			`units::inverse<units::squared<units::second>>>;`

			`protected:`
			`frc2::Timer m_timer;`
			`frc::Rotation2d m_angle{0_rad};`

			`units::meters_per_second_t m_frontLeftSpeed = 0.0_mps;`
			`units::meters_per_second_t m_rearLeftSpeed = 0.0_mps;`
			`units::meters_per_second_t m_frontRightSpeed = 0.0_mps;`
			`units::meters_per_second_t m_rearRightSpeed = 0.0_mps;`

			`frc::ProfiledPIDController<units::radians> m_rotController{`
			`1, 0, 0,`
			`frc::TrapezoidProfile<units::radians>::Constraints{`
			`9_rad_per_s, units::unit_t<radians_per_second_squared_t>(3)}};`

			`static constexpr units::meter_t kxTolerance{1 / 12.0};`
			`static constexpr units::meter_t kyTolerance{1 / 12.0};`
			`static constexpr units::radian_t kAngularTolerance{1 / 12.0};`

			`static constexpr units::meter_t kWheelBase{0.5};`
			`static constexpr units::meter_t kTrackWidth{0.5};`

			`frc::MecanumDriveKinematics m_kinematics{`
			`frc::Translation2d{kWheelBase / 2, kTrackWidth / 2},`
			`frc::Translation2d{kWheelBase / 2, -kTrackWidth / 2},`
			`frc::Translation2d{-kWheelBase / 2, kTrackWidth / 2},`
			`frc::Translation2d{-kWheelBase / 2, -kTrackWidth / 2}};`

			`frc::MecanumDriveOdometry m_odometry{m_kinematics, 0_rad,`
			`frc::Pose2d{0_m, 0_m, 0_rad}};`

			`frc::MecanumDriveWheelSpeeds getCurrentWheelSpeeds() {`
			`return frc::MecanumDriveWheelSpeeds{m_frontLeftSpeed, m_frontRightSpeed,`
			`m_rearLeftSpeed, m_rearRightSpeed};`
			`}`

			`frc::Pose2d getRobotPose() {`
			`m_odometry.UpdateWithTime(m_timer.Get(), m_angle, getCurrentWheelSpeeds());`
			`return m_odometry.GetPose();`
			`}`
			`};`

			`TEST_F(MecanumControllerCommandTest, ReachesReference) {`
			`frc2::Subsystem subsystem{};`

			`auto waypoints =`
			`std::vector{frc::Pose2d{0_m, 0_m, 0_rad}, frc::Pose2d{1_m, 5_m, 3_rad}};`
			`auto trajectory = frc::TrajectoryGenerator::GenerateTrajectory(`
			`waypoints, {8.8_mps, 0.1_mps_sq});`

			`auto endState = trajectory.Sample(trajectory.TotalTime());`

			`auto command = frc2::MecanumControllerCommand(`
			`trajectory, [&]() { return getRobotPose(); }, m_kinematics,`

			`frc2::PIDController(0.6, 0, 0), frc2::PIDController(0.6, 0, 0),`
			`m_rotController, units::meters_per_second_t(8.8),`
			`[&](units::meters_per_second_t frontLeft,`
			`units::meters_per_second_t rearLeft,`
			`units::meters_per_second_t frontRight,`
			`units::meters_per_second_t rearRight) {`
			`m_frontLeftSpeed = frontLeft;`
			`m_rearLeftSpeed = rearLeft;`
			`m_frontRightSpeed = frontRight;`
			`m_rearRightSpeed = rearRight;`
			`},`
			`{&subsystem});`

			`m_timer.Reset();`
			`m_timer.Start();`
			`command.Initialize();`
			`while (!command.IsFinished()) {`
			`command.Execute();`
			`m_angle = trajectory.Sample(m_timer.Get()).pose.Rotation();`
			`}`
			`m_timer.Stop();`
			`command.End(false);`

[wpilib] Add X and Y component getters to Pose2d and Transform2d (#2563) pose.Translation().X() and pose.Translation.Y() are common operations, so shortening them to pose.X() and pose.Y() would be convenient. Java uses the getX() convention so that is used instead of X() for Java. 2020-07-02 18:09:36 -07:00			`EXPECT_NEAR_UNITS(endState.pose.X(), getRobotPose().X(), kxTolerance);`
			`EXPECT_NEAR_UNITS(endState.pose.Y(), getRobotPose().Y(), kyTolerance);`
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00			`EXPECT_NEAR_UNITS(endState.pose.Rotation().Radians(),`
			`getRobotPose().Rotation().Radians(), kAngularTolerance);`
			`}`