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

// Copyright (c) FIRST and other WPILib contributors.
// Open Source Software; you can modify and/or share it under the terms of
// the WPILib BSD license file in the root directory of this project.

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

#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/simulation/SimHooks.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}};

  void SetUp() override { frc::sim::PauseTiming(); }

  void TearDown() override { frc::sim::ResumeTiming(); }

  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();
    frc::sim::StepTiming(5_ms);
  }
  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);
}
Remove year from file copyright message (NFC) (#2972) Also update copyright to include "and other WPILib contributors" and clarify license referral language to not be restricted to FIRST teams. 2020-12-26 14:12:05 -08:00			`// Copyright (c) FIRST and other WPILib contributors.`
			`// Open Source Software; you can modify and/or share it under the terms of`
			`// the WPILib BSD license file in the root directory of this project.`
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00
			`#include <frc2/Timer.h>`
			`#include <frc2/command/MecanumControllerCommand.h>`
			`#include <frc2/command/Subsystem.h>`

			`#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>`
[command] Speed up MecanumControllerCommand and SwerveControllerCommand tests (#2604) Currently, these two tests take several seconds to complete and fail intermittently in Windows CI. This is caused by relying on wall clock time. Sampling the trajectory with wall clock time means the simulation must run for several seconds to reach the end of the trajectory. Also, the controller can become unstable when Windows CI experiences process scheduling delays of several hundred milliseconds. Feedback controllers don't cope well with large delays on systems with fast dynamics. This patch uses the mocking functionality of frc::Timer to advance the clock by 5ms at every timestep instead of using the wall clock time. This has two benefits: 1. The tests complete much faster because the simulation can step forward faster than real time. 2. The controller is more stable because the sample period is uniform, which should fix the occasional failures. 2020-07-18 21:58:37 -07:00			`#include <frc/simulation/SimHooks.h>`
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00			`#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}};`

[command] Speed up MecanumControllerCommand and SwerveControllerCommand tests (#2604) Currently, these two tests take several seconds to complete and fail intermittently in Windows CI. This is caused by relying on wall clock time. Sampling the trajectory with wall clock time means the simulation must run for several seconds to reach the end of the trajectory. Also, the controller can become unstable when Windows CI experiences process scheduling delays of several hundred milliseconds. Feedback controllers don't cope well with large delays on systems with fast dynamics. This patch uses the mocking functionality of frc::Timer to advance the clock by 5ms at every timestep instead of using the wall clock time. This has two benefits: 1. The tests complete much faster because the simulation can step forward faster than real time. 2. The controller is more stable because the sample period is uniform, which should fix the occasional failures. 2020-07-18 21:58:37 -07:00			`void SetUp() override { frc::sim::PauseTiming(); }`

			`void TearDown() override { frc::sim::ResumeTiming(); }`

Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00			`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) {`
[command] Speed up MecanumControllerCommand and SwerveControllerCommand tests (#2604) Currently, these two tests take several seconds to complete and fail intermittently in Windows CI. This is caused by relying on wall clock time. Sampling the trajectory with wall clock time means the simulation must run for several seconds to reach the end of the trajectory. Also, the controller can become unstable when Windows CI experiences process scheduling delays of several hundred milliseconds. Feedback controllers don't cope well with large delays on systems with fast dynamics. This patch uses the mocking functionality of frc::Timer to advance the clock by 5ms at every timestep instead of using the wall clock time. This has two benefits: 1. The tests complete much faster because the simulation can step forward faster than real time. 2. The controller is more stable because the sample period is uniform, which should fix the occasional failures. 2020-07-18 21:58:37 -07:00			`frc2::Subsystem subsystem;`
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00
			`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] Speed up MecanumControllerCommand and SwerveControllerCommand tests (#2604) Currently, these two tests take several seconds to complete and fail intermittently in Windows CI. This is caused by relying on wall clock time. Sampling the trajectory with wall clock time means the simulation must run for several seconds to reach the end of the trajectory. Also, the controller can become unstable when Windows CI experiences process scheduling delays of several hundred milliseconds. Feedback controllers don't cope well with large delays on systems with fast dynamics. This patch uses the mocking functionality of frc::Timer to advance the clock by 5ms at every timestep instead of using the wall clock time. This has two benefits: 1. The tests complete much faster because the simulation can step forward faster than real time. 2. The controller is more stable because the sample period is uniform, which should fix the occasional failures. 2020-07-18 21:58:37 -07:00
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00			`command.Initialize();`
			`while (!command.IsFinished()) {`
			`command.Execute();`
			`m_angle = trajectory.Sample(m_timer.Get()).pose.Rotation();`
[command] Speed up MecanumControllerCommand and SwerveControllerCommand tests (#2604) Currently, these two tests take several seconds to complete and fail intermittently in Windows CI. This is caused by relying on wall clock time. Sampling the trajectory with wall clock time means the simulation must run for several seconds to reach the end of the trajectory. Also, the controller can become unstable when Windows CI experiences process scheduling delays of several hundred milliseconds. Feedback controllers don't cope well with large delays on systems with fast dynamics. This patch uses the mocking functionality of frc::Timer to advance the clock by 5ms at every timestep instead of using the wall clock time. This has two benefits: 1. The tests complete much faster because the simulation can step forward faster than real time. 2. The controller is more stable because the sample period is uniform, which should fix the occasional failures. 2020-07-18 21:58:37 -07:00			`frc::sim::StepTiming(5_ms);`
Add holonomic follower examples (#2052) 2019-11-21 19:52:56 -08:00			`}`
			`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);`
			`}`