YAGSL/swervelib/SwerveDrive.java

package swervelib;

import edu.wpi.first.math.VecBuilder;
import edu.wpi.first.math.controller.SimpleMotorFeedforward;
import edu.wpi.first.math.estimator.SwerveDrivePoseEstimator;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.math.geometry.Rotation3d;
import edu.wpi.first.math.geometry.Transform2d;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.math.kinematics.ChassisSpeeds;
import edu.wpi.first.math.kinematics.SwerveModulePosition;
import edu.wpi.first.math.trajectory.Trajectory;
import edu.wpi.first.wpilibj.Timer;
import edu.wpi.first.wpilibj.smartdashboard.Field2d;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import frc.robot.Robot;
import java.util.ArrayList;
import java.util.List;
import swervelib.imu.SwerveIMU;
import swervelib.math.SwerveKinematics2;
import swervelib.math.SwerveModuleState2;
import swervelib.parser.SwerveControllerConfiguration;
import swervelib.parser.SwerveDriveConfiguration;

/**
 * Swerve Drive class representing and controlling the swerve drive.
 */
public class SwerveDrive
{

  /**
   * Swerve Kinematics object utilizing second order kinematics.
   */
  public final  SwerveKinematics2        kinematics;
  /**
   * Swerve drive configuration.
   */
  public final  SwerveDriveConfiguration swerveDriveConfiguration;
  /**
   * Swerve odometry.
   */
  public final  SwerveDrivePoseEstimator swerveDrivePoseEstimator;
  /**
   * Swerve modules.
   */
  private final SwerveModule[]           swerveModules;
  /**
   * Field object.
   */
  public        Field2d                  field = new Field2d();
  /**
   * Swerve controller for controlling heading of the robot.
   */
  public        SwerveController         swerveController;
  /**
   * Swerve IMU device for sensing the heading of the robot.
   */
  private       SwerveIMU                imu;
  /**
   * The current angle of the robot and last time odometry during simulations.
   */
  private       double                   angle, lastTime;
  /**
   * Time during simulations.
   */
  private Timer timer;

  /**
   * Creates a new swerve drivebase subsystem.  Robot is controlled via the drive() method, or via the setModuleStates()
   * method.  The drive() method incorporates kinematics— it takes a translation and rotation, as well as parameters for
   * field-centric and closed-loop velocity control. setModuleStates() takes a list of SwerveModuleStates and directly
   * passes them to the modules. This subsystem also handles odometry.
   *
   * @param config           The {@link SwerveDriveConfiguration} configuration to base the swerve drive off of.
   * @param controllerConfig The {@link SwerveControllerConfiguration} to use when creating the
   *                         {@link SwerveController}.
   */
  public SwerveDrive(SwerveDriveConfiguration config, SwerveControllerConfiguration controllerConfig)
  {
    swerveDriveConfiguration = config;
    swerveController = new SwerveController(controllerConfig);
    // Create Kinematics from swerve module locations.
    kinematics = new SwerveKinematics2(config.moduleLocationsMeters);

    // Create an integrator for angle if the robot is being simulated to emulate an IMU
    // If the robot is real, instantiate the IMU instead.
    if (!Robot.isReal())
    {
      timer = new Timer();
      timer.start();
      lastTime = 0;
    } else
    {
      imu = config.imu;
      imu.factoryDefault();
    }

    this.swerveModules = config.modules;

//    odometry = new SwerveDriveOdometry(kinematics, getYaw(), getModulePositions());
    swerveDrivePoseEstimator = new SwerveDrivePoseEstimator(
        kinematics,
        getYaw(),
        getModulePositions(),
        new Pose2d(new Translation2d(0, 0), Rotation2d.fromDegrees(0)),
        VecBuilder.fill(0.1, 0.1, 0.1), // x,y,heading in radians; state std dev, higher=less weight
        VecBuilder.fill(0.9, 1.0, 0.9)); // x,y,heading in radians; Vision measurement std dev, higher=less weight

    zeroGyro();
    SmartDashboard.putData("Field", field);
  }

  /**
   * The primary method for controlling the drivebase.  Takes a Translation2d and a rotation rate, and calculates and
   * commands module states accordingly.  Can use either open-loop or closed-loop velocity control for the wheel
   * velocities.  Also has field- and robot-relative modes, which affect how the translation vector is used.
   *
   * @param translation   {@link Translation2d} that is the commanded linear velocity of the robot, in meters per
   *                      second. In robot-relative mode, positive x is torwards the bow (front) and positive y is
   *                      torwards port (left).  In field-relative mode, positive x is away from the alliance wall
   *                      (field North) and positive y is torwards the left wall when looking through the driver station
   *                      glass (field West).
   * @param rotation      Robot angular rate, in radians per second. CCW positive.  Unaffected by field/robot
   *                      relativity.
   * @param fieldRelative Drive mode.  True for field-relative, false for robot-relative.
   * @param isOpenLoop    Whether to use closed-loop velocity control.  Set to true to disable closed-loop.
   */
  public void drive(Translation2d translation, double rotation, boolean fieldRelative, boolean isOpenLoop)
  {
    // Creates a robot-relative ChassisSpeeds object, converting from field-relative speeds if necessary.
    ChassisSpeeds velocity = fieldRelative ? ChassisSpeeds.fromFieldRelativeSpeeds(translation.getX(),
                                                                                   translation.getY(),
                                                                                   rotation,
                                                                                   getYaw()) : new ChassisSpeeds(
        translation.getX(),
        translation.getY(),
        rotation);

    // Display commanded speed for testing
    SmartDashboard.putString("RobotVelocity", velocity.toString());

    // Calculate required module states via kinematics
    SwerveModuleState2[] swerveModuleStates = kinematics.toSwerveModuleStates(velocity);

    setModuleStates(swerveModuleStates, isOpenLoop);
  }

  /**
   * Set the module states (azimuth and velocity) directly.  Used primarily for auto pathing.
   *
   * @param desiredStates A list of SwerveModuleStates to send to the modules.
   * @param isOpenLoop    Whether to use closed-loop velocity control.  Set to true to disable closed-loop.
   */
  public void setModuleStates(SwerveModuleState2[] desiredStates, boolean isOpenLoop)
  {
    // Desaturates wheel speeds
    SwerveKinematics2.desaturateWheelSpeeds(desiredStates, swerveDriveConfiguration.maxSpeed);

    // Sets states
    for (SwerveModule module : swerveModules)
    {
      module.setDesiredState(desiredStates[module.moduleNumber], isOpenLoop);
      SmartDashboard.putNumber("Module " + module.moduleNumber + " Speed Setpoint: ",
                               desiredStates[module.moduleNumber].speedMetersPerSecond);
      SmartDashboard.putNumber("Module " + module.moduleNumber + " Angle Setpoint: ",
                               desiredStates[module.moduleNumber].angle.getDegrees());
    }
  }

  /**
   * Set chassis speeds with closed-loop velocity control.
   *
   * @param chassisSpeeds Chassis speeds to set.
   */
  public void setChassisSpeeds(ChassisSpeeds chassisSpeeds)
  {
    setModuleStates(kinematics.toSwerveModuleStates(chassisSpeeds),
                    false);
  }

  /**
   * Gets the current pose (position and rotation) of the robot, as reported by odometry.
   *
   * @return The robot's pose
   */
  public Pose2d getPose()
  {
    return swerveDrivePoseEstimator.getEstimatedPosition();
  }

  /**
   * Gets the current field-relative velocity (x, y and omega) of the robot
   *
   * @return A ChassisSpeeds object of the current field-relative velocity
   */
  public ChassisSpeeds getFieldVelocity()
  {
    // ChassisSpeeds has a method to convert from field-relative to robot-relative speeds,
    // but not the reverse.  However, because this transform is a simple rotation, negating the angle
    // given as the robot angle reverses the direction of rotation, and the conversion is reversed.
    return ChassisSpeeds.fromFieldRelativeSpeeds(kinematics.toChassisSpeeds(getStates()), getYaw().unaryMinus());
  }

  /**
   * Gets the current robot-relative velocity (x, y and omega) of the robot
   *
   * @return A ChassisSpeeds object of the current robot-relative velocity
   */
  public ChassisSpeeds getRobotVelocity()
  {
    return kinematics.toChassisSpeeds(getStates());
  }


  /**
   * Resets odometry to the given pose. Gyro angle and module positions do not need to be reset when calling this
   * method.  However, if either gyro angle or module position is reset, this must be called in order for odometry to
   * keep working.
   *
   * @param pose The pose to set the odometry to
   */
  public void resetOdometry(Pose2d pose)
  {
    swerveDrivePoseEstimator.resetPosition(getYaw(), getModulePositions(), pose);
  }

  /**
   * Post the trajectory to the field
   *
   * @param trajectory the trajectory to post.
   */
  public void postTrajectory(Trajectory trajectory)
  {
    field.getObject("Trajectory").setTrajectory(trajectory);
  }

  /**
   * Gets the current module states (azimuth and velocity)
   *
   * @return A list of SwerveModuleStates containing the current module states
   */
  public SwerveModuleState2[] getStates()
  {
    SwerveModuleState2[] states = new SwerveModuleState2[swerveDriveConfiguration.moduleCount];
    for (SwerveModule module : swerveModules)
    {
      states[module.moduleNumber] = module.getState();
    }
    return states;
  }

  /**
   * Gets the current module positions (azimuth and wheel position (meters))
   *
   * @return A list of SwerveModulePositions containg the current module positions
   */
  public SwerveModulePosition[] getModulePositions()
  {
    SwerveModulePosition[] positions = new SwerveModulePosition[swerveDriveConfiguration.moduleCount];
    for (SwerveModule module : swerveModules)
    {
      positions[module.moduleNumber] = module.getPosition();
    }
    return positions;
  }

  /**
   * Resets the gyro angle to zero and resets odometry to the same position, but facing toward 0.
   */
  public void zeroGyro()
  {
    // Resets the real gyro or the angle accumulator, depending on whether the robot is being simulated
    if (Robot.isReal())
    {
      imu.setYaw(0);
    } else
    {
      angle = 0;
    }
    swerveController.lastAngle = 0;
    resetOdometry(new Pose2d(getPose().getTranslation(), new Rotation2d()));
  }

  /**
   * Gets the current yaw angle of the robot, as reported by the imu.  CCW positive, not wrapped.
   *
   * @return The yaw as a {@link Rotation2d} angle
   */
  public Rotation2d getYaw()
  {
    // Read the imu if the robot is real or the accumulator if the robot is simulated.
    if (Robot.isReal())
    {
      double[] ypr = new double[3];
      imu.getYawPitchRoll(ypr);
      return Rotation2d.fromDegrees(swerveDriveConfiguration.invertedIMU ? 360 - ypr[0] : ypr[0]);
    } else
    {
      return new Rotation2d(angle);
    }
  }

  /**
   * Gets the current pitch angle of the robot, as reported by the imu.
   *
   * @return The heading as a {@link Rotation2d} angle
   */
  public Rotation2d getPitch()
  {
    // Read the imu if the robot is real or the accumulator if the robot is simulated.
    if (Robot.isReal())
    {
      double[] ypr = new double[3];
      imu.getYawPitchRoll(ypr);
      return Rotation2d.fromDegrees(swerveDriveConfiguration.invertedIMU ? 360 - ypr[1] : ypr[1]);
    } else
    {
      return new Rotation2d();
    }
  }

  /**
   * Gets the current roll angle of the robot, as reported by the imu.
   *
   * @return The heading as a {@link Rotation2d} angle
   */
  public Rotation2d getRoll()
  {
    // Read the imu if the robot is real or the accumulator if the robot is simulated.
    if (Robot.isReal())
    {
      double[] ypr = new double[3];
      imu.getYawPitchRoll(ypr);
      return Rotation2d.fromDegrees(swerveDriveConfiguration.invertedIMU ? 360 - ypr[2] : ypr[2]);
    } else
    {
      return new Rotation2d();
    }
  }

  /**
   * Gets the current gyro Rotation3d of the robot, as reported by the imu.
   *
   * @return The heading as a {@link Rotation3d} angle
   */
  public Rotation3d getGyroRotation3d()
  {
    // Read the imu if the robot is real or the accumulator if the robot is simulated.
    if (Robot.isReal())
    {
      double[] ypr = new double[3];
      imu.getYawPitchRoll(ypr);
      return new Rotation3d(
          Math.toRadians(swerveDriveConfiguration.invertedIMU ? 360 - ypr[2] : ypr[2]),
          Math.toRadians(swerveDriveConfiguration.invertedIMU ? 360 - ypr[1] : ypr[1]),
          Math.toRadians(swerveDriveConfiguration.invertedIMU ? 360 - ypr[0] : ypr[0]));
    } else
    {
      return new Rotation3d(angle, 0, 0);
    }
  }

  /**
   * Sets the drive motors to brake/coast mode.
   *
   * @param brake True to set motors to brake mode, false for coast.
   */
  public void setMotorIdleMode(boolean brake)
  {
    for (SwerveModule swerveModule : swerveModules)
    {
      swerveModule.setMotorBrake(brake);
    }
  }

  /**
   * Point all modules toward the robot center, thus making the robot very difficult to move.
   */
  public void setDriveBrake()
  {
    for (SwerveModule swerveModule : swerveModules)
    {
      swerveModule.setDesiredState(new SwerveModuleState2(0,
                                                          swerveModule.configuration.moduleLocation.getAngle(),
                                                          0), true);
    }
  }

  /**
   * Get the swerve module poses and on the field relative to the robot.
   *
   * @param robotPose Robot pose.
   * @return Swerve module poses.
   */
  public Pose2d[] getSwerveModulePoses(Pose2d robotPose)
  {
    Pose2d[]     poseArr = new Pose2d[swerveDriveConfiguration.moduleCount];
    List<Pose2d> poses   = new ArrayList<>();
    for (SwerveModule module : swerveModules)
    {
      poses.add(robotPose.plus(new Transform2d(module.configuration.moduleLocation, module.getState().angle)));
    }
    return poses.toArray(poseArr);
  }

  /**
   * Setup the swerve module feedforward.
   *
   * @param feedforward Feedforward for the drive motor on swerve modules.
   */
  public void replaceSwerveModuleFeedforward(SimpleMotorFeedforward feedforward)
  {
    for (SwerveModule swerveModule : swerveModules)
    {
      swerveModule.feedforward = feedforward;
    }
  }

  /**
   * Update odometry should be run every loop.
   */
  public void updateOdometry()
  {
    // Update odometry
    swerveDrivePoseEstimator.update(getYaw(), getModulePositions());

    // Update angle accumulator if the robot is simulated
    if (!Robot.isReal())
    {
      angle += kinematics.toChassisSpeeds(getStates()).omegaRadiansPerSecond * (timer.get() - lastTime);
      lastTime = timer.get();
      field.getObject("XModules").setPoses(getSwerveModulePoses(swerveDrivePoseEstimator.getEstimatedPosition()));
    }

    field.setRobotPose(swerveDrivePoseEstimator.getEstimatedPosition());

    double[] moduleStates = new double[swerveModules.length * 2];
    for (SwerveModule module : swerveModules)
    {
      SmartDashboard.putNumber("Module" + module.moduleNumber + "Absolute Encoder", module.getAbsolutePosition());
      SmartDashboard.putNumber("Module" + module.moduleNumber + "Relative Encoder", module.getRelativePosition());
      moduleStates[module.moduleNumber] = module.getState().angle.getDegrees();
      moduleStates[module.moduleNumber + 1] = module.getState().speedMetersPerSecond;
    }
    SmartDashboard.putNumberArray("moduleStates", moduleStates);
  }

  /**
   * Synchronize angle motor integrated encoders with data from absolute encoders.
   */
  public void synchronizeModuleEncoders()
  {
    for (SwerveModule module : swerveModules)
    {
      module.synchronizeEncoders();
    }
  }

  /**
   * Add a vision measurement to the {@link SwerveDrivePoseEstimator} with the given timestamp of the vision
   * measurement. <b>THIS WILL BREAK IF UPDATED TOO OFTEN.</b>
   *
   * @param robotPose Robot {@link Pose2d} as measured by vision.
   * @param timestamp Timestamp the measurement was taken as time since FPGATimestamp, could be taken from
   *                  {@link Timer#getFPGATimestamp()}.
   */
  public void addVisionMeasurement(Pose2d robotPose, double timestamp)
  {
    swerveDrivePoseEstimator.addVisionMeasurement(robotPose, timestamp);
  }
}