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src/main/java/frc4388/robot/Main.java
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2018 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. */
/*----------------------------------------------------------------------------*/
package frc4388.robot;
import edu.wpi.first.wpilibj.RobotBase;
/**
* Do NOT add any static variables to this class, or any initialization at all.
* Unless you know what you are doing, do not modify this file except to
* change the parameter class to the startRobot call.
*/
public final class Main {
private Main() {
}
/**
* Main initialization function. Do not perform any initialization here.
*
* <p>If you change your main robot class, change the parameter type.
*/
public static void main(String... args) {
RobotBase.startRobot(Robot::new);
}
}
src/main/java/frc4388/robot/Robot.java
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2017-2019 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. */
/*----------------------------------------------------------------------------*/
package frc4388.robot;
// Advantagekit
import org.littletonrobotics.junction.LogFileUtil;
import org.littletonrobotics.junction.LoggedRobot;
import org.littletonrobotics.junction.Logger;
import org.littletonrobotics.junction.networktables.NT4Publisher;
import org.littletonrobotics.junction.wpilog.WPILOGReader;
import org.littletonrobotics.junction.wpilog.WPILOGWriter;
import edu.wpi.first.wpilibj.RobotController;
import edu.wpi.first.wpilibj2.command.Command;
import edu.wpi.first.wpilibj2.command.CommandScheduler;
import frc4388.robot.constants.BuildConstants;
import frc4388.robot.constants.Constants.SimConstants;
import frc4388.utility.DeferredBlock;
import frc4388.utility.compute.RobotTime;
import frc4388.utility.compute.Trim;
import frc4388.utility.status.FaultReporter;
//import frc4388.robot.subsystems.LED;
/**
* The VM is configured to automatically run this class, and to call the
* functions corresponding to each mode, as described in the TimedRobot
* documentation. If you change the name of this class or the package after
* creating this project, you must also update the build.gradle file in the
* project.
*/
public class Robot extends LoggedRobot {
Command m_autonomousCommand;
private RobotTime m_robotTime = RobotTime.getInstance();
private RobotContainer m_robotContainer;
//private LED mled = new LED();
/**
* This function is run when the robot is first started up and should be
* used for any initialization code.
*/
@Override
public void robotInit() {
// Start logging with AdvantageKit
startLogging();
// Instantiate our RobotContainer. This will perform all our button bindings, and put our
// autonomous chooser on the dashboard.
m_robotContainer = new RobotContainer();
// // Create a shuffleboard update thread, that will periodically update the values on shuffleboard
// FaultReporter.startThread();
}
/**
* This function is called every robot packet, no matter the mode. Use
* this for items like diagnostics that you want ran during disabled,
* autonomous, teleoperated and test.doubl
*
* <p>This runs after the mode specific periodic functions, but before
* LiveWindow and SmartDashboard integrated updating.
*/
@Override
public void robotPeriodic() {
m_robotTime.updateTimes();
// SmartDashboard.putNumber("Time", System.currentTimeMillis());
m_robotContainer.m_robotLED.update();
// Runs the Scheduler. This is responsible for polling buttons, adding newly-scheduled
// commands, running already-scheduled commands, removing finished or interrupted commands,
// and running subsystem periodic() methods. This must be called from the robot's periodic
// block in order for anything in the Command-based framework to work.
CommandScheduler.getInstance().run();
}
/**
* This function is called once each time the robot enters Disabled mode.
* You can use it to reset any subsystem information you want to clear when
* the robot is disabled.
*/
@Override
public void disabledInit() {
m_robotTime.endMatchTime();
}
@Override
public void disabledPeriodic() {
}
@Override
public void disabledExit() {
DeferredBlock.execute();
}
/**
* This autonomous runs the autonomous command selected by your {@link RobotContainer} class.
*/
@Override
public void autonomousInit() {
m_autonomousCommand = m_robotContainer.getAutonomousCommand();
/*
* String autoSelected = SmartDashboard.getString("Auto Selector",
* "Default"); switch(autoSelected) { case "My Auto": autonomousCommand
* = new MyAutoCommand(); break; case "Default Auto": default:
* autonomousCommand = new ExampleCommand(); break; }
*/
// schedule the autonomous command (example)
if (m_autonomousCommand != null) {
m_autonomousCommand.schedule();
}
m_robotTime.startMatchTime();
}
/**
* This function is called periodically during autonomous.
*/
@Override
public void autonomousPeriodic() {
}
@Override
public void teleopInit() {
m_robotContainer.stop();
// This makes sure that the autonomous stops running when
// teleop starts running. If you want the autonomous to
// continue until interrupted by another command, remove
// this line or comment it out.
if (m_autonomousCommand != null) {
CommandScheduler.getInstance().cancel(m_autonomousCommand);
m_autonomousCommand.cancel();
m_autonomousCommand.end(true);
}
m_robotTime.startMatchTime();
}
/**
* This function is called periodically during operator control.
*/
@Override
public void teleopPeriodic() {
// m_robotContainer.m_robotMap.rightFront.go(m_robotContainer.getDeadbandedDriverController().getLeft());
}
/**
* This function is called periodically during operator control.
*/
@Override
public void teleopExit() { // the only OTHER mode that teleop can enter into is disabled.
Trim.dumpAll();
}
@Override
public void testInit() {
FaultReporter.printReport();
}
// VisionSystemSim visionSim;
// RobotMapSim robotMapSim;
// @Override
// public void simulationInit() {
// visionSim = new VisionSystemSim("main");
// robotMapSim = m_robotContainer.m_robotMap.configureSim();
// // A 0.5 x 0.25 meter rectangular target
// TargetModel targetModel = new TargetModel(0.5, 0.25);
// // The pose of where the target is on the field.
// // Its rotation determines where "forward" or the target x-axis points.
// // Let's say this target is flat against the far wall center, facing the blue driver stations.
// Pose3d targetPose = new Pose3d(16, 4, 2, new Rotation3d(0, 0, Math.PI));
// // The given target model at the given pose
// VisionTargetSim visionTarget = new VisionTargetSim(targetPose, targetModel);
// // Add this vision target to the vision system simulation to make it visible
// visionSim.addVisionTargets(visionTarget);
// // The layout of AprilTags which we want to add to the vision system
// AprilTagFieldLayout tagLayout = Constants.FieldConstants.kTagLayout;
// visionSim.addAprilTags(tagLayout);
// visionSim.addCamera(robotMapSim.leftCamera, Constants.VisionConstants.LEFT_CAMERA_POS);
// visionSim.addCamera(robotMapSim.rightCamera, Constants.VisionConstants.RIGHT_CAMERA_POS);
// SmartDashboard.putData(visionSim.getDebugField());
// }
// @Override
// public void simulationPeriodic() {
// m_robotContainer.m_robotSwerveDrive.updateSim(RobotController.getBatteryVoltage());
// // visionSim.update(m_robotContainer.m_robotSwerveDrive.getPose2d());
// // m_robotContainer.m_robotSwerveDrive.
// }
// Start AdvantageKit logging / replay and record metadata
// Refrence: https://github.com/Mechanical-Advantage/AdvantageKit/blob/main/template_projects/sources/skeleton/src/main/java/frc/robot/Robot.java
public void startLogging() {
// Record metadata
Logger.recordMetadata("ProjectName", BuildConstants.MAVEN_NAME);
Logger.recordMetadata("BuildDate", BuildConstants.BUILD_DATE);
Logger.recordMetadata("Git+SHA", BuildConstants.GIT_SHA);
Logger.recordMetadata("GitDate", BuildConstants.GIT_DATE);
Logger.recordMetadata("GitBranch", BuildConstants.GIT_BRANCH);
switch (BuildConstants.DIRTY) {
case 0:
Logger.recordMetadata("GitDirty", "All changes committed");
break;
case 1:
Logger.recordMetadata("GitDirty", "Uncomitted changes");
break;
default:
Logger.recordMetadata("GitDirty", "Unknown");
break;
}
// Set up data receivers & replay source
switch (SimConstants.currentMode) {
case REAL:
// Running on a real robot, log to a USB stick ("/U/logs")
Logger.addDataReceiver(new WPILOGWriter());
Logger.addDataReceiver(new NT4Publisher());
break;
case SIM:
// Running a physics simulator, log to NT
Logger.addDataReceiver(new NT4Publisher());
break;
case REPLAY:
// Replaying a log, set up replay source
setUseTiming(false); // Run as fast as possible
String logPath = LogFileUtil.findReplayLog();
Logger.setReplaySource(new WPILOGReader(logPath));
Logger.addDataReceiver(new WPILOGWriter(LogFileUtil.addPathSuffix(logPath, "_sim")));
break;
}
// Start AdvantageKit logger
Logger.start();
}
}
src/main/java/frc4388/robot/RobotContainer.java
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2018-2019 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. */
/*----------------------------------------------------------------------------*/
package frc4388.robot;
// Drive Systems
import edu.wpi.first.wpilibj.DriverStation;
import java.io.File;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.math.util.Units;
import edu.wpi.first.wpilibj.GenericHID;
import edu.wpi.first.wpilibj.RobotBase;
import edu.wpi.first.wpilibj.smartdashboard.SendableChooser;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import frc4388.utility.controller.XboxController;
import frc4388.utility.controller.ButtonBox;
import frc4388.utility.controller.DeadbandedXboxController;
import edu.wpi.first.wpilibj2.command.button.JoystickButton;
import edu.wpi.first.wpilibj2.command.button.Trigger;
// Commands
import edu.wpi.first.wpilibj2.command.Command;
import edu.wpi.first.wpilibj2.command.InstantCommand;
import edu.wpi.first.wpilibj2.command.ParallelRaceGroup;
import edu.wpi.first.wpilibj2.command.RunCommand;
import edu.wpi.first.wpilibj2.command.SequentialCommandGroup;
import edu.wpi.first.wpilibj2.command.WaitCommand;
import edu.wpi.first.wpilibj2.command.Commands;
import edu.wpi.first.wpilibj2.command.ConditionalCommand;
// Autos
import frc4388.utility.controller.VirtualController;
import frc4388.robot.commands.MoveForTimeCommand;
import frc4388.robot.commands.MoveUntilSuply;
import frc4388.robot.commands.alignment.DriveToReef;
import frc4388.robot.commands.alignment.DriveUntilLiDAR;
import frc4388.robot.commands.alignment.LidarAlign;
import frc4388.robot.commands.wait.waitElevatorRefrence;
import frc4388.robot.commands.wait.waitEndefectorRefrence;
import frc4388.robot.commands.wait.waitFeedCoral;
import frc4388.robot.commands.wait.waitSupplier;
import frc4388.robot.constants.Constants;
import frc4388.robot.constants.Constants.AutoConstants;
import frc4388.robot.constants.Constants.LiDARConstants;
import frc4388.robot.constants.Constants.OIConstants;
import frc4388.robot.constants.Constants.SimConstants.Mode;
import com.pathplanner.lib.auto.NamedCommands;
import com.pathplanner.lib.commands.PathPlannerAuto;
// Subsystems
import frc4388.robot.subsystems.LED;
import frc4388.robot.subsystems.elevator.Elevator;
import frc4388.robot.subsystems.elevator.Elevator.CoordinationState;
import frc4388.robot.subsystems.lidar.LiDAR;
import frc4388.robot.subsystems.swerve.SwerveDrive;
import frc4388.robot.subsystems.vision.Vision;
// Utilites
import frc4388.utility.DeferredBlock;
import frc4388.utility.compute.TimesNegativeOne;
import frc4388.utility.compute.ReefPositionHelper.Side;
/**
* This class is where the bulk of the robot should be declared. Since
* Command-based is a "declarative" paradigm, very little robot logic should
* actually be handled in the {@link Robot} periodic methods (other than the
* scheduler calls). Instead, the structure of the robot (2including subsystems,
* commands, and button mappings) should be declared here.
*/
public class RobotContainer {
/* RobotMap */
public final RobotMap m_robotMap = new RobotMap(Mode.REAL);
/* Subsystems */
public final LED m_robotLED = new LED();
public final Vision m_vision = new Vision(m_robotMap.leftCamera, m_robotMap.rightCamera);
public final Elevator m_robotElevator = new Elevator(m_robotMap.elevatorIO, m_robotLED);
public final SwerveDrive m_robotSwerveDrive = new SwerveDrive(m_robotMap.swerveDrivetrain, m_vision);
// public final SwerveDrive m_robotSwerveDrive = new SwerveDrive(m_robotMap.swerveDrivetrain);
public final LiDAR reefLidar = new LiDAR(m_robotMap.reefLidar, "Reef");
public final LiDAR reverseLidar = new LiDAR(m_robotMap.reverseLidar, "Reverse");
/* Controllers */
private final DeadbandedXboxController m_driverXbox = new DeadbandedXboxController(OIConstants.XBOX_DRIVER_ID);
private final DeadbandedXboxController m_operatorXbox = new DeadbandedXboxController(OIConstants.XBOX_OPERATOR_ID);
private final ButtonBox m_buttonBox = new ButtonBox(OIConstants.BUTTONBOX_ID);
// public List<Subsystem> subsystems = new ArrayList<>();
// ! Teleop Commands
public void stop() {
new InstantCommand(()->{}, m_robotSwerveDrive).schedule();
m_robotSwerveDrive.stopModules();
Constants.AutoConstants.Y_OFFSET_TRIM.set(0);
}
// ! /* Autos */
private SendableChooser<String> autoChooser;
private Command autoCommand;
/**
* This method is used to replcate {@link Trigger Triggers} for {@link VirtualController Virtual Controllers}. <p/>
* Please use {@link RobotContainer#DualJoystickButton} in {@link RobotContainer#configureButtonBindings} for standard buttons.
*/
private void configureVirtualButtonBindings() {
// ? /* Driver Buttons */
/* Notice: the following buttons have not been replicated
* Swerve Drive Slow and Fast mode Gear Shifts : Fast mode is known to cause drift, so we disable that feature in Autoplayback
* Swerve Drive Rotation Gear Shifts : Same reason as Slow and Fast mode.
* Auto Recording controls : We don't want an Null Ouroboros for an auto.
*/
// ? /* Operator Buttons */
/* Notice: the following buttons have not been replicated
* Override Intake Position Encoder : It's an emergancy overide, for when the position of intake when the robot boots, the intake is not inside the robot.
* We don't need it in an auto.
* Climbing controls : We don't need to climb in auto.
*/
// ? Notice: the Programer Buttons are not to be replicated because they are designed for debuging the robot, and do not need to be replicated in auto.
}
/**
* Use this to pass the autonomous command to the main {@link Robot} class.
*
* @return the command to run in autonomous
*/
public Command getAutonomousCommand() {
//return autoPlayback;
//return new GotoPositionCommand(m_robotSwerveDrive, m_vision)
//return autoChooser.getSelected();
// try{
// // // Load the path you want to follow using its name in the GUI
// return autoCommand;
// } catch (Exception e) {
// DriverStation.reportError("Path planner error: " + e.getMessage(), e.getStackTrace());
return autoCommand;
// }
// return new PathPlannerAuto("Line-up-no-arm");
// zach told me to do the below comment
//return new GotoPositionCommand(m_robotSwerveDrive, m_vision);
// return new GotoPositionCommand(m_robotSwerveDrive, m_vision, AutoConstants.targetpos);
}
public boolean autoChooserUpdated = false;
public void makeAutoChooser() {
autoChooser = new SendableChooser<String>();
File dir;
if(RobotBase.isReal()) {
dir = new File("/home/lvuser/deploy/pathplanner/autos/");
} else {
// dir = new File("C:\\Users\\Ridgebotics\\Documents\\GitHub\\2025RidgeScape\\src\\main\\deploy\\pathplanner\\autos\\");
dir = new File("/home/astatin3/Documents/GitHub/2025RidgeScape/src/main/deploy/pathplanner/autos");
}
String[] autos = dir.list();
if(autos == null) return;
for (String auto : autos) {
if (auto.endsWith(".auto"))
autoChooser.addOption(auto.replaceAll(".auto", ""), auto.replaceAll(".auto", ""));
// System.out.println(auto);
}
autoChooser.onChange((filename) -> {
autoChooserUpdated = true;
if (filename.equals("Taxi")) {
autoCommand = new SequentialCommandGroup(
new MoveForTimeCommand(m_robotSwerveDrive,
new Translation2d(0, -1),
new Translation2d(), 1000, true
), new InstantCommand(()-> {m_robotSwerveDrive.softStop();} , m_robotSwerveDrive));
} else {
autoCommand = new PathPlannerAuto(filename);
}
System.out.println("Robot Auto Changed " + filename);
});
// SmartDashboard.putData(autoChooser);
}
/**
* A button binding for two controllers, preferably an {@link DeadbandedXboxController Xbox Controller} and {@link VirtualController Virtual Xbox Controller}
* @param joystickA A controller
* @param joystickB A controller
* @param buttonNumber The button to bind to
*/
public Trigger DualJoystickButton(GenericHID joystickA, GenericHID joystickB, int buttonNumber) {
return new Trigger(() -> (joystickA.getRawButton(buttonNumber) || joystickB.getRawButton(buttonNumber)));
}
public DeadbandedXboxController getDeadbandedDriverController() {
return this.m_driverXbox;
}
public DeadbandedXboxController getDeadbandedOperatorController() {
return this.m_operatorXbox;
}
public ButtonBox getButtonBox() {
return this.m_buttonBox;
}
}
src/main/java/frc4388/robot/RobotMap.java
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2018-2019 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. */
/*----------------------------------------------------------------------------*/
package frc4388.robot;
import com.ctre.phoenix6.hardware.TalonFX;
import org.photonvision.PhotonCamera;
import org.photonvision.simulation.PhotonCameraSim;
import org.photonvision.simulation.SimCameraProperties;
import com.ctre.phoenix6.hardware.CANcoder;
import com.ctre.phoenix6.swerve.SwerveDrivetrain;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.wpilibj.DigitalInput;
import frc4388.robot.constants.Constants.ElevatorConstants;
import frc4388.robot.constants.Constants.LiDARConstants;
import frc4388.robot.constants.Constants.SimConstants;
import frc4388.robot.constants.Constants.VisionConstants;
import frc4388.robot.subsystems.elevator.ElevatorIO;
import frc4388.robot.subsystems.elevator.ElevatorReal;
import frc4388.robot.subsystems.lidar.LiDAR;
import frc4388.robot.subsystems.lidar.LidarIO;
import frc4388.robot.subsystems.lidar.LidarReal;
import frc4388.robot.subsystems.swerve.SwerveDriveConstants;
import frc4388.robot.subsystems.swerve.SwerveIO;
import frc4388.robot.subsystems.swerve.SwerveReal;
import frc4388.robot.subsystems.vision.VisionIO;
import frc4388.robot.subsystems.vision.VisionReal;
import frc4388.utility.status.FaultCANCoder;
import frc4388.utility.status.FaultPhotonCamera;
import frc4388.utility.status.FaultPidgeon2;
import frc4388.utility.status.FaultTalonFX;
/**
* Defines and holds all I/O objects on the Roborio. This is useful for unit
* testing and modularization.
*/
public class RobotMap {
// private Pigeon2 m_pigeon2 = new Pigeon2(SwerveDriveConstants.IDs.DRIVE_PIGEON.id);
// public RobotGyro gyro = new RobotGyro(m_pigeon2);
public final VisionIO leftCamera;
public final VisionIO rightCamera;
// public final LiDAR lidar = new
public final LidarIO reefLidar;
public final LidarIO reverseLidar;
/* LED Subsystem */
// public final Spark LEDController = new Spark(LEDConstants.LED_SPARK_ID);
/* Swreve Drive Subsystem */
public final SwerveIO swerveDrivetrain;
/* Elevator Subsystem */
public final ElevatorIO elevatorIO;
public RobotMap(SimConstants.Mode mode) {
switch (mode) {
case REAL:
// Configure cameras
PhotonCamera leftCameraReal = new PhotonCamera(VisionConstants.LEFT_CAMERA_NAME);
PhotonCamera rightCameraReal = new PhotonCamera(VisionConstants.RIGHT_CAMERA_NAME);
leftCamera = new VisionReal(leftCameraReal, VisionConstants.LEFT_CAMERA_POS); ;
rightCamera = new VisionReal(rightCameraReal, VisionConstants.RIGHT_CAMERA_POS);
FaultPhotonCamera.addDevice(leftCameraReal, "Left Camera");
FaultPhotonCamera.addDevice(rightCameraReal , "Right Camera");
// Configure LiDAR
reefLidar = new LidarReal(LiDARConstants.REEF_LIDAR_DIO_CHANNEL);
reverseLidar = new LidarReal(LiDARConstants.REVERSE_LIDAR_DIO_CHANNEL);
// Configure swerve drive train
SwerveDrivetrain<TalonFX, TalonFX, CANcoder> swerveDrivetrainReal = new SwerveDrivetrain<TalonFX, TalonFX, CANcoder> (TalonFX::new, TalonFX::new, CANcoder::new,
SwerveDriveConstants.DrivetrainConstants,
SwerveDriveConstants.FRONT_LEFT, SwerveDriveConstants.FRONT_RIGHT,
SwerveDriveConstants.BACK_LEFT, SwerveDriveConstants.BACK_RIGHT
);
swerveDrivetrain = new SwerveReal(swerveDrivetrainReal);
// Configure elevator
TalonFX elevator = new TalonFX(ElevatorConstants.ELEVATOR_ID.id);
TalonFX endeffector = new TalonFX(ElevatorConstants.ENDEFFECTOR_ID.id);
DigitalInput basinLimitSwitch = new DigitalInput(ElevatorConstants.BASIN_LIMIT_SWITCH);
DigitalInput endeffectorLimitSwitch = new DigitalInput(ElevatorConstants.ENDEFFECTOR_LIMIT_SWITCH);
DigitalInput IRIntakeBeam = new DigitalInput(ElevatorConstants.INTAKE_LIMIT_SWITCH);
elevatorIO = new ElevatorReal(elevator, endeffector, basinLimitSwitch, endeffectorLimitSwitch, IRIntakeBeam);
// Fault
FaultPidgeon2.addDevice(swerveDrivetrainReal.getPigeon2(), "Gyro");
FaultTalonFX.addDevice(elevator, "Elevator");
FaultTalonFX.addDevice(endeffector, "Endeffector");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(0).getDriveMotor(), "Module 0 Drive");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(0).getSteerMotor(), "Module 0 Steer");
FaultCANCoder.addDevice(swerveDrivetrainReal.getModule(0).getEncoder(), "Module 0 CANCoder");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(1).getDriveMotor(), "Module 1 Drive");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(1).getSteerMotor(), "Module 1 Steer");
FaultCANCoder.addDevice(swerveDrivetrainReal.getModule(1).getEncoder(), "Module 1 CANCoder");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(2).getDriveMotor(), "Module 2 Drive");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(2).getSteerMotor(), "Module 2 Steer");
FaultCANCoder.addDevice(swerveDrivetrainReal.getModule(2).getEncoder(), "Module 2 CANCoder");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(3).getDriveMotor(), "Module 3 Drive");
FaultTalonFX.addDevice(swerveDrivetrainReal.getModule(3).getSteerMotor(), "Module 3 Steer");
FaultCANCoder.addDevice(swerveDrivetrainReal.getModule(3).getEncoder(), "Module 3 CANCoder");
break;
// case SIM:
// break;
default:
leftCamera = new VisionIO() {};
rightCamera = new VisionIO() {};
reefLidar = new LidarIO() {};
reverseLidar = new LidarIO() {};
swerveDrivetrain = new SwerveIO() {};
elevatorIO = new ElevatorIO() {};
break;
}
}
// public class RobotMapSim {
// public PhotonCameraSim leftCamera;
// public PhotonCameraSim rightCamera;
// }
// public RobotMapSim configureSim() {
// RobotMapSim sim = new RobotMapSim();
// // The simulated camera properties
// SimCameraProperties cameraProp = new SimCameraProperties();
// // A 640 x 480 camera with a 100 degree diagonal FOV.
// cameraProp.setCalibration(640, 480, Rotation2d.fromDegrees(100));
// // Approximate detection noise with average and standard deviation error in pixels.
// cameraProp.setCalibError(0.25, 0.08);
// // Set the camera image capture framerate (Note: this is limited by robot loop rate).
// cameraProp.setFPS(20);
// // The average and standard deviation in milliseconds of image data latency.
// cameraProp.setAvgLatencyMs(35);
// cameraProp.setLatencyStdDevMs(5);
// // sim.leftCamera = new PhotonCameraSim(leftCamera, cameraProp);
// // sim.rightCamera = new PhotonCameraSim(rightCamera, cameraProp);
// sim.leftCamera.enableRawStream(true);
// sim.leftCamera.enableProcessedStream(true);
// sim.leftCamera.enableDrawWireframe(true);
// sim.rightCamera.enableRawStream(true);
// sim.rightCamera.enableProcessedStream(true);
// sim.rightCamera.enableDrawWireframe(true);
// return sim;
// }
}
src/main/java/frc4388/robot/commands/Autos/neo AutoRecoding format.txt
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AUTO file format
HEADER static size 0x5
0x00 BYTE NUM AXES: defualts to 6
0x01 BYTE NUM POV: defualts to 1
0x02 BYTE NUM CONTROLLERS: defualts to 2
0x03 SHORT FRAMES: any value greator or equal than one.
FRAME PER CONTROLLER: defualt size 0x34
0x00 DOUBLE AXES[NUM AXES]
0x30 SHORT BUTTONS
0x32 SHORT POVs[NUM POV]
FRAME: size varrys
FRAME PER CONTROLLER[NUM CONTROLLERS]
INT UNIXTIMESTAMP
FILE:
HEADER
FRAME[FRAMES]
src/main/java/frc4388/robot/commands/Autos/neoPlaybackChooser.java
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package frc4388.robot.commands.autos;
// package frc4388.robot.commands.Autos;
// import java.io.File;
// import java.util.ArrayList;
// import java.util.HashMap;
// import edu.wpi.first.wpilibj.shuffleboard.BuiltInWidgets;
// import edu.wpi.first.wpilibj.shuffleboard.ComplexWidget;
// import edu.wpi.first.wpilibj.shuffleboard.Shuffleboard;
// import edu.wpi.first.wpilibj.smartdashboard.SendableChooser;
// import edu.wpi.first.wpilibj2.command.Command;
// import edu.wpi.first.wpilibj2.command.InstantCommand;
// import frc4388.robot.commands.Swerve.JoystickPlayback;
// import frc4388.robot.commands.Swerve.neoJoystickPlayback;
// import frc4388.robot.subsystems.SwerveDrive;
// import frc4388.utility.controller.VirtualController;
// public class neoPlaybackChooser {
// private final SendableChooser<String> m_teamChosser = new SendableChooser<String>();
// private final SendableChooser<String> m_possitionChosser = new SendableChooser<String>();
// private final SendableChooser<String> m_autoNameChosser = new SendableChooser<String>();
// private final SwerveDrive m_swerve;
// private final VirtualController[] m_controllers;
// // private final ArrayList<SendableChooser<Command>> m_choosers = new ArrayList<>();
// // private SendableChooser<Command> m_playback = null;
// private final ArrayList<ComplexWidget> m_widgets = new ArrayList<>();
// // private final HashMap<String, Command> m_commandPool = new HashMap<>();
// // private final File m_dir = new File("/home/lvuser/autos/");
// // private int m_cmdNum = 0;
// // commands
// private Command m_noAuto = new InstantCommand();
// public neoPlaybackChooser(SwerveDrive swerve, VirtualController[] controllers) {
// m_teamChosser.addOption("Red", "red");
// m_teamChosser.setDefaultOption("Blue", "blue");
// m_teamChosser.addOption("Nuetral", "nuetral");
// m_possitionChosser.addOption("AMP", "amp");
// m_possitionChosser.setDefaultOption("Center", "center");
// m_possitionChosser.addOption("Source", "source");
// m_swerve = swerve;
// m_controllers = controllers;
// }
// public neoPlaybackChooser addOption(String name, String option) {
// m_autoNameChosser.addOption(name, option);
// return this;
// }
// // public PlaybackChooser buildDisplay() {
// // for (int i = 0; i < 10; i++) {
// // appendCommand();
// // }
// // m_playback = m_choosers.get(0);
// // nextChooser();
// // // ! This does not work, why?
// // Shuffleboard.getTab("Auto Chooser")
// // .add("Add Sequence", new InstantCommand(() -> nextChooser()))
// // .withPosition(4, 0);
// // return this;
// // }
// // This will be bound to a button for the time being
// public void render() {
// // var chooser = new SendableChooser<Command>();
// // // chooser.setDefaultOption("No Auto", m_noAuto);
// // m_choosers.add(chooser);
// ComplexWidget widget = Shuffleboard.getTab("Neo Auto Chooser")
// .add("Command: " + m_choosers.size(), chooser)
// .withSize(4, 1)
// .withPosition(0, m_choosers.size() - 1)
// .withWidget(BuiltInWidgets.kSplitButtonChooser)
// .withWidget(BuiltInWidgets.kComboBoxChooser);
// m_widgets.add(widget);
// }
// // public void nextChooser() {
// // SendableChooser<Command> chooser = m_choosers.get(m_cmdNum++);
// // String[] dirs = m_dir.list();
// // if(dirs != null){ // Fix funny error
// // for (String auto : dirs) {
// // chooser.addOption(auto, new JoystickPlayback(m_swerve, auto));
// // }
// // }
// // for (var cmd_name : m_commandPool.keySet()) {
// // chooser.addOption(cmd_name, m_commandPool.get(cmd_name));
// // }
// // }
// public String autoName() {
// return m_teamChosser.getSelected() + "_" + m_possitionChosser.getSelected() + "_" + m_autoNameChosser.getSelected() + ".auto";
// }
// public Command getCommand() {
// return new neoJoystickPlayback(m_swerve, autoName(), m_controllers, true, true);
// }
// }
src/main/java/frc4388/robot/commands/MoveForTimeCommand.java
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package frc4388.robot.commands;
import java.time.Instant;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.swerve.SwerveDrive;
// Command to repeat a joystick movement for a specific time.
public class MoveForTimeCommand extends Command {
private final SwerveDrive swerveDrive;
private final Translation2d leftStick;
private final Translation2d rightStick;
private final long duration;
private final boolean robotRelative;
private Instant startTime;
public MoveForTimeCommand(
SwerveDrive swerveDrive,
Translation2d leftStick,
Translation2d rightStick,
long millis,
boolean robotRelative) {
addRequirements(swerveDrive);
this.swerveDrive = swerveDrive;
this.leftStick = leftStick;
this.rightStick = rightStick;
this.duration = millis;
this.robotRelative = robotRelative;
}
@Override
public void initialize() {
startTime = Instant.now();
}
@Override
public void execute() {
swerveDrive.driveWithInput(leftStick, rightStick, !robotRelative);
}
@Override
public boolean isFinished() {
return Math.abs(startTime.toEpochMilli() - Instant.now().toEpochMilli()) > duration;
}
}
src/main/java/frc4388/robot/commands/MoveUntilSuply.java
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package frc4388.robot.commands;
import java.util.function.Supplier;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.swerve.SwerveDrive;
// Command to repeat a joystick movement for a specific time.
public class MoveUntilSuply extends Command {
private final SwerveDrive swerveDrive;
private final Translation2d leftStick;
private final Translation2d rightStick;
private final Supplier<Boolean> truth;
private final boolean robotRelative;
public MoveUntilSuply(
SwerveDrive swerveDrive,
Translation2d leftStick,
Translation2d rightStick,
Supplier<Boolean> truth,
boolean robotRelative) {
addRequirements(swerveDrive);
this.swerveDrive = swerveDrive;
this.leftStick = leftStick;
this.rightStick = rightStick;
this.truth = truth;
this.robotRelative = robotRelative;
}
@Override
public void initialize() {
}
@Override
public void execute() {
swerveDrive.driveWithInput(leftStick, rightStick, !robotRelative);
}
@Override
public boolean isFinished() {
return truth.get();
}
}
src/main/java/frc4388/robot/commands/PID.java
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// 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.
package frc4388.robot.commands;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.utility.structs.Gains;
public abstract class PID extends Command {
protected Gains gains;
private double output = 0;
private double tolerance = 0;
/** Creates a new PelvicInflammatoryDisease. */
public PID(double kp, double ki, double kd, double kf, double tolerance) {
gains = new Gains(kp, ki, kd, kf, 0);
this.tolerance = tolerance;
}
public PID(Gains gains, double tolerance) {
this.gains = gains;
this.tolerance = tolerance;
}
/** produces the error from the setpoint */
public abstract double getError();
/** todo: javadoc */
public abstract void runWithOutput(double output);
// Called when the command is initially scheduled.
@Override
public final void initialize() {
output = 0;
}
private double prevError, cumError = 0;
// Called every time the scheduler runs while the command is scheduled.
@Override
public final void execute() {
double error = getError();
cumError += error * .02; // 20 ms
double delta = error - prevError;
output = error * gains.kP;
output += cumError * gains.kI;
output += delta * gains.kD;
output += gains.kF;
runWithOutput(output);
}
// Returns true when the command should end.
@Override
public final boolean isFinished() {
return Math.abs(getError()) < tolerance;
}
}
src/main/java/frc4388/robot/commands/Swerve/RotateToAngle.java
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// 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.
package frc4388.robot.commands.swerve;
import edu.wpi.first.math.geometry.Translation2d;
import frc4388.robot.commands.PID;
import frc4388.robot.subsystems.swerve.SwerveDrive;
public class RotateToAngle extends PID {
SwerveDrive drive;
double targetAngle;
/** Creates a new RotateToAngle. */
public RotateToAngle(SwerveDrive drive, double targetAngle) {
super(0.3, 0.0, 0.0, 0.0, 1);
this.drive = drive;
this.targetAngle = targetAngle;
addRequirements(drive);
}
@Override
public double getError() {
return targetAngle - drive.getGyroAngle();
}
@Override
public void runWithOutput(double output) {
drive.driveWithInput(new Translation2d(0.0, 0.0), new Translation2d(output / Math.abs(getError()), 0.0), true);
}
}
src/main/java/frc4388/robot/commands/Swerve/neoJoystickPlayback.java
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package frc4388.robot.commands.swerve;
import java.io.FileInputStream;
import java.util.ArrayList;
import java.util.function.Supplier;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.swerve.SwerveDrive;
import frc4388.utility.compute.DataUtils;
import frc4388.utility.controller.VirtualController;
import frc4388.utility.structs.UtilityStructs.AutoRecordingControllerFrame;
import frc4388.utility.structs.UtilityStructs.AutoRecordingFrame;
/**
* The NEO autonomus playback system, designed based the old {@link JoystickPlayback} System but with {@link VirtualController}s
* @author Zachary Wilke
*/
public class neoJoystickPlayback extends Command {
private final SwerveDrive swerve;
private final VirtualController[] controllers;
private final ArrayList<AutoRecordingFrame> frames = new ArrayList<>();
private final Supplier<String> filenameGetter;
private String filename;
private int frame_index = 0;
// private long startTime = 0;
// private long playbackTime = 0;
private boolean m_finished = false; // ! There is no better way.
private boolean m_shouldfree = false; // should free memory on ending
private byte m_numAxes = 0;
private byte m_numPOVs = 0;
private byte m_numControllers = 0;
private short m_numFrames = -1;
/**
* Creates an new NEO Joystick Playback with specifyed pramiters.
* @param swerve m_robotSwerveDrive
* @param filenameGetter a String Supplier, designed for quickly changing auto names in shuffle board.
* @param controllers an <b>Order-Specific</b> Array of Virtual controllers, index 0 means driver, index 1 means operator, etc.
* @param shouldfree Unloads the auto on compleation or intruption.
* @param instantload Load the auto on object instantiation
*/
public neoJoystickPlayback(SwerveDrive swerve, Supplier<String> filenameGetter, VirtualController[] controllers, boolean shouldfree, boolean instantload) {
this.swerve = swerve;
this.filenameGetter = filenameGetter;
this.controllers = controllers;
this.m_shouldfree = shouldfree;
if (instantload) loadAuto();
addRequirements(this.swerve);
}
/**
* Creates an new NEO Joystick Playback with specifyed pramiters.
* @param swerve m_robotSwerveDrive
* @param filename a String containing the name of the auto file you wish to playback.
* @param controllers an <b>Order-Specific</b> Array of Virtual controllers, index 0 means driver, index 1 means operator, etc.
* @param shouldfree unloads the auto on compleation or intruption.
* @param instantload load the auto on object instantiation
*/
public neoJoystickPlayback(SwerveDrive swerve, String filename, VirtualController[] controllers, boolean shouldfree, boolean instantload) {
this(swerve, () -> filename, controllers, shouldfree, instantload);
}
/**
* Creates an new NEO Joystick Playback with specifyed pramiters.
* @param swerve m_robotSwerveDrive
* @param filenameGetter a String Supplier, designed for quickly changing auto names in shuffle board.
* @param controllers an <b>Order-Specific</b> Array of Virtual controllers, index 0 means driver, index 1 means operator, etc.
*/
public neoJoystickPlayback(SwerveDrive swerve, Supplier<String> filenameGetter, VirtualController[] controllers) {
this(swerve, filenameGetter, controllers, true, false);
}
/**
* Creates an new NEO Joystick Playback with specifyed pramiters.
* @param swerve m_robotSwerveDrive
* @param filename a String containing the name of the auto file you wish to playback.
* @param controllers an <b>Order-Specific</b> Array of Virtual controllers, index 0 means driver, index 1 means operator, etc.
*/
public neoJoystickPlayback(SwerveDrive swerve, String filename, VirtualController[] controllers) {
this(swerve, () -> filename, controllers, true, false);
}
/**
* Load the auto file from disk into memory
* @return Returns true if loading was successful, else wise; return false
* @implNote if the auto is already loaded, it will return true.
*/
public boolean loadAuto() {
filename = filenameGetter.get();
try (FileInputStream stream = new FileInputStream("/home/lvuser/autos/" + filename)) {
if (m_numFrames != -1 && m_numFrames == frames.size()) {
System.out.println("AUTOPLAYBACK: Auto Already loaded.");
return true;
}
m_numAxes = stream.readNBytes(1)[0];
m_numPOVs = stream.readNBytes(1)[0];
m_numControllers = stream.readNBytes(1)[0];
m_numFrames = DataUtils.byteArrayToShort(stream.readNBytes(2));
if (m_numControllers > controllers.length) {
System.out.println("AUTOPLAYBACK: The auto file `" + filename + "` wants " + m_numControllers
+ " virtual controllers but only " + controllers.length + " were given");
return false;
}
for (int i = 0; i < m_numFrames; i++) {
AutoRecordingFrame frame = new AutoRecordingFrame();
for (int j = 0; j < m_numControllers; j++) {
AutoRecordingControllerFrame controllerFrame = new AutoRecordingControllerFrame();
double[] axes = new double[m_numAxes];
for (int k = 0; k < m_numAxes; k++) { // we love third level for loops.
axes[k] = DataUtils.byteArrayToDouble(stream.readNBytes(8));
}
short button = DataUtils.byteArrayToShort(stream.readNBytes(2));
short[] POV = new short[m_numPOVs];
for (int k = 0; k < m_numPOVs; k++) {
POV[k] = DataUtils.byteArrayToShort(stream.readNBytes(2));
}
controllerFrame.axes = axes;
controllerFrame.button = button;
controllerFrame.POV = POV;
frame.controllerFrames[j] = controllerFrame;
}
frame.timeStamp = DataUtils.byteArrayToInt(stream.readNBytes(4));
frames.add(frame);
}
System.out.println("AUTOPLAYBACK: Read Auto `" + filename + "` that is " + m_numFrames + " frames long");
return true;
} catch (Exception e) {
e.printStackTrace();
System.out.println("AUTOPLAYBACK: Unable to read auto file `" + filename + '`');
return false;
}
}
/**
* Unloads the auto.
*/
public void unloadAuto() {
System.out.println("AUTOPLAYBACK: Auto unloaded");
frames.clear();
}
@Override
public void initialize() {
// startTime = System.currentTimeMillis();
// playbackTime = 0;
frame_index = 0;
m_finished = !loadAuto();
}
@Override
public void execute() {
if (frame_index >= m_numFrames) m_finished = true;
if (m_finished) return;
// if (frame_index == 0) {
// startTime = System.currentTimeMillis();
// playbackTime = 0;
// } else {
// playbackTime = System.currentTimeMillis() - startTime;
// }
AutoRecordingFrame frame = frames.get(frame_index);
for (int i = 0; i < controllers.length; i++) {
AutoRecordingControllerFrame controllerFrame = frame.controllerFrames[i];
controllers[i].setFrame(controllerFrame.axes, controllerFrame.button, controllerFrame.POV);
if (i == 0) {
this.swerve.driveWithInput(
new Translation2d(controllers[i].getRawAxis(0), controllers[i].getRawAxis(1)),
new Translation2d(controllers[i].getRawAxis(4), controllers[i].getRawAxis(5)),
true);
}
}
frame_index++;
}
@Override
public void end(boolean interrupted) {
for (VirtualController controller : controllers) controller.zeroControls();
swerve.stopModules();
if (m_shouldfree) unloadAuto();
}
@Override
public boolean isFinished() {
return m_finished;
}
}
src/main/java/frc4388/robot/commands/Swerve/neoJoystickRecorder.java
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package frc4388.robot.commands.swerve;
import java.io.FileOutputStream;
import java.util.ArrayList;
import java.util.function.Supplier;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj.XboxController;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.swerve.SwerveDrive;
import frc4388.utility.compute.DataUtils;
import frc4388.utility.controller.DeadbandedXboxController;
import frc4388.utility.structs.UtilityStructs.AutoRecordingControllerFrame;
import frc4388.utility.structs.UtilityStructs.AutoRecordingFrame;
/**
* The NEO autonomus recording system, designed based the old {@link JoystickRecorder} System but with {@link frc4388.utility.controller.VirtualController VirtualController}s
* @author Zachary Wilke
*/
public class neoJoystickRecorder extends Command {
private final SwerveDrive swerve;
private final XboxController[] controllers;
private String filename;
private final Supplier<String> filenameGetter;
private long startTime = -1;
private final ArrayList<AutoRecordingFrame> frames = new ArrayList<>();
/**
* Creates an new NEO Joystick Playback with specifyed pramiters.
* @param swerve m_robotSwerveDrive
* @param controllers an <b>Order-Specific</b> Array of Virtual controllers, index 0 means driver, index 1 means operator, etc.
* @param filenameGetter a String Supplier, designed for quickly changing auto names in shuffle board.
*/
public neoJoystickRecorder(SwerveDrive swerve, DeadbandedXboxController[] controllers, Supplier<String> filenameGetter) {
this.swerve = swerve;
this.controllers = controllers;
this.filenameGetter = filenameGetter;
this.filename = "";
addRequirements(this.swerve);
}
/**
* Creates an new NEO Joystick Playback with specifyed pramiters.
* @param swerve m_robotSwerveDrive
* @param controllers an <b>Order-Specific</b> Array of Virtual controllers, index 0 means driver, index 1 means operator, etc.
* @param filename a String containing the name of the auto file you wish to playback.
*/
public neoJoystickRecorder(SwerveDrive swerve, DeadbandedXboxController[] controllers, String filename) {
this(swerve, controllers, () -> filename);
}
@Override
public void initialize() {
frames.clear();
this.startTime = System.currentTimeMillis();
AutoRecordingFrame frame = new AutoRecordingFrame();
frame.controllerFrames = new AutoRecordingControllerFrame[] {new AutoRecordingControllerFrame(), new AutoRecordingControllerFrame()};
frames.add(frame);
this.filename = this.filenameGetter.get();
}
@Override
public void execute() {
System.out.println("AUTORECORD: RECORDING");
AutoRecordingFrame frame = new AutoRecordingFrame();
frame.timeStamp = (int) (System.currentTimeMillis() - startTime);
for (int i = 0; i < controllers.length; i++) {
XboxController controller = controllers[i];
AutoRecordingControllerFrame controllerFrame = new AutoRecordingControllerFrame();
double[] axes = {controller.getLeftX(), controller.getLeftY(),
controller.getLeftTriggerAxis(), controller.getRightTriggerAxis(),
controller.getRightX(), controller.getRightY()};
short button = 0;
for (int j = 0; j < 10; j++)
if (controller.getRawButton(j+1))
button |= 1 << j;
short[] POV = {(short)(controller.getPOV())};
controllerFrame.axes = axes;
controllerFrame.button = button;
controllerFrame.POV = POV;
frame.controllerFrames[i] = controllerFrame;
}
frames.add(frame);
swerve.driveWithInput(new Translation2d(frame.controllerFrames[0].axes[0], frame.controllerFrames[0].axes[1]),
new Translation2d(frame.controllerFrames[0].axes[4], frame.controllerFrames[0].axes[5]),
true); // Really jank way of doing this.
}
@Override
public void end(boolean interrupted) {
try (FileOutputStream stream = new FileOutputStream("/home/lvuser/autos/" + filename)) {
// header: size of 0x5
// byte Number of axes per controller
// byte Number of POVs per controller
// byte Number of controllers
// short Number of frames
stream.write(new byte[]{6, 1, (byte) controllers.length});
stream.write(DataUtils.shortToByteArray((short) frames.size()));
// frame
// controller frame * number of controllers
// int unix time stamp.
for (AutoRecordingFrame frame : frames) {
// controller frame
// double axis * Number of axes per controller
// short button states
// short POV * Number of POVs per controller
for (AutoRecordingControllerFrame controllerFrame: frame.controllerFrames) {
for (double axis: controllerFrame.axes) {
stream.write(DataUtils.doubleToByteArray(axis));
}
stream.write(DataUtils.shortToByteArray(controllerFrame.button));
for (short POV: controllerFrame.POV) {
stream.write(DataUtils.shortToByteArray(POV));
}
}
stream.write(DataUtils.intToByteArray(frame.timeStamp));
}
System.out.println("AUTORECORD: Wrote auto `" + filename + "` that is " + frames.size() + " frames long.");
} catch (Exception e) {
e.printStackTrace();
}
}
}
src/main/java/frc4388/robot/commands/WhileTrueCommand.java
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package frc4388.robot.commands;
// 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.
import static edu.wpi.first.util.ErrorMessages.requireNonNullParam;
import edu.wpi.first.util.sendable.SendableBuilder;
import edu.wpi.first.wpilibj2.command.Command;
import java.util.function.BooleanSupplier;
/**
* A command composition that runs one of two commands, depending on the value of the given
* condition when this command is initialized.
*
* <p>The rules for command compositions apply: command instances that are passed to it cannot be
* added to any other composition or scheduled individually, and the composition requires all
* subsystems its components require.
*
* <p>This class is provided by the NewCommands VendorDep
*/
public class WhileTrueCommand extends Command {
private final Command m_whileTrue;
private final BooleanSupplier m_condition;
/**
* Creates a new WhileTrueCommand.
*
* @param whileTrue the command to run while the condition is true
* @param condition the condition to determine which command to run
*/
@SuppressWarnings("this-escape")
public WhileTrueCommand(Command whileTrue, BooleanSupplier condition) {
m_whileTrue = requireNonNullParam(whileTrue, "whileTrue", "WhileTrueCommand");
m_condition = requireNonNullParam(condition, "condition", "WhileTrueCommand");
//CommandScheduler.getInstance().registerComposedCommands(whileTrue);
// addRequirements(whileTrue.getRequirements());
}
@Override
public void initialize() {
if(m_condition.getAsBoolean())
m_whileTrue.initialize();
}
@Override
public void execute() {
m_whileTrue.execute();
System.out.println("Loop, " + !m_whileTrue.isFinished() + ", " + m_condition.getAsBoolean());
if(!m_whileTrue.isFinished())
return;
if(m_condition.getAsBoolean()){
m_whileTrue.end(false);
m_whileTrue.initialize();
}
}
@Override
public void end(boolean interrupted) {
m_whileTrue.end(interrupted);
}
@Override
public boolean isFinished() {
return !m_condition.getAsBoolean() && m_whileTrue.isFinished();
}
@Override
public boolean runsWhenDisabled() {
return m_whileTrue.runsWhenDisabled();
}
@Override
public InterruptionBehavior getInterruptionBehavior() {
if (m_whileTrue.getInterruptionBehavior() == InterruptionBehavior.kCancelSelf) {
return InterruptionBehavior.kCancelSelf;
} else {
return InterruptionBehavior.kCancelIncoming;
}
}
@Override
public void initSendable(SendableBuilder builder) {
super.initSendable(builder);
builder.addStringProperty("whileTrue", m_whileTrue::getName, null);
builder.addStringProperty(
"selected",
() -> {
if (m_whileTrue == null) {
return "null";
} else {
return m_whileTrue.getName();
}
},
null);
}
}
src/main/java/frc4388/robot/commands/alignment/DriveToReef.java
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package frc4388.robot.commands.alignment;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.math.util.Units;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.constants.Constants.AutoConstants;
import frc4388.robot.subsystems.swerve.SwerveDrive;
import frc4388.robot.subsystems.vision.Vision;
import frc4388.utility.compute.ReefPositionHelper;
import frc4388.utility.compute.TimesNegativeOne;
import frc4388.utility.compute.ReefPositionHelper.Side;
import frc4388.utility.structs.Gains;
public class DriveToReef extends Command {
// private Translation2d translation2d= new Translation2d(14.579471999999997,0.24587199999999998);
// private Translation2d translation2d= new Translation2d(16.579342-0.15,5.547867999999999);
private PID xPID = new PID(AutoConstants.XY_GAINS, 0);
private PID yPID = new PID(AutoConstants.XY_GAINS, 0);
// private PID rotPID = new PID(AutoConstants.ROT_GAINS, 0);
private Pose2d targetpos;
SwerveDrive swerveDrive;
Vision vision;
double distance;
Side side;
boolean waitVelocityZero;
/**
* Command to drive robot to position.
* @param SwerveDrive m_robotSwerveDrive
*/
public DriveToReef(SwerveDrive swerveDrive, Vision vision, double distance, Side side, boolean waitVelocityZero) {
this.swerveDrive = swerveDrive;
this.vision = vision;
this.distance = distance;
this.side = side;
this.waitVelocityZero = waitVelocityZero && false;
addRequirements(swerveDrive);
}
public static double tagRelativeXError = -1;
private static void setTagRelativeXError(double val){
tagRelativeXError = val;
}
@Override
public void initialize() {
xPID.initialize();
yPID.initialize();
this.targetpos = ReefPositionHelper.getNearestPosition(
this.vision.getPose2d(),
side,
Units.inchesToMeters(AutoConstants.X_OFFSET_TRIM.get()),
distance + Units.inchesToMeters(AutoConstants.Y_OFFSET_TRIM.get())
);
}
double xerr;
double yerr;
double roterr;
double xoutput;
double youtput;
double rotoutput;
@Override
public void execute() {
xerr = TimesNegativeOne.invert(targetpos.getX() - vision.getPose2d().getX(), TimesNegativeOne.XAxis);
yerr = TimesNegativeOne.invert(targetpos.getY() - vision.getPose2d().getY(), !TimesNegativeOne.YAxis);
// xerr = targetpos.getX() - vision.getPose2d().getX();
// yerr = targetpos.getX() - vision.getPose2d().getY();
// roterr = TimesNegativeOne.invert(targetpos.getRotation().getDegrees() - vision.getPose2d().getRotation().getDegrees(), TimesNegativeOne.isRed);
roterr = ((targetpos.getRotation().getDegrees() - vision.getPose2d().getRotation().getDegrees()));
if(roterr > 180){
roterr -= 360;
}else if(roterr < -180){
roterr += 360;
}
// SmartDashboard.putNumber("Rotational PID target", targetpos.getRotation().getDegrees());
// SmartDashboard.putNumber("Rotational PID position", vision.getPose2d().getRotation().getDegrees());
// SmartDashboard.putNumber("Rotational PID error", roterr);
SmartDashboard.putNumber("PID X Error", xerr);
SmartDashboard.putNumber("PID Y Error", yerr);
SmartDashboard.putNumber("PID Rot Error", roterr);
xoutput = xPID.update(xerr);
youtput = yPID.update(yerr);
// rotoutput = rotPID.update(roterr);
xoutput *= Math.abs(xerr) < AutoConstants.XY_TOLERANCE ? 0 : 1;
youtput *= Math.abs(yerr) < AutoConstants.XY_TOLERANCE ? 0 : 1;
// rotoutput *= Math.abs(roterr) < AutoConstants.ROT_TOLERANCE ? 0 : 1;
Translation2d leftStick = new Translation2d(
Math.max(Math.min(-youtput, 1), -1),
Math.max(Math.min(-xoutput, 1), -1)
// 0,0
);
// Translation2d rightStick = new Translation2d(
// Math.max(Math.min(rotoutput, 1), -1),
// 0
// );
setTagRelativeXError(
new Translation2d(xerr, yerr).getAngle()
.rotateBy(targetpos.getRotation())
.getCos());
swerveDrive.driveRelativeAngle(leftStick, targetpos.getRotation());
// swerveDrive.driveWithInputOrientation(leftStick, rightStick, true);
}
@Override
public final boolean isFinished() {
boolean finished = (
(Math.abs(xerr) < AutoConstants.XY_TOLERANCE || Math.abs(xoutput) <= AutoConstants.MIN_XY_PID_OUTPUT) &&
(Math.abs(yerr) < AutoConstants.XY_TOLERANCE || Math.abs(youtput) <= AutoConstants.MIN_XY_PID_OUTPUT) &&
(Math.abs(roterr) < AutoConstants.ROT_TOLERANCE) &&
(!waitVelocityZero || swerveDrive.lastOdomSpeed < AutoConstants.VELOCITY_THRESHHOLD)
);
// System.out.println(finished);
if(finished)
swerveDrive.softStop();
return finished;
// this statement is a boolean in and of itself
}
private class PID {
protected Gains gains;
private double output = 0;
/** Creates a new PelvicInflammatoryDisease. */
public PID(Gains gains, double tolerance) {
this.gains = gains;
}
// Called when the command is initially scheduled.
public final void initialize() {
output = 0;
}
private double prevError, cumError = 0;
// Called every time the scheduler runs while the command is scheduled.
public double update(double error) {
cumError += error * .02; // 20 ms
double delta = error - prevError;
output = error * gains.kP;
output += cumError * gains.kI;
output += delta * gains.kD;
output += gains.kF;
return output;
}
}
}
src/main/java/frc4388/robot/commands/alignment/DriveUntilLiDAR.java
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package frc4388.robot.commands.alignment;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.lidar.LiDAR;
import frc4388.robot.subsystems.swerve.SwerveDrive;
// Command to repeat a joystick movement for a specific time.
public class DriveUntilLiDAR extends Command {
private final SwerveDrive swerveDrive;
private final Translation2d leftStick;
private final Translation2d rightStick;
private final LiDAR m_lidar;
private final double mindistance;
public DriveUntilLiDAR(
SwerveDrive swerveDrive,
Translation2d leftStick,
Translation2d rightStick,
LiDAR lidar,
double mindistance) {
addRequirements(swerveDrive);
this.swerveDrive = swerveDrive;
this.leftStick = leftStick;
this.rightStick = rightStick;
this.m_lidar = lidar;
this.mindistance = mindistance;
}
@Override
public void initialize() {
}
@Override
public void execute() {
swerveDrive.driveFine(leftStick, rightStick, 0.3);
}
@Override
public boolean isFinished() {
if (Math.abs(m_lidar.getDistance()) < mindistance) {
swerveDrive.softStop();
return true;
}
return false;
}
}
src/main/java/frc4388/robot/commands/alignment/LidarAlign.java
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// 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.
package frc4388.robot.commands.alignment;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.lidar.LiDAR;
import frc4388.robot.subsystems.swerve.SwerveDrive;
/* You should consider using the more terse Command factories API instead https://docs.wpilib.org/en/stable/docs/software/commandbased/organizing-command-based.html#defining-commands */
public class LidarAlign extends Command {
private SwerveDrive swerveDrive;
private LiDAR lidar;
private int currentFinderTick;
// private int tickFoundPipe;
private boolean foundReef;
private boolean headedRight;
private double speed;
private int bounces;
private double additionalDistance = 0;
// private final boolean constructedHeadedRight;
/** Creates a new LidarAlign. */
public LidarAlign(SwerveDrive swerveDrive, LiDAR lidar) {//, boolean headedRight) {
// Use addRequirements() here to declare subsystem dependencies.
this.swerveDrive = swerveDrive;
this.lidar = lidar;
addRequirements(swerveDrive, lidar);
}
// Called when the command is initially scheduled.
@Override
public void initialize() {
this.currentFinderTick = 0;
this.speed = 0.4; // TODO: find good speed for this
this.foundReef = false;
this.headedRight = (DriveToReef.tagRelativeXError < 0);
this.additionalDistance = 0;
this.bounces = 0;
}
// Called every time the scheduler runs while the command is scheduled.
@Override
public void execute() {
if (lidar.withinDistance()) {
swerveDrive.softStop();
foundReef = true;
return;
}
if (currentFinderTick > (15 + additionalDistance)) { //arbutrary threshhold for now.
headedRight = !headedRight;
currentFinderTick *= -1;
bounces++;
additionalDistance += 5;
if (bounces == 5) return;
}
double currentHeading = (swerveDrive.getGyroAngle() * 180) / Math.PI;
double relAngle = (Math.round(currentHeading / 60.d) * 60); // Relative driving to the side of the reef
SmartDashboard.putNumber("Rel Angle", relAngle);
SmartDashboard.putNumber("heading", currentHeading);
if (!headedRight) {
swerveDrive.driveRelativeLockedAngle(new Translation2d(0, -speed), Rotation2d.fromDegrees(relAngle));
} else {
swerveDrive.driveRelativeLockedAngle(new Translation2d(0, speed), Rotation2d.fromDegrees(relAngle));
}
currentFinderTick++;
}
// Called once the command ends or is interrupted.
@Override
public void end(boolean interrupted) {
}
// Returns true when the command should end.
@Override
public boolean isFinished() {
if (lidar.getDistance() < 4) {
swerveDrive.stopModules();
return true;
} else if (foundReef && lidar.withinDistance()) { // spot on
swerveDrive.stopModules();
return true;
} else if (foundReef && !lidar.withinDistance()) { // over shot
speed = speed / 2;
headedRight = !headedRight;
currentFinderTick = 0;
foundReef = false;
return false;
} else if (bounces >= 3) {
swerveDrive.stopModules();
return true;
} else {
return false;
}
}
}
src/main/java/frc4388/robot/commands/wait/waitElevatorRefrence.java
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// 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.
package frc4388.robot.commands.wait;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.elevator.Elevator;
/* You should consider using the more terse Command factories API instead https://docs.wpilib.org/en/stable/docs/software/commandbased/organizing-command-based.html#defining-commands */
public class waitElevatorRefrence extends Command {
/** Creates a new waitElevatorRefrence. */
private Elevator elevator;
public waitElevatorRefrence(Elevator elevator) {
this.elevator = elevator;
// Use addRequirements() here to declare subsystem dependencies.
}
// Called when the command is initially scheduled.
@Override
public void initialize() {}
// Called every time the scheduler runs while the command is scheduled.
@Override
public void execute() {}
// Called once the command ends or is interrupted.
@Override
public void end(boolean interrupted) {}
// Returns true when the command should end.
@Override
public boolean isFinished() {
return elevator.elevatorAtReference();
}
}
src/main/java/frc4388/robot/commands/wait/waitEndefectorRefrence.java
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// 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.
package frc4388.robot.commands.wait;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.elevator.Elevator;
/* You should consider using the more terse Command factories API instead https://docs.wpilib.org/en/stable/docs/software/commandbased/organizing-command-based.html#defining-commands */
public class waitEndefectorRefrence extends Command {
/** Creates a new waitElevatorRefrence. */
private Elevator elevator;
public waitEndefectorRefrence(Elevator elevator) {
this.elevator = elevator;
// Use addRequirements() here to declare subsystem dependencies.
}
// Called when the command is initially scheduled.
@Override
public void initialize() {}
// Called every time the scheduler runs while the command is scheduled.
@Override
public void execute() {}
// Called once the command ends or is interrupted.
@Override
public void end(boolean interrupted) {}
// Returns true when the command should end.
@Override
public boolean isFinished() {
return elevator.endeffectorAtReference();
}
}
src/main/java/frc4388/robot/commands/wait/waitFeedCoral.java
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// 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.
package frc4388.robot.commands.wait;
import edu.wpi.first.wpilibj2.command.Command;
import frc4388.robot.subsystems.elevator.Elevator;
/* You should consider using the more terse Command factories API instead https://docs.wpilib.org/en/stable/docs/software/commandbased/organizing-command-based.html#defining-commands */
public class waitFeedCoral extends Command {
/** Creates a new waitElevatorRefrence. */
private Elevator elevator;
public waitFeedCoral(Elevator elevator) {
this.elevator = elevator;
// Use addRequirements() here to declare subsystem dependencies.
}
// Called when the command is initially scheduled.
@Override
public void initialize() {}
// Called every time the scheduler runs while the command is scheduled.
@Override
public void execute() {}
// Called once the command ends or is interrupted.
@Override
public void end(boolean interrupted) {}
// Returns true when the command should end.
@Override
public boolean isFinished() {
return elevator.hasCoral();
}
}
src/main/java/frc4388/robot/commands/wait/waitSupplier.java
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// 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.
package frc4388.robot.commands.wait;
import java.util.function.Supplier;
import edu.wpi.first.wpilibj2.command.Command;
/* You should consider using the more terse Command factories API instead https://docs.wpilib.org/en/stable/docs/software/commandbased/organizing-command-based.html#defining-commands */
public class waitSupplier extends Command {
/** Creates a new waitSupplier. */
private final Supplier<Boolean> truth;
public waitSupplier(Supplier<Boolean> truth) {
this.truth = truth;
}
// Called when the command is initially scheduled.
@Override
public void initialize() {}
// Called every time the scheduler runs while the command is scheduled.
@Override
public void execute() {}
// Called once the command ends or is interrupted.
@Override
public void end(boolean interrupted) {}
// Returns true when the command should end.
@Override
public boolean isFinished() {
return truth.get();
}
}
src/main/java/frc4388/robot/constants/BuildConstants.java
+19
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package frc4388.robot.constants;
/**
* Automatically generated file containing build version information.
*/
public final class BuildConstants {
public static final String MAVEN_GROUP = "";
public static final String MAVEN_NAME = "2025RidgeScape";
public static final String VERSION = "unspecified";
public static final int GIT_REVISION = 173;
public static final String GIT_SHA = "2b7bb1224195b9e001e60b895ee04d63abdfc513";
public static final String GIT_DATE = "2025-07-17 09:15:19 MDT";
public static final String GIT_BRANCH = "advantagekit";
public static final String BUILD_DATE = "2025-07-17 11:55:31 MDT";
public static final long BUILD_UNIX_TIME = 1752774931371L;
public static final int DIRTY = 1;
private BuildConstants(){}
}
src/main/java/frc4388/robot/constants/Constants.java
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2018-2019 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. */
/*----------------------------------------------------------------------------*/
package frc4388.robot.constants;
import com.ctre.phoenix6.configs.Slot0Configs;
import edu.wpi.first.apriltag.AprilTagFieldLayout;
import edu.wpi.first.apriltag.AprilTagFields;
import edu.wpi.first.math.Matrix;
import edu.wpi.first.math.VecBuilder;
import edu.wpi.first.math.geometry.Rotation3d;
import edu.wpi.first.math.geometry.Transform3d;
import edu.wpi.first.math.geometry.Translation3d;
import edu.wpi.first.math.numbers.N1;
import edu.wpi.first.math.numbers.N3;
import edu.wpi.first.math.util.Units;
import edu.wpi.first.wpilibj.RobotBase;
import frc4388.utility.compute.Trim;
import frc4388.utility.status.CanDevice;
import frc4388.utility.structs.Gains;
import frc4388.utility.structs.LEDPatterns;
/**
* The Constants class provides a convenient place for teams to hold robot-wide numerical or boolean
* constants. This class should not be used for any other purpose. All constants should be
* declared globally (i.e. public static). Do not put anything functional in this class.
*
* <p>It is advised to statically import this class (or one of its inner classes) wherever the
* constants are needed, to reduce verbosity.
*/
public final class Constants {
public static final String CANBUS_NAME = "rio";
public static final class LiDARConstants {
public static final int REEF_LIDAR_DIO_CHANNEL = 7;
public static final int REVERSE_LIDAR_DIO_CHANNEL = 4;
public static final int HUMAN_PLAYER_STATION_DISTANCE = 40;
public static final int LIDAR_DETECT_DISTANCE = 100; // Min distance to detect pole
public static final int LIDAR_MICROS_TO_CM = 10;
public static final int SECONDS_TO_MICROS = 1000000;
}
public static final class AutoConstants {
// public static final Gains XY_GAINS = new Gains(5,0.6,0.0);
public static final Gains XY_GAINS = new Gains(8,0,0.0);
// public static final ConfigurableDouble P_XY_GAINS = new ConfigurableDouble("P_XY_GAINS", XY_GAINS.kP);
// public static final ConfigurableDouble I_XY_GAINS = new ConfigurableDouble("I_XY_GAINS", XY_GAINS.kI);
// public static final ConfigurableDouble D_XY_GAINS = new ConfigurableDouble("D_XY_GAINS", XY_GAINS.kD);
// public static final Gains XY_GAINS = new Gains(3,0.3,0.0);
// public static final Gains ROT_GAINS = new Gains(0.05,0,0.007);
// public static final Gains ROT_GAINS = new Gains(0.05,0,0.0);
public static final Trim X_OFFSET_TRIM = new Trim("X Offset Trim", Double.MAX_VALUE, -Double.MAX_VALUE,0.5, 0);
// public static final Trim Y_OFFSET_TRIM = new Trim("Y Offset Trim", Double.MAX_VALUE, -Double.MAX_VALUE, 0.5, 1.5);
public static final Trim Y_OFFSET_TRIM = new Trim("Y Offset Trim", Double.MAX_VALUE, -Double.MAX_VALUE, 0.5, 0);
public static final double XY_TOLERANCE = 0.07; // Meters
public static final double ROT_TOLERANCE = 5; // Degrees
public static final double MIN_XY_PID_OUTPUT = 0.0;
public static final double MIN_ROT_PID_OUTPUT = 0.0;
public static final double VELOCITY_THRESHHOLD = 0.01;
}
public static final class VisionConstants {
public static final String LEFT_CAMERA_NAME = "CAMERA_LEFT";
public static final String RIGHT_CAMERA_NAME = "CAMERA_RIGHT";
public static final Transform3d LEFT_CAMERA_POS = new Transform3d(new Translation3d(Units.inchesToMeters(4.547), Units.inchesToMeters(8.031), Units.inchesToMeters(8.858)), new Rotation3d(0,0.0,0.0));
public static final Transform3d RIGHT_CAMERA_POS = new Transform3d(new Translation3d(Units.inchesToMeters(4.547), -Units.inchesToMeters(8.031), Units.inchesToMeters(8.858)), new Rotation3d(0,0.0,0.0));
public static final double MIN_ESTIMATION_DISTANCE = 2; // Meters
// Photonvision thing
// The standard deviations of our vision estimated poses, which affect correction rate
// X, Y, Theta
// https://www.chiefdelphi.com/t/photonvision-finding-standard-deviations-for-swervedriveposeestimator/467802/2
public static final Matrix<N3, N1> kSingleTagStdDevs = VecBuilder.fill(0.5, 0.5, 4);
public static final Matrix<N3, N1> kMultiTagStdDevs = VecBuilder.fill(0.1, 0.1, 1);
}
public static final class FieldConstants {
public static final AprilTagFieldLayout kTagLayout = AprilTagFieldLayout.loadField(AprilTagFields.k2025ReefscapeWelded);
// Test april tag field layout
// public static final AprilTagFieldLayout kTagLayout = new AprilTagFieldLayout(
// Arrays.asList(new AprilTag[] {
// new AprilTag(1, new Pose3d(
// new Translation3d(0.,0.,0.26035), new Rotation3d(0.,0.,0.)
// )),
// }), 100, 100);
}
public static final class LEDConstants {
public static final int LED_SPARK_ID = 9;
public static final LEDPatterns DEFAULT_PATTERN = LEDPatterns.FOREST_WAVES;
public static final LEDPatterns WAITING_PATTERN = LEDPatterns.SOLID_RED;
public static final LEDPatterns DOWN_PATTERN = LEDPatterns.SOLID_YELLOW;
public static final LEDPatterns READY_PATTERN = LEDPatterns.SOLID_GREEN_DARK;
public static final LEDPatterns SCORING_PATTERN = LEDPatterns.RAINBOW_RAINBOW;
public static final LEDPatterns RED_PATTERN = LEDPatterns.LAVA_WAVES;
public static final LEDPatterns BLUE_PATTERN = LEDPatterns.OCEAN_WAVES;
}
public static final class OIConstants {
public static final int XBOX_DRIVER_ID = 0;
public static final int XBOX_OPERATOR_ID = 1;
public static final int BUTTONBOX_ID = 2;
public static final int XBOX_PROGRAMMER_ID = 3;
public static final double LEFT_AXIS_DEADBAND = 0.1;
}
// Logging constants
public static class SimConstants {
public static final Mode simMode = Mode.SIM;
public static final Mode currentMode = RobotBase.isReal() ? Mode.REAL : simMode;
public static enum Mode {
/** Running on a real robot. */
REAL,
/** Running a physics simulator. */
SIM,
/** Replaying from a log file. */
REPLAY
}
}
}
src/main/java/frc4388/robot/subsystems/LED.java
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2018 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. */
/*----------------------------------------------------------------------------*/
package frc4388.robot.subsystems;
import org.littletonrobotics.junction.AutoLogOutput;
import edu.wpi.first.wpilibj.DriverStation;
import edu.wpi.first.wpilibj.motorcontrol.Spark;
import edu.wpi.first.wpilibj2.command.SubsystemBase;
import frc4388.robot.constants.Constants.LEDConstants;
import frc4388.utility.status.Status;
import frc4388.utility.status.FaultReporter;
import frc4388.utility.status.Queryable;
import frc4388.utility.status.Status.ReportLevel;
import frc4388.utility.structs.LEDPatterns;
/**
* Allows for the control of a 5v LED Strip using a Rev Robotics Blinkin LED
* Driver
*/
public class LED extends SubsystemBase implements Queryable {
public LED() {
FaultReporter.register(this);
}
private static Spark LEDController = new Spark(LEDConstants.LED_SPARK_ID);
private LEDPatterns mode = LEDConstants.DEFAULT_PATTERN;
public void setMode(LEDPatterns pattern){
this.mode = pattern;
}
@Override
public void periodic() {
update();
}
public void update() {
if(!LEDController.isAlive() || LEDController.isSafetyEnabled()) return;
if(DriverStation.isDisabled()){
LEDController.set(LEDConstants.DEFAULT_PATTERN.getValue());
}else
LEDController.set(mode.getValue());
}
@AutoLogOutput
public String state() {
return mode.getClass().toString();
}
@Override
public String getName() {
return "LEDs";
}
@Override
public Status diagnosticStatus() {
Status status = new Status();
if(!LEDController.isAlive())
status.addReport(ReportLevel.ERROR, "LED is DISCONNECTED");
status.addReport(ReportLevel.INFO, "LED Mode: " + mode.name());
return status;
}
}
src/main/java/frc4388/robot/subsystems/lidar/LiDAR.java
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package frc4388.robot.subsystems.lidar;
import org.littletonrobotics.junction.Logger;
import edu.wpi.first.wpilibj2.command.SubsystemBase;
import frc4388.robot.constants.Constants.LiDARConstants;
import frc4388.utility.status.Status;
import frc4388.utility.status.FaultReporter;
import frc4388.utility.status.Queryable;
import frc4388.utility.status.Status.ReportLevel;
public class LiDAR extends SubsystemBase implements Queryable {
LidarIO io;
LidarStateAutoLogged state = new LidarStateAutoLogged();
private String name = "Lidar";
public LiDAR(LidarIO device, String name) {
FaultReporter.register(this);
this.io = device;
this.name = name;
}
@Override
public void periodic() {
io.updateInputs(state);
Logger.processInputs("LiDAR/"+name, state);
}
// @AutoLogOutput(key = "Lidar/{name}")
public double getDistance(){
return state.distance;
}
public boolean withinDistance(){
if(state.distance == -1) return false;
return state.distance < LiDARConstants.LIDAR_DETECT_DISTANCE;
}
@Override
public String getName() {
return "Lidar " + name;
}
@Override
public Status diagnosticStatus() {
Status s = new Status();
if(state.distance == -1)
s.addReport(ReportLevel.ERROR, "LiDAR DISCONNECTED");
s.addReport(ReportLevel.INFO, "LiDAR Distance: " + state.distance);
return s;
}
}
src/main/java/frc4388/robot/subsystems/lidar/LidarIO.java
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package frc4388.robot.subsystems.lidar;
import org.littletonrobotics.junction.AutoLog;
public interface LidarIO {
@AutoLog
public class LidarState {
public boolean connected;
public double distance;
}
public default void updateInputs(LidarState state) {}
}
src/main/java/frc4388/robot/subsystems/lidar/LidarReal.java
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package frc4388.robot.subsystems.lidar;
import edu.wpi.first.wpilibj.Counter;
import frc4388.robot.constants.Constants.LiDARConstants;
// https://girlsofsteeldocs.readthedocs.io/en/latest/technical-resources/sensors/LIDAR-Lite-Distance-Sensor.html#minimal-roborio-interface
public class LidarReal implements LidarIO {
private Counter LidarPWM;
public LidarReal(int port) {
LidarPWM = new Counter(port);
LidarPWM.setMaxPeriod(1.00); //set the max period that can be measured
LidarPWM.setSemiPeriodMode(true); //Set the counter to period measurement
LidarPWM.reset();
}
@Override
public void updateInputs(LidarState state) {
if(LidarPWM.get() < 1)
state.distance = -1;
else
state.distance = (LidarPWM.getPeriod() * LiDARConstants.SECONDS_TO_MICROS) / LiDARConstants.LIDAR_MICROS_TO_CM;
}
}
src/main/java/frc4388/robot/subsystems/swerve/SwerveDrive.java
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// 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.
package frc4388.robot.subsystems.swerve;
import org.littletonrobotics.junction.AutoLogOutput;
import org.littletonrobotics.junction.Logger;
import com.ctre.phoenix6.swerve.SwerveRequest;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.math.kinematics.ChassisSpeeds;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import edu.wpi.first.wpilibj2.command.SubsystemBase;
import frc4388.robot.constants.Constants.AutoConstants;
import frc4388.robot.subsystems.vision.Vision;
import frc4388.utility.compute.TimesNegativeOne;
import frc4388.utility.status.Status;
import frc4388.utility.status.FaultReporter;
import frc4388.utility.status.Queryable;
import com.pathplanner.lib.controllers.PPHolonomicDriveController;
import com.pathplanner.lib.util.PathPlannerLogging;
import com.pathplanner.lib.config.PIDConstants;
import com.pathplanner.lib.auto.AutoBuilder;
import com.pathplanner.lib.config.RobotConfig;
public class SwerveDrive extends SubsystemBase implements Queryable {
// private SwerveDrivetrain<TalonFX, TalonFX, CANcoder> swerveDriveTrain;
private SwerveIO io;
private SwerveStateAutoLogged state;
private Vision vision;
public int gear_index = SwerveDriveConstants.STARTING_GEAR;
public boolean stopped = false;
public boolean robotKnowsWhereItIs = false;
public double speedAdjust = SwerveDriveConstants.MAX_SPEED_MEETERS_PER_SEC * SwerveDriveConstants.GEARS[gear_index];
public double rotSpeedAdjust = SwerveDriveConstants.MAX_ROT_SPEED;
public double autoSpeedAdjust = SwerveDriveConstants.MAX_SPEED_MEETERS_PER_SEC * 0.25; // cap auto performance to
// 25%
public double lastOdomSpeed;
public Pose2d initalPose2d = new Pose2d();
public double rotTarget = 0.0;
public Rotation2d orientRotTarget = new Rotation2d();
public ChassisSpeeds chassisSpeeds = new ChassisSpeeds();
/** Creates a new SwerveDrive. */
public SwerveDrive(SwerveIO swerveDriveTrain, Vision vision) {
// public SwerveDrive(SwerveDrivetrain<TalonFX, TalonFX, CANcoder>
// swerveDriveTrain) {
FaultReporter.register(this);
this.io = swerveDriveTrain;
this.state = new SwerveStateAutoLogged();
this.vision = vision;
RobotConfig config;
try {
config = RobotConfig.fromGUISettings();
} catch (Exception e) {
// Handle exception as needed
config = null;
}
// DoubleSupplier a = () -> 1.d;
AutoBuilder.configure(
() -> {
return getPose2d();
}, // Robot pose supplier
this::setOdoPose, // Method to reset odometry (will be called if your auto has a starting
// pose)
() -> state.speeds, // ChassisSpeeds supplier. MUST BE ROBOT RELATIVE
(speeds, feedforwards) -> io.setControl(new SwerveRequest.ApplyRobotSpeeds()
.withSpeeds(speeds)), // Method that will drive the robot given ROBOT RELATIVE ChassisSpeeds.
// Also optionally outputs individual module feedforwards
new PPHolonomicDriveController( // PPHolonomicController is the built in path following controller for
// holonomic drive trains
new PIDConstants(5.0, 0.0, 0.0), // Translation PID constants
new PIDConstants(5.0, 0.0, 0.0) // Rotation PID constants
),
config, // The robot configuration
() -> {
// Boolean supplier that controls when the path will be mirrored for the red
// alliance
// This will flip the path being followed to the red side of the field.
// THE ORIGIN WILL REMAIN ON THE BLUE SIDE
// var alliance = DriverStation.getAlliance();
// if (alliance.isPresent()) {
// return alliance.get() == DriverStation.Alliance.Red;
// }
return TimesNegativeOne.isRed;
},
this // Reference to this subsystem to set requirements
);
PathPlannerLogging.setLogActivePathCallback(
(activePath) -> {
Logger.recordOutput(
"Odometry/Trajectory", activePath.toArray(new Pose2d[activePath.size()]));
});
PathPlannerLogging.setLogTargetPoseCallback(
(targetPose) -> {
Logger.recordOutput("Odometry/TrajectorySetpoint", targetPose);
});
// // Configure SysId
// sysId =
// new SysIdRoutine(
// new SysIdRoutine.Config(
// null,
// null,
// null,
// (state) -> Logger.recordOutput("Drive/SysIdState", toString())),
// new SysIdRoutine.Mechanism(
// (voltage) -> runCharacterization(voltage.in(Volts)), null, this));
}
public void setOdoPose(Pose2d pose) {
if (pose == null) return;
initalPose2d = pose;
io.resetPose(pose);
}
// public void oneModuleTest(SwerveModule module, Translation2d leftStick,
// Translation2d rightStick){
// // double ang = Math.atan2(rightStick.getY(), rightStick.getX());
// // rightStick.getAngle()
// double speed = Math.sqrt(Math.pow(leftStick.getX(), 2) +
// Math.pow(leftStick.getY(), 2));
// // System.out.println(ang);
// // module.go(ang);
// // Rotation2d rot = Rotation2d.fromRadians(ang);
// Rotation2d rot = new Rotation2d(rightStick.getX(), rightStick.getY());
// SwerveModuleState state = new SwerveModuleState(speed, rot);
// module.setDesiredState(state);
// }
public void driveWithInput(Translation2d leftStick, Translation2d rightStick, boolean fieldRelative) {
if (rightStick.getNorm() < 0.05 && leftStick.getNorm() < 0.05 && stopped == false) // if no imput and the swerve drive is still going:
stopModules(); // stop the swerve
if (rightStick.getNorm() < 0.05 && leftStick.getNorm() < 0.05) // if no imput
return; // don't bother doing swerve drive math and return early.
leftStick = leftStick.rotateBy(TimesNegativeOne.ForwardOffset);
stopped = false;
if (fieldRelative) {
leftStick = TimesNegativeOne.invert(leftStick, TimesNegativeOne.XAxis, TimesNegativeOne.YAxis);
rightStick = TimesNegativeOne.invert(rightStick, TimesNegativeOne.RotAxis);
// ! drift correction
if (rightStick.getNorm() > 0.05 || !SwerveDriveConstants.DRIFT_CORRECTION_ENABLED) {
rotTarget = state.currentPose.getRotation().getDegrees();
io.setControl(new SwerveRequest.FieldCentric()
.withVelocityX(leftStick.getX() * speedAdjust)
.withVelocityY(leftStick.getY() * speedAdjust)
.withRotationalRate(rightStick.getX() * rotSpeedAdjust));
// .withForwardPerspective(ForwardPerspectiveValue.OperatorPerspective));
SmartDashboard.putBoolean("drift correction", false);
} else {
var ctrl = new SwerveRequest.FieldCentricFacingAngle()
.withVelocityX(leftStick.getX() * speedAdjust)
.withVelocityY(leftStick.getY() * speedAdjust)
.withTargetDirection(Rotation2d.fromDegrees(rotTarget));
ctrl.HeadingController.setPID(
SwerveDriveConstants.PIDConstants.DRIFT_CORRECTION_GAINS.kP,
SwerveDriveConstants.PIDConstants.DRIFT_CORRECTION_GAINS.kI,
SwerveDriveConstants.PIDConstants.DRIFT_CORRECTION_GAINS.kD
);
io.setControl(ctrl);
SmartDashboard.putBoolean("drift correction", true);
}
} else { // Create robot-relative speeds.
io.setControl(new SwerveRequest.RobotCentric()
.withVelocityX(leftStick.getX() * speedAdjust)
.withVelocityY(-leftStick.getY() * speedAdjust)
.withRotationalRate(rightStick.getX() * rotSpeedAdjust));
}
}
public void driveFine(Translation2d leftStick, Translation2d rightStick, double percentOutput) {
stopped = false;
// Create robot-relative speeds.
if (rightStick.getNorm() > 0.1) rightStick = rightStick.times(0);
io.setControl(new SwerveRequest.RobotCentric()
.withVelocityX(leftStick.getX() * SwerveDriveConstants.MAX_SPEED_MEETERS_PER_SEC * percentOutput)
.withVelocityY(-leftStick.getY() * SwerveDriveConstants.MAX_SPEED_MEETERS_PER_SEC * percentOutput)
.withRotationalRate(rightStick.getX() * rotSpeedAdjust));
}
public void driveWithInputOrientation(Translation2d leftStick, Translation2d rightStick) { // there is no practical
// reason to have a robot
// relitive version of
// this, and no pre
// provided version
if (rightStick.getNorm() < 0.05 && leftStick.getNorm() < 0.05 && stopped == false) // if no imput and the swerve
// drive is still going:
stopModules(); // stop the swerve
if (rightStick.getNorm() < 0.05 && leftStick.getNorm() < 0.05) // if no imput
return; // don't bother doing swerve drive math and return early.
leftStick.rotateBy(TimesNegativeOne.ForwardOffset);
io.setControl(new SwerveRequest.FieldCentricFacingAngle()
.withVelocityX(leftStick.getX() * speedAdjust)
.withVelocityY(leftStick.getY() * speedAdjust)
.withTargetDirection(rightStick.getAngle()));
}
public void driveRelativeAngle(Translation2d leftStick, Rotation2d heading) {
leftStick = leftStick.rotateBy(TimesNegativeOne.ForwardOffset);
leftStick = TimesNegativeOne.invert(leftStick, TimesNegativeOne.XAxis, TimesNegativeOne.YAxis);
var ctrl = new SwerveRequest.FieldCentricFacingAngle()
.withVelocityX(leftStick.getX() * speedAdjust)
.withVelocityY(leftStick.getY() * speedAdjust)
.withTargetDirection(heading);
ctrl.HeadingController.setPID(
SwerveDriveConstants.PIDConstants.RELATIVE_LOCKED_ANGLE_GAINS.kP,
SwerveDriveConstants.PIDConstants.RELATIVE_LOCKED_ANGLE_GAINS.kI,
SwerveDriveConstants.PIDConstants.RELATIVE_LOCKED_ANGLE_GAINS.kD
);
io.setControl(ctrl);
}
public void driveRelativeLockedAngle(Translation2d leftStick, Rotation2d heading) {
leftStick = leftStick.rotateBy(heading);
var ctrl = new SwerveRequest.FieldCentricFacingAngle()
.withVelocityX(leftStick.getX() * speedAdjust)
.withVelocityY(leftStick.getY() * speedAdjust)
.withTargetDirection(heading);
// ctrl.HeadingController.setPID(
// DriveConstants.PIDConstants.RELATIVE_LOCKED_ANGLE_GAINS.kP,
// DriveConstants.PIDConstants.RELATIVE_LOCKED_ANGLE_GAINS.kI,
// DriveConstants.PIDConstants.RELATIVE_LOCKED_ANGLE_GAINS.kD
// );
io.setControl(ctrl);
}
public void activateLuigiMode() {
io.setLimits(20);
}
public void deactivateLuigiMode() {
io.setLimits(SwerveDriveConstants.Configurations.SLIP_CURRENT);
}
public boolean rotateToTarget(double angle) {
io.setControl(new SwerveRequest.FieldCentricFacingAngle()
.withVelocityX(0)
.withVelocityY(0)
.withTargetDirection(Rotation2d.fromDegrees(angle)));
if (Math.abs(angle - getGyroAngle()) < 5.0) {
return true;
}
return false;
}
public boolean isStopped() {
return lastOdomSpeed < AutoConstants.STOP_VELOCITY;
}
public void driveWithInputRotation(Translation2d leftStick, Rotation2d rot) {
// if (leftStick.getNorm() < 0.05 && stopped == false) // if no imput and the
// swerve drive is still going:
// stopModules(); // stop the swerve
// if (leftStick.getNorm() < 0.05) //if no imput
// return; // don't bother doing swerve drive math and return early.
leftStick = leftStick.rotateBy(TimesNegativeOne.ForwardOffset);
io.setControl(new SwerveRequest.FieldCentricFacingAngle()
.withVelocityX(leftStick.getX() * -speedAdjust)
.withVelocityY(leftStick.getY() * speedAdjust)
.withTargetDirection(rot));
// double
}
public double getGyroAngle() {
return getPose2d().getRotation().getRadians();
}
public Pose2d getPose2d() {
if(state.currentPose == null)
return initalPose2d;
return state.currentPose;
}
public void resetGyro() {
io.tareEverything();
robotKnowsWhereItIs = false;
rotTarget = 0;
// vision.resetRotations();
}
public void softStop() {
stopped = true;
io.setControl(new SwerveRequest.FieldCentric()
.withVelocityX(0)
.withVelocityY(0)
.withRotationalRate(0)
); // stop the modules without breaking
}
public void stopModules() {
// stopped = true;
// swerveDriveTrain.setControl(new SwerveRequest.SwerveDriveBrake());
softStop();
}
@Override
public void periodic() {
// This method will be called once per scheduler run\
SmartDashboard.putNumber("Gyro", (getGyroAngle() * 180) / Math.PI);
SmartDashboard.putNumber("RotTartget", rotTarget);
io.updateInputs(state);
Logger.processInputs("SwerveDrive", state);
vision.setLastOdomPose(state.currentPose);
setLastOdomSpeed(state.currentPose, state.lastPose, state.odometryRate);
if (vision.isTag()) {
Pose2d pose = vision.getPose2d();
if (!robotKnowsWhereItIs) {
robotKnowsWhereItIs = true;
Pose2d curPose = getPose2d();
rotTarget += pose.getRotation().getDegrees() - curPose.getRotation().getDegrees();
}
io.addVisionMeasurement(vision.getPosesToAdd());
}
// if(e.isPresent())
}
private void reset_index() {
gear_index = SwerveDriveConstants.STARTING_GEAR; // however we wish to initialize the gear (What gear does the
// robot start in?)
}
public void shiftDown() {
if (gear_index == -1 || gear_index >= SwerveDriveConstants.GEARS.length)
reset_index(); // If outof bounds: reset index
int i = gear_index - 1;
if (i == -1)
i = 0;
setPercentOutput(SwerveDriveConstants.GEARS[i]);
gear_index = i;
}
public void shiftUp() {
if (gear_index == -1 || gear_index >= SwerveDriveConstants.GEARS.length)
reset_index(); // If outof bounds: reset index
int i = gear_index + 1;
if (i == SwerveDriveConstants.GEARS.length)
i = SwerveDriveConstants.GEARS.length - 1;
setPercentOutput(SwerveDriveConstants.GEARS[i]);
gear_index = i;
}
public void setPercentOutput(double speed) {
speedAdjust = SwerveDriveConstants.MAX_SPEED_MEETERS_PER_SEC * speed;
gear_index = -1;
}
public void setToSlow() {
setPercentOutput(SwerveDriveConstants.SLOW_SPEED);
gear_index = 0;
}
public void setToFast() {
setPercentOutput(SwerveDriveConstants.FAST_SPEED);
gear_index = 1;
}
public void setToTurbo() {
setPercentOutput(SwerveDriveConstants.TURBO_SPEED);
gear_index = 2;
}
public void shiftUpRot() {
rotSpeedAdjust = SwerveDriveConstants.ROTATION_SPEED;
}
public void shiftDownRot() {
rotSpeedAdjust = SwerveDriveConstants.MIN_ROT_SPEED;
}
private int tmp_gear_index = SwerveDriveConstants.STARTING_GEAR;
public void startSlowPeriod() {
tmp_gear_index = gear_index;
setToSlow();
}
public void startTurboPeriod() {
tmp_gear_index = gear_index;
setToTurbo();
}
public void endSlowPeriod() {
setPercentOutput(SwerveDriveConstants.GEARS[tmp_gear_index]);
gear_index = tmp_gear_index;
}
public void setLastOdomSpeed(Pose2d curPose, Pose2d lastPose, double freq){
if(curPose != null && lastPose != null){
lastOdomSpeed = curPose.getTranslation().getDistance(lastPose.getTranslation())/freq;
}
}
@AutoLogOutput(key="SwerveDrive/speed ")
public double getOdometrySpeed() {
return lastOdomSpeed;
}
@Override
public String getName() {
return "Swerve Drive Controller";
}
@Override
public Status diagnosticStatus() {
Status status = new Status();
// status.addReport(ReportLevel.INFO,
// "Don't know how to diganose new CTRE swerve systems. please check under the CAN(t) section for more detailed information about the swerves there.");
return status;
}
}
src/main/java/frc4388/robot/subsystems/swerve/SwerveDriveConstants.java
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package frc4388.robot.subsystems.swerve;
import static edu.wpi.first.units.Units.Inches;
import static edu.wpi.first.units.Units.Rotations;
import com.ctre.phoenix6.configs.CANcoderConfiguration;
import com.ctre.phoenix6.configs.ClosedLoopRampsConfigs;
import com.ctre.phoenix6.configs.CurrentLimitsConfigs;
import com.ctre.phoenix6.configs.MotorOutputConfigs;
import com.ctre.phoenix6.configs.OpenLoopRampsConfigs;
import com.ctre.phoenix6.configs.Slot0Configs;
import com.ctre.phoenix6.configs.TalonFXConfiguration;
import com.ctre.phoenix6.signals.NeutralModeValue;
import com.ctre.phoenix6.signals.StaticFeedforwardSignValue;
import com.ctre.phoenix6.swerve.SwerveDrivetrainConstants;
import com.ctre.phoenix6.swerve.SwerveModuleConstants;
import com.ctre.phoenix6.swerve.SwerveModuleConstants.ClosedLoopOutputType;
import com.ctre.phoenix6.swerve.SwerveModuleConstants.DriveMotorArrangement;
import com.ctre.phoenix6.swerve.SwerveModuleConstants.SteerFeedbackType;
import com.ctre.phoenix6.swerve.SwerveModuleConstants.SteerMotorArrangement;
import com.ctre.phoenix6.swerve.SwerveModuleConstantsFactory;
import edu.wpi.first.units.measure.Angle;
import edu.wpi.first.units.measure.Distance;
import frc4388.utility.status.CanDevice;
import frc4388.utility.structs.Gains;
// No mans land
// Beware, there be dragons.
public final class SwerveDriveConstants {
public static final double MAX_ROT_SPEED = Math.PI * 2;
public static final double AUTO_MAX_ROT_SPEED = 1.5;
public static final double MIN_ROT_SPEED = 1.0;
public static double ROTATION_SPEED = MAX_ROT_SPEED;
public static double PLAYBACK_ROTATION_SPEED = AUTO_MAX_ROT_SPEED;
public static double ROT_CORRECTION_SPEED = 10; // MIN_ROT_SPEED;
public static final double CORRECTION_MIN = 10;
public static final double CORRECTION_MAX = 50;
public static final double SLOW_SPEED = 0.25;
public static final double FAST_SPEED = 0.5;
public static final double TURBO_SPEED = 1.0;
public static final double[] GEARS = {SLOW_SPEED, FAST_SPEED, TURBO_SPEED};
public static final int STARTING_GEAR = 0;
// Dimensions
public static final double WIDTH = 18.5; // TODO: validate
public static final double HEIGHT = 18.5; // TODO: validate
public static final double HALF_WIDTH = WIDTH / 2.d;
public static final double HALF_HEIGHT = HEIGHT / 2.d;
// Mechanics
private static final double COUPLE_RATIO = 3; //todo: find
private static final double DRIVE_RATIO = 6.12;
private static final double STEER_RATIO = (150/7);
private static final Distance WHEEL_RADIUS = Inches.of(2);
public static final double MAX_SPEED_MEETERS_PER_SEC = 6.22; // TODO: Validate
public static final double MAX_SPEED_FEET_PER_SECOND = MAX_SPEED_MEETERS_PER_SEC * 3.28084;
public static final double MAX_ANGULAR_SPEED_FEET_PER_SECOND = 2 * 2 * Math.PI;
// Operation
public static final double FORWARD_OFFSET = 90; // 0, 90, 180, 270
public static final boolean DRIFT_CORRECTION_ENABLED = true;
public static final boolean INVERT_X = false;
public static final boolean INVERT_Y = true;
public static final boolean INVERT_ROTATION = false;
// public static final Trim POINTLESS_TRIM = new Trim("Pointless Trim", Double.MAX_VALUE, Double.MIN_VALUE, 0.1, 0);
private static final class ModuleSpecificConstants { //2025
//Front Left
private static final Angle FRONT_LEFT_ENCODER_OFFSET = Rotations.of(-0.368896484375);
private static final boolean FRONT_LEFT_DRIVE_MOTOR_INVERTED = false;
private static final boolean FRONT_LEFT_STEER_MOTOR_INVERTED = true;
private static final boolean FRONT_LEFT_ENCODER_INVERTED = false;
private static final Distance FRONT_LEFT_XPOS = Inches.of(HALF_WIDTH);
private static final Distance FRONT_LEFT_YPOS = Inches.of(HALF_HEIGHT);
//Front Right
private static final Angle FRONT_RIGHT_ENCODER_OFFSET = Rotations.of(-0.011474609375);
private static final boolean FRONT_RIGHT_DRIVE_MOTOR_INVERTED = true;
private static final boolean FRONT_RIGHT_STEER_MOTOR_INVERTED = true;
private static final boolean FRONT_RIGHT_ENCODER_INVERTED = false;
private static final Distance FRONT_RIGHT_XPOS = Inches.of(HALF_WIDTH);
private static final Distance FRONT_RIGHT_YPOS = Inches.of(-HALF_HEIGHT);
//Back Left
private static final Angle BACK_LEFT_ENCODER_OFFSET = Rotations.of(0.333251953125+0.5);
private static final boolean BACK_LEFT_DRIVE_MOTOR_INVERTED = false;
private static final boolean BACK_LEFT_STEER_MOTOR_INVERTED = true;
private static final boolean BACK_LEFT_ENCODER_INVERTED = false;
private static final Distance BACK_LEFT_XPOS = Inches.of(-HALF_WIDTH);
private static final Distance BACK_LEFT_YPOS = Inches.of(HALF_HEIGHT);
//Back Right
private static final Angle BACK_RIGHT_ENCODER_OFFSET = Rotations.of(0.4306640625+0.5);
private static final boolean BACK_RIGHT_DRIVE_MOTOR_INVERTED = false;
private static final boolean BACK_RIGHT_STEER_MOTOR_INVERTED = true;
private static final boolean BACK_RIGHT_ENCODER_INVERTED = false;
private static final Distance BACK_RIGHT_XPOS = Inches.of(-HALF_WIDTH);
private static final Distance BACK_RIGHT_YPOS = Inches.of(-HALF_HEIGHT);
}
public static final class IDs {
public static final CanDevice RIGHT_FRONT_WHEEL = new CanDevice("RIGHT_FRONT_WHEEL", 4);
public static final CanDevice RIGHT_FRONT_STEER = new CanDevice("RIGHT_FRONT_STEER", 5);
public static final CanDevice RIGHT_FRONT_ENCODER = new CanDevice("RIGHT_FRONT_ENCODER", 11);
public static final CanDevice LEFT_FRONT_WHEEL = new CanDevice("LEFT_FRONT_WHEEL", 2);
public static final CanDevice LEFT_FRONT_STEER = new CanDevice("LEFT_FRONT_STEER", 3);
public static final CanDevice LEFT_FRONT_ENCODER = new CanDevice("LEFT_FRONT_ENCODER", 10);
public static final CanDevice LEFT_BACK_WHEEL = new CanDevice("LEFT_BACK_WHEEL", 6);
public static final CanDevice LEFT_BACK_STEER = new CanDevice("LEFT_BACK_STEER", 7);
public static final CanDevice LEFT_BACK_ENCODER = new CanDevice("LEFT_BACK_ENCODER", 12);
public static final CanDevice RIGHT_BACK_WHEEL = new CanDevice("RIGHT_BACK_WHEEL", 8);
public static final CanDevice RIGHT_BACK_STEER = new CanDevice("RIGHT_BACK_STEER", 9);
public static final CanDevice RIGHT_BACK_ENCODER = new CanDevice("RIGHT_BACK_ENCODER", 13);
public static final CanDevice DRIVE_PIGEON = new CanDevice("DRIVE_PIGEON", 14);
}
public static final class PIDConstants {
public static final int SWERVE_SLOT_IDX = 0;
public static final int SWERVE_PID_LOOP_IDX = 1;
public static final Gains SWERVE_GAINS = new Gains(50, 0.0, 0.32, 0.0, 0, 0.0);
public static final Slot0Configs CURRENT_SWERVE_ROT_GAINS = new Slot0Configs()
.withKP(50).withKI(0).withKD(0.32)
.withKS(0).withKV(0).withKA(0);
public static final Slot0Configs TEST_SWERVE_ROT_GAINS = new Slot0Configs()
.withKP(10).withKI(0).withKD(0.3)
.withKS(0).withKV(0).withKA(0);
public static final Gains TEST_SWERVE_GAINS = new Gains(1.2, 0.0, 0.0, 0.0, 0, 0.0);
// The steer motor uses any SwerveModule.SteerRequestType control request with the
// output type specified by SwerveModuleConstants.SteerMotorClosedLoopOutput
public static final Slot0Configs PREPROVIDED_STEER_GAINS = new Slot0Configs()
.withKP(100).withKI(0).withKD(0.6)
.withKS(0.1).withKV(1.91).withKA(0)
.withStaticFeedforwardSign(StaticFeedforwardSignValue.UseClosedLoopSign);
// When using closed-loop control, the drive motor uses the control
// output type specified by SwerveModuleConstants.DriveMotorClosedLoopOutput
public static final Slot0Configs PREPROVIDED_DRIVE_GAINS = new Slot0Configs()
.withKP(0.1).withKI(0).withKD(0)
.withKS(0).withKV(0.124);
public static final Gains DRIFT_CORRECTION_GAINS = new Gains(2.5, 0, 0.1);
public static final Gains RELATIVE_LOCKED_ANGLE_GAINS = new Gains(10, 0, 1);
}
public static final class Configurations {
public static final double OPEN_LOOP_RAMP_RATE = 0.4; // Todo: Test. think this will help.
public static final double CLOSED_LOOP_RAMP_RATE = 0.4; // Todo: Test. think this will help.
public static final double NEUTRAL_DEADBAND = 0.04;
// POWER! (limiting)
private static final TalonFXConfiguration DRIVE_MOTOR_CONFIGS = new TalonFXConfiguration()
.withMotorOutput(
new MotorOutputConfigs()
.withNeutralMode(NeutralModeValue.Brake)
.withDutyCycleNeutralDeadband(NEUTRAL_DEADBAND)
).withOpenLoopRamps(
new OpenLoopRampsConfigs()
.withDutyCycleOpenLoopRampPeriod(OPEN_LOOP_RAMP_RATE)
).withClosedLoopRamps(
new ClosedLoopRampsConfigs()
.withDutyCycleClosedLoopRampPeriod(CLOSED_LOOP_RAMP_RATE)
);
private static final TalonFXConfiguration STEER_MOTOR_CONFIGS = new TalonFXConfiguration()
.withCurrentLimits(
new CurrentLimitsConfigs()
.withStatorCurrentLimit(40) // TODO: tune???
.withStatorCurrentLimitEnable(true)
).withMotorOutput(
new MotorOutputConfigs()
.withNeutralMode(NeutralModeValue.Brake)
.withDutyCycleNeutralDeadband(NEUTRAL_DEADBAND)
// ).withOpenLoopRamps(
// new OpenLoopRampsConfigs()
// .withDutyCycleOpenLoopRampPeriod(SwerveDriveConstants.Configurations.OPEN_LOOP_RAMP_RATE)
// ).withClosedLoopRamps(
// new ClosedLoopRampsConfigs()
// .withDutyCycleClosedLoopRampPeriod(SwerveDriveConstants.Configurations.CLOSED_LOOP_RAMP_RATE)
);
public static final double SLIP_CURRENT = 60; // TODO: Tune???
}
public static final SwerveDrivetrainConstants DrivetrainConstants = new SwerveDrivetrainConstants()
.withPigeon2Id(IDs.DRIVE_PIGEON.id);
private static final SwerveModuleConstantsFactory<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> ConstantCreator =
new SwerveModuleConstantsFactory<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration>() // holy verbosity batman.
.withDriveMotorGearRatio(DRIVE_RATIO)
.withSteerMotorGearRatio(STEER_RATIO)
.withCouplingGearRatio(COUPLE_RATIO)
.withWheelRadius(WHEEL_RADIUS)
.withSteerMotorGains(PIDConstants.PREPROVIDED_STEER_GAINS) // ?
.withDriveMotorGains(PIDConstants.PREPROVIDED_DRIVE_GAINS) // ?
.withSteerMotorClosedLoopOutput(ClosedLoopOutputType.Voltage)
.withDriveMotorClosedLoopOutput(ClosedLoopOutputType.Voltage)
.withSlipCurrent(Configurations.SLIP_CURRENT)
.withSpeedAt12Volts(MAX_SPEED_MEETERS_PER_SEC)
.withDriveMotorType(DriveMotorArrangement.TalonFX_Integrated)
.withSteerMotorType(SteerMotorArrangement.TalonFX_Integrated)
.withFeedbackSource(SteerFeedbackType.RemoteCANcoder)
.withDriveMotorInitialConfigs(Configurations.DRIVE_MOTOR_CONFIGS)
.withSteerMotorInitialConfigs(Configurations.STEER_MOTOR_CONFIGS);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> FRONT_LEFT =
ConstantCreator.createModuleConstants(
IDs.LEFT_FRONT_STEER.id, IDs.LEFT_FRONT_WHEEL.id, IDs.LEFT_FRONT_ENCODER.id, ModuleSpecificConstants.FRONT_LEFT_ENCODER_OFFSET,
ModuleSpecificConstants.FRONT_LEFT_XPOS, ModuleSpecificConstants.FRONT_LEFT_YPOS,
ModuleSpecificConstants.FRONT_LEFT_DRIVE_MOTOR_INVERTED, ModuleSpecificConstants.FRONT_LEFT_STEER_MOTOR_INVERTED, ModuleSpecificConstants.FRONT_LEFT_ENCODER_INVERTED
);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> FRONT_RIGHT =
ConstantCreator.createModuleConstants(
IDs.RIGHT_FRONT_STEER.id, IDs.RIGHT_FRONT_WHEEL.id, IDs.RIGHT_FRONT_ENCODER.id, ModuleSpecificConstants.FRONT_RIGHT_ENCODER_OFFSET,
ModuleSpecificConstants.FRONT_RIGHT_XPOS, ModuleSpecificConstants.FRONT_RIGHT_YPOS,
ModuleSpecificConstants.FRONT_RIGHT_DRIVE_MOTOR_INVERTED, ModuleSpecificConstants.FRONT_RIGHT_STEER_MOTOR_INVERTED, ModuleSpecificConstants.FRONT_RIGHT_ENCODER_INVERTED
);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> BACK_LEFT =
ConstantCreator.createModuleConstants(
IDs.LEFT_BACK_STEER.id, IDs.LEFT_BACK_WHEEL.id, IDs.LEFT_BACK_ENCODER.id, ModuleSpecificConstants.BACK_LEFT_ENCODER_OFFSET,
ModuleSpecificConstants.BACK_LEFT_XPOS, ModuleSpecificConstants.BACK_LEFT_YPOS,
ModuleSpecificConstants.BACK_LEFT_DRIVE_MOTOR_INVERTED, ModuleSpecificConstants.BACK_LEFT_STEER_MOTOR_INVERTED, ModuleSpecificConstants.BACK_LEFT_ENCODER_INVERTED
);
public static final SwerveModuleConstants<TalonFXConfiguration, TalonFXConfiguration, CANcoderConfiguration> BACK_RIGHT =
ConstantCreator.createModuleConstants(
IDs.RIGHT_BACK_STEER.id, IDs.RIGHT_BACK_WHEEL.id, IDs.RIGHT_BACK_ENCODER.id, ModuleSpecificConstants.BACK_RIGHT_ENCODER_OFFSET,
ModuleSpecificConstants.BACK_RIGHT_XPOS, ModuleSpecificConstants.BACK_RIGHT_YPOS,
ModuleSpecificConstants.BACK_RIGHT_DRIVE_MOTOR_INVERTED, ModuleSpecificConstants.BACK_RIGHT_STEER_MOTOR_INVERTED, ModuleSpecificConstants.BACK_RIGHT_ENCODER_INVERTED
);
// misc
public static final int TIMEOUT_MS = 30;
public static final int SMARTDASHBOARD_UPDATE_FRAME = 2;
}
src/main/java/frc4388/robot/subsystems/swerve/SwerveIO.java
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package frc4388.robot.subsystems.swerve;
import java.util.List;
import org.littletonrobotics.junction.AutoLog;
import com.ctre.phoenix6.swerve.SwerveRequest;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.math.kinematics.ChassisSpeeds;
import frc4388.robot.subsystems.vision.VisionIO.PoseObservation;
public interface SwerveIO {
@AutoLog
public class SwerveState {
public Pose2d currentPose = null;
public Pose2d lastPose = null;
public ChassisSpeeds speeds = null;
public double odometryRate = 1;
}
public default void setControl(SwerveRequest ctrl) {}
public default void setLimits(double limitInAmps) {}
public default void tareEverything() {}
public default void resetPose(Pose2d pose) {}
public default void addVisionMeasurement(List<PoseObservation> poses) {}
public default void updateInputs(SwerveState state) {}
}
src/main/java/frc4388/robot/subsystems/swerve/SwerveReal.java
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package frc4388.robot.subsystems.swerve;
import java.util.List;
import com.ctre.phoenix6.Utils;
import com.ctre.phoenix6.configs.TalonFXConfiguration;
import com.ctre.phoenix6.hardware.CANcoder;
import com.ctre.phoenix6.hardware.TalonFX;
import com.ctre.phoenix6.swerve.SwerveDrivetrain;
import com.ctre.phoenix6.swerve.SwerveModule;
import com.ctre.phoenix6.swerve.SwerveRequest;
import frc4388.robot.subsystems.vision.Vision;
import frc4388.robot.subsystems.vision.VisionIO.PoseObservation;
public class SwerveReal implements SwerveIO {
SwerveDrivetrain<TalonFX, TalonFX, CANcoder> swerveDriveTrain;
public SwerveReal(SwerveDrivetrain<TalonFX, TalonFX, CANcoder> swerveDriveTrain) {
this.swerveDriveTrain = swerveDriveTrain;
swerveDriveTrain.getOdometryFrequency();
}
@Override
public void updateInputs(SwerveState state) {
double time = Vision.getTime();
state.odometryRate = 1 / swerveDriveTrain.getOdometryFrequency();
state.currentPose = swerveDriveTrain.samplePoseAt(time).orElse(null);
state.lastPose = swerveDriveTrain.samplePoseAt(time - state.odometryRate).orElse(null);
state.speeds = swerveDriveTrain.getState().Speeds;
}
@Override
public void setControl(SwerveRequest ctrl) {
swerveDriveTrain.setControl(ctrl);
}
@Override
public void tareEverything() {
swerveDriveTrain.tareEverything();
}
@Override
public void setLimits(double limitInAmps) {
for (SwerveModule<TalonFX, TalonFX, CANcoder> module : swerveDriveTrain.getModules()) {
var talonFXConfigurator = module.getDriveMotor().getConfigurator();
var talonFXConfigs = new TalonFXConfiguration();
talonFXConfigurator.refresh(talonFXConfigs);
talonFXConfigs.CurrentLimits.StatorCurrentLimit = limitInAmps;
talonFXConfigs.CurrentLimits.SupplyCurrentLimit = limitInAmps+10;
talonFXConfigurator.apply(talonFXConfigs);
}
}
@Override
public void addVisionMeasurement(List<PoseObservation> poses) {
for(PoseObservation pose : poses) {
swerveDriveTrain.addVisionMeasurement(pose.pose(), Utils.fpgaToCurrentTime(pose.timestamp()));
}
}
}
src/main/java/frc4388/robot/subsystems/vision/Vision.java
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package frc4388.robot.subsystems.vision;
import java.util.ArrayList;
import java.util.List;
import java.util.Optional;
import org.littletonrobotics.junction.AutoLogOutput;
import org.littletonrobotics.junction.Logger;
import com.ctre.phoenix6.Utils;
import com.ctre.phoenix6.hardware.CANcoder;
import com.ctre.phoenix6.hardware.TalonFX;
import com.ctre.phoenix6.swerve.SwerveDrivetrain;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.wpilibj2.command.SubsystemBase;
import frc4388.robot.subsystems.vision.VisionIO.PoseObservation;
import frc4388.utility.status.FaultReporter;
import frc4388.utility.status.Queryable;
import frc4388.utility.status.Status;
public class Vision extends SubsystemBase implements Queryable {
VisionIO[] io;
VisionStateAutoLogged[] state;
public Pose2d lastVisionPose = new Pose2d();
public Pose2d lastPhysOdomPose = new Pose2d();
public Vision(VisionIO... devices) {
FaultReporter.register(this);
io = devices;
state = new VisionStateAutoLogged[io.length];
for(int i = 0; i < io.length; i++) {
state[i] = new VisionStateAutoLogged();
}
}
@Override
public void periodic() {
for(int i = 0; i < io.length; i++) {
io[i].updateInputs(state[i]);
Logger.processInputs("Vision/Camera" + i , state[i]);
}
}
public List<PoseObservation> getPosesToAdd(){
List<PoseObservation> poses = new ArrayList<>();
for(int i = 0; i < state.length; i++) {
if(state[i].lastEstimatedPose != null) {
poses.add(state[i].lastEstimatedPose);
}
}
return poses;
}
public void setLastOdomPose(Pose2d pose){
if(pose != null)
lastPhysOdomPose = pose;
}
public boolean isTag(){
for(int i = 0; i < state.length; i++){
if(state[i].isTagDetected && state[i].isTagProcessed)
return true;
}
return false;
}
@AutoLogOutput
public Pose2d getPose2d() {
if(lastPhysOdomPose != null)
return lastPhysOdomPose;
// if(lastVisionPose != null)
// return lastVisionPose;
return new Pose2d();
}
public static double getTime() {
return Utils.getCurrentTimeSeconds();
}
@Override
public Status diagnosticStatus() {
return new Status();
// // TODO Auto-generated method stub
// throw new UnsupportedOperationException("Unimplemented method 'diagnosticStatus'");
}
}
src/main/java/frc4388/robot/subsystems/vision/VisionIO.java
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package frc4388.robot.subsystems.vision;
import org.littletonrobotics.junction.AutoLog;
import edu.wpi.first.math.geometry.Pose2d;
public interface VisionIO {
@AutoLog
public class VisionState {
public boolean isTagDetected = false;
public boolean isTagProcessed = false;
// public double latency = 0;
public PoseObservation lastEstimatedPose = null;
}
public static record PoseObservation(
Pose2d pose,
double timestamp
) {}
public default void updateInputs(VisionState state) {}
}
src/main/java/frc4388/robot/subsystems/vision/VisionReal.java
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package frc4388.robot.subsystems.vision;
import edu.wpi.first.math.geometry.Transform3d;
import java.util.Optional;
import org.photonvision.EstimatedRobotPose;
import org.photonvision.PhotonCamera;
import org.photonvision.PhotonPoseEstimator;
import org.photonvision.PhotonPoseEstimator.PoseStrategy;
import org.photonvision.targeting.PhotonPipelineResult;
import frc4388.robot.constants.Constants.FieldConstants;
import frc4388.robot.constants.Constants.VisionConstants;
public class VisionReal implements VisionIO {
// private PhotonCamera[] cameras;
// private PhotonPoseEstimator[] estimators;
private PhotonCamera camera;
private PhotonPoseEstimator estimator;
// public List<EstimatedRobotPose> poses = new ArrayList<>();
public VisionReal(PhotonCamera camera, Transform3d position){
this.camera = camera;
estimator = new PhotonPoseEstimator(FieldConstants.kTagLayout, PoseStrategy.MULTI_TAG_PNP_ON_COPROCESSOR, position);
estimator.setMultiTagFallbackStrategy(PoseStrategy.LOWEST_AMBIGUITY);
}
// private Instant lastVisionTime = null;
public void updateInputs(VisionState state) {
state.isTagProcessed = false;
state.isTagDetected = false;
state.lastEstimatedPose = null;
var results = camera.getAllUnreadResults();
// If there are no more updates from the camera
if (results.size() == 0)
return;
var result = results.get(results.size()-1);
state.isTagDetected = state.isTagDetected | result.hasTargets();
// If there are no tags
if(!result.hasTargets())
return;
Optional<EstimatedRobotPose> estimatedRobotPose = getEstimatedGlobalPose(result, estimator);
// If the tag was failed to be processed
if(estimatedRobotPose.isEmpty())
return;
EstimatedRobotPose pose = estimatedRobotPose.get();
state.lastEstimatedPose = new PoseObservation(pose.estimatedPose.toPose2d(), pose.timestampSeconds);
state.isTagProcessed = true;
}
/**
* The latest estimated robot pose on the field from vision data. This may be empty. This should
* only be called once per loop.
*
* <p>Also includes updates for the standard deviations, which can (optionally) be retrieved with
* {@link getEstimationStdDevs}
*
* @return An {@link EstimatedRobotPose} with an estimated pose, estimate timestamp, and targets
* used for estimation.
*/
public Optional<EstimatedRobotPose> getEstimatedGlobalPose(PhotonPipelineResult change, PhotonPoseEstimator estimator) {
Optional<EstimatedRobotPose> visionEst = Optional.empty();
var targets = change.getTargets();
for(int i = targets.size()-1; i >= 0; i--){
Transform3d pos = targets.get(i).getBestCameraToTarget();
double distance = Math.sqrt(Math.pow(pos.getX(),2) + Math.pow(pos.getY(),2) + Math.pow(pos.getZ(),2));
if (distance > VisionConstants.MIN_ESTIMATION_DISTANCE) {
change.targets.remove(i);
}
}
if(targets.size() <= 0)
return visionEst; // Will be empty
visionEst = estimator.update(change);
// updateEstimationStdDevs(visionEst, change.getTargets(), estimator);
return visionEst;
}
public String getName() {
return camera.getName();
}
// /**
// * Calculates new standard deviations This algorithm is a heuristic that creates dynamic standard
// * deviations based on number of tags, estimation strategy, and distance from the tags.
// *
// * @param estimatedPose The estimated pose to guess standard deviations for.
// * @param targets All targets in this camera frame
// */
// private void updateEstimationStdDevs(
// Optional<EstimatedRobotPose> estimatedPose,
// List<PhotonTrackedTarget> targets,
// PhotonPoseEstimator estimator) {
// if (estimatedPose.isEmpty()) {
// // No pose input. Default to single-tag std devs
// curStdDevs = VisionConstants.kSingleTagStdDevs;
// } else {
// // Pose present. Start running Heuristic
// var estStdDevs = VisionConstants.kSingleTagStdDevs;
// int numTags = 0;
// double avgDist = 0;
// // Precalculation - see how many tags we found, and calculate an average-distance metric
// for (var tgt : targets) {
// var tagPose = estimator.getFieldTags().getTagPose(tgt.getFiducialId());
// if (tagPose.isEmpty()) continue;
// double distance = tagPose
// .get()
// .toPose2d()
// .getTranslation()
// .getDistance(estimatedPose.get().estimatedPose.toPose2d().getTranslation());
// if (distance < VisionConstants.MIN_ESTIMATION_DISTANCE) {
// numTags++;
// avgDist += distance;
// }
// }
// if (numTags == 0) {
// // No tags visible. Default to single-tag std devs
// curStdDevs = VisionConstants.kSingleTagStdDevs;
// } else {
// // One or more tags visible, run the full heuristic.
// avgDist /= numTags;
// // Decrease std devs if multiple targets are visible
// if (numTags > 1) estStdDevs = VisionConstants.kMultiTagStdDevs;
// // Increase std devs based on (average) distance
// if (numTags == 1 && avgDist > 4)
// estStdDevs = VecBuilder.fill(Double.MAX_VALUE, Double.MAX_VALUE, Double.MAX_VALUE);
// else estStdDevs = estStdDevs.times(1 + (avgDist * avgDist / 30));
// curStdDevs = estStdDevs;
// }
// }
// }
}
src/main/java/frc4388/utility/DeferredBlock.java
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package frc4388.utility;
import java.util.ArrayList;
// Class for running code snippets whenever the robot is enabled.
public class DeferredBlock {
private static ArrayList<Runnable> m_blocks_norerun = new ArrayList<>();
private static ArrayList<Runnable> m_blocks_rerun = new ArrayList<>();
private static boolean m_hasRun = false;
public static void addBlock(Runnable block) {
addBlock(block, false);
}
public static void addBlock(Runnable block, boolean rerun) {
if(rerun) {
m_blocks_rerun.add(block);
} else {
m_blocks_norerun.add(block);
}
}
public static void execute() {
// Run blocks that run multiple times.
for (Runnable block : m_blocks_rerun) {
block.run();
}
// Run blocks that only run once
if (m_hasRun) return;
for (Runnable block : m_blocks_norerun) {
block.run();
}
m_blocks_norerun.clear(); // for garbage collection
m_hasRun = true;
}
}
src/main/java/frc4388/utility/compute/DataUtils.java
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package frc4388.utility.compute;
import java.nio.ByteBuffer;
public class DataUtils {
public static byte[] doubleToByteArray(double value) {
byte[] bytes = new byte[8];
ByteBuffer.wrap(bytes).putDouble(value);
return bytes;
}
public static double byteArrayToDouble(byte[] bytes) {
return ByteBuffer.wrap(bytes).getDouble();
}
public static byte[] intToByteArray(int value) {
byte[] bytes = new byte[4];
ByteBuffer.wrap(bytes).putInt(value);
return bytes;
}
public static int byteArrayToInt(byte[] bytes) {
return ByteBuffer.wrap(bytes).getInt();
}
public static byte[] shortToByteArray(short value) {
byte[] bytes = new byte[2];
ByteBuffer.wrap(bytes).putShort(value);
return bytes;
}
public static short byteArrayToShort(byte[] bytes) {
return ByteBuffer.wrap(bytes).getShort();
}
}
src/main/java/frc4388/utility/compute/ReefPositionHelper.java
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package frc4388.utility.compute;
import edu.wpi.first.math.geometry.Pose2d;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.math.util.Units;
import frc4388.robot.constants.Constants.AutoConstants;
import frc4388.robot.constants.Constants.FieldConstants;
public class ReefPositionHelper {
public enum Side {
LEFT,
RIGHT,
CENTER,
FAR_LEFT
}
public static final Pose2d[] RED_TAGS = {
FieldConstants.kTagLayout.getTagPose(6).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(7).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(8).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(9).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(10).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(11).get().toPose2d()
};
public static final Pose2d[] BLUE_TAGS = {
FieldConstants.kTagLayout.getTagPose(17).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(18).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(19).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(20).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(21).get().toPose2d(),
FieldConstants.kTagLayout.getTagPose(22).get().toPose2d()
};
public static double distanceTo(Pose2d first, Pose2d second){
return Math.sqrt(Math.pow(first.getX() - second.getX(),2) + Math.pow(first.getY() - second.getY(),2));
}
/*
* Function to loop through a list of tag locations to figure out closest one
*/
public static Pose2d getNearestTag(Pose2d[] locations, Pose2d position){
if(locations.length <= 0) return new Pose2d();
Pose2d minPos = locations[0];
double minDistance = distanceTo(position,minPos);
for(int i = 1; i < locations.length; i++){
double dist = distanceTo(locations[i],position);
if(dist < minDistance){
minPos = locations[i];
minDistance = dist;
}
}
System.out.println(minPos.getRotation().getDegrees());
return minPos;
}
/*
* Function to find closest tag location based on side
*/
public static Pose2d getNearestTag(Pose2d position) {
if(TimesNegativeOne.isRed)
return getNearestTag(RED_TAGS, position);
else
return getNearestTag(BLUE_TAGS, position);
}
public static Pose2d getNearestPosition(Pose2d position, Side side, double xtrim, double ydistance) {
return offset(getNearestTag(position),
getSide(side) + xtrim,
ydistance);
}
public static double getSide(Side side){
switch(side) {
case LEFT:
return -(AutoConstants.X_SCORING_POSITION_OFFSET);
case FAR_LEFT:
return -(AutoConstants.X_SCORING_POSITION_OFFSET+Units.inchesToMeters(8));
case RIGHT:
return (AutoConstants.X_SCORING_POSITION_OFFSET);
case CENTER:
return 0;
}
assert false;
return 0;
}
public static Pose2d offset(Pose2d oldPose, double xoffset, double yoffset){
Translation2d oldTranslation = oldPose.getTranslation();
double rot = oldPose.getRotation().getRadians();
return new Pose2d(new Translation2d(
oldTranslation.getX() + Math.cos(rot + Math.PI/2) * xoffset + Math.cos(rot) * yoffset,
oldTranslation.getY() + Math.sin(rot + Math.PI/2) * xoffset + Math.sin(rot) * yoffset
), oldPose.getRotation().rotateBy(Rotation2d.k180deg));
}
}
src/main/java/frc4388/utility/compute/RobotTime.java
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2018-2019 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. */
/*----------------------------------------------------------------------------*/
package frc4388.utility.compute;
/**
* <p>Keeps track of Robot times like time passed, delta time, etc
* <p>All times are in milliseconds
*/
public class RobotTime {
private long m_currTime = System.currentTimeMillis();
public long m_deltaTime = 0;
private long m_startRobotTime = m_currTime;
public long m_robotTime = 0;
public long m_lastRobotTime = 0;
private long m_startMatchTime = 0;
public long m_matchTime = 0;
public long m_lastMatchTime = 0;
public long m_frameNumber = 0;
/**
* Private constructor prevents other classes from instantiating
*/
private RobotTime(){}
private static RobotTime instance = null;
/**
* Gets the instance of Robot Time. If there is no instance running one will be created.
* @return instance of Robot Time
*/
public static RobotTime getInstance() {
if (instance == null) {
instance = new RobotTime();
}
return instance;
}
/**
* Call this once per periodic loop.
*/
public void updateTimes() {
m_lastRobotTime = m_robotTime;
m_lastMatchTime = m_matchTime;
m_currTime = System.currentTimeMillis();
m_robotTime = m_currTime - m_startRobotTime;
m_deltaTime = m_robotTime - m_lastRobotTime;
m_frameNumber++;
if (m_startMatchTime != 0) {
m_matchTime = m_currTime - m_startMatchTime;
}
}
/**
* Call this in both the auto and periodic inits
*/
public void startMatchTime() {
if (m_startMatchTime == 0) {
m_startMatchTime = m_currTime;
}
}
/**
* Call this in disabled init
*/
public void endMatchTime() {
m_startMatchTime = 0;
m_matchTime = 0;
}
}
src/main/java/frc4388/utility/compute/RobotUnits.java
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// 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.
package frc4388.utility.compute;
/** Aarav's good units class (better than WPILib)
* @author Aarav Shah */
public class RobotUnits {
// constants
// angle conversions
public static double degreesToRadians(final double degrees) {return degrees * Math.PI / 180;}
public static double radiansToDegrees(final double radians) {return radians / Math.PI * 180;}
// falcon conversions
public static double falconTicksToRotations(final double ticks) {return ticks / 2048;}
public static double falconRotationsToTicks(final double rotations) {return rotations * 2048;}
// distance conversions
public static double metersToFeet(final double meters) {return meters * 3.28084;}
public static double feetToMeters(final double feet) {return feet / 3.28084;}
}
src/main/java/frc4388/utility/compute/TimesNegativeOne.java
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package frc4388.utility.compute;
import java.util.Optional;
import edu.wpi.first.math.geometry.Rotation2d;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj.DriverStation;
import edu.wpi.first.wpilibj.DriverStation.Alliance;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
import frc4388.robot.subsystems.swerve.SwerveDriveConstants;
// Class that holds weather the drivers sticks should be inverted
public class TimesNegativeOne {
public static boolean XAxis = SwerveDriveConstants.INVERT_X;
public static boolean YAxis = SwerveDriveConstants.INVERT_Y;
public static boolean RotAxis = SwerveDriveConstants.INVERT_ROTATION;
public static boolean isRed = false;
public static Rotation2d ForwardOffset = Rotation2d.fromDegrees(SwerveDriveConstants.FORWARD_OFFSET);
private static boolean isRed() {
Optional<Alliance> alliance = DriverStation.getAlliance();
if(alliance.isEmpty()) return false;
return (alliance.get() == Alliance.Red);
}
public static void update(){
isRed = isRed();
XAxis = SwerveDriveConstants.INVERT_X ^ isRed;
YAxis = SwerveDriveConstants.INVERT_Y ^ isRed;
RotAxis = SwerveDriveConstants.INVERT_ROTATION;
ForwardOffset = Rotation2d.fromDegrees((SwerveDriveConstants.FORWARD_OFFSET + (isRed ? 0 : 0)));
SmartDashboard.putBoolean("Is red alliance", isRed);
}
public static double invert(double num, boolean invert){
return invert ? -num : num;
}
public static Translation2d invert(Translation2d stick, boolean invertXY){
if(invertXY) return stick.times(-1);
else return stick;
}
public static Translation2d invert(Translation2d stick, boolean invertX, boolean invertY){
return new Translation2d(
invert(stick.getX(), invertX),
invert(stick.getY(), invertY)
);
}
}
src/main/java/frc4388/utility/compute/Trim.java
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// 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.
package frc4388.utility.compute;
import java.io.FileInputStream;
import java.io.FileOutputStream;
import java.util.ArrayList;
import edu.wpi.first.networktables.GenericEntry;
import edu.wpi.first.wpilibj.shuffleboard.Shuffleboard;
import edu.wpi.first.wpilibj.shuffleboard.ShuffleboardTab;
/**
* Reboot persistant Trims.
* @author Zachary Wilke
*/
public class Trim {
private static ArrayList<Trim> trims = new ArrayList<Trim>();
private static ShuffleboardTab trimTab = Shuffleboard.getTab("Trims");
private String trimName;
private double upperBound;
private double lowerBound;
private double step;
private boolean modified = false;
private double currentValue;
private boolean persistant = false;
private GenericEntry trimElement = null;
/**
* Creates a variably Trim with a given name, upper and lower bounds, step size and intial value
* @param trimName please keep the trim name without special symbols
* @param upperBound the upper limit inclusive
* @param lowerBound the lower limit inclusive
* @param step the step size
* @param inital the inital value, will get overridden if the persistant trim exists on disk.
* @param persistnat Weather the trim is persistant or not
*/
public Trim(String trimName, double upperBound, double lowerBound, double step, double inital, boolean persistant) {
this.trimName = trimName;
this.upperBound = upperBound;
this.lowerBound = lowerBound;
this.step = step;
this.persistant = persistant;
currentValue = inital;
load();
trimElement = trimTab.add(trimName, currentValue).getEntry();
trims.add(this);
}
/**
* Creates a non-Trim with a given name, upper and lower bounds, step size and intial value
* @param trimName please keep the trim name without special symbols
* @param upperBound the upper limit inclusive
* @param lowerBound the lower limit inclusive
* @param step the step size
* @param inital the inital value, will get overridden if the persistant trim exists on disk.
*/
public Trim(String trimName, double upperBound, double lowerBound, double step, double inital) {
this.trimName = trimName;
this.upperBound = upperBound;
this.lowerBound = lowerBound;
this.step = step;
currentValue = inital;
load();
trimElement = trimTab.add(trimName, currentValue).getEntry();
trims.add(this);
}
private void clampModify() {
currentValue = Math.min(upperBound, Math.max(currentValue, lowerBound));
if (trimElement != null)
trimElement.setValue(currentValue);
modified = true;
}
public void stepUp() {
this.currentValue += step;
clampModify();
}
public void stepDown() {
this.currentValue -= step;
clampModify();
}
public void set(double value) {
this.currentValue = value;
clampModify();
}
public double get() {
return this.currentValue;
}
public boolean isModified() {
return modified;
}
public boolean load() {
if(!persistant)
return false;
try (FileInputStream stream = new FileInputStream("/home/lvuser/trims/" + trimName)) {
double fileValue = DataUtils.byteArrayToDouble(stream.readNBytes(8));
currentValue = fileValue;
clampModify();
modified = false;
if (fileValue != currentValue) {
System.out.println("TRIMS: Loaded trim `" + trimName + "` has a value that is higher than or less than the bounds set for the trim, clamping...");
modified = true;
}
return true;
} catch (Exception e) {
// e.printStackTrace();
System.out.println("TRIMS: Unable to read trim file `" + trimName + "`, using current value...");
return false;
}
}
public void dump() {
try (FileOutputStream stream = new FileOutputStream("/home/lvuser/trims/" + trimName)) {
stream.write(DataUtils.doubleToByteArray(currentValue));
modified = false;
} catch (Exception e) {
// e.printStackTrace();
System.out.println("TRIMS: Unable to write to trim file `" + trimName + "`!?!");
}
}
public static void dumpAll() {
for (int i = 0; i < trims.size(); i++) {
Trim trim = trims.get(i);
if (trim.isModified())
trim.dump();
}
}
}
src/main/java/frc4388/utility/configurable/ConfigurableDouble.java
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package frc4388.utility.configurable;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
public class ConfigurableDouble {
private double defualtValue;
private String name;
/**
* Creates an new ConfigurableDouble through Smart Dashboard.
* @param name the name of the Smart Dashboard key.
* @param defualtValue the initilization value
*/
public ConfigurableDouble(String name, double defualtValue) {
this.name = name;
this.defualtValue = defualtValue;
SmartDashboard.putNumber(name, defualtValue);
}
public double get() {
return SmartDashboard.getNumber(name, defualtValue);
}
}
src/main/java/frc4388/utility/configurable/ConfigurableString.java
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package frc4388.utility.configurable;
import edu.wpi.first.wpilibj.smartdashboard.SmartDashboard;
public class ConfigurableString {
private String defualtValue;
private String name;
/**
* Creates an new ConfigurableString through Smart Dashboard.
* @param name the name of the Smart Dashboard key.
* @param defualtValue the initilization value
*/
public ConfigurableString(String name, String defualtValue) {
this.name = name;
this.defualtValue = defualtValue;
SmartDashboard.putString(name, defualtValue);
}
public String get() {
return SmartDashboard.getString(name, defualtValue);
}
}
src/main/java/frc4388/utility/controller/ButtonBox.java
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package frc4388.utility.controller;
import edu.wpi.first.wpilibj.GenericHID;
public class ButtonBox extends GenericHID {
public static final int White = 1;
public static final int One = 2;
public static final int Two = 3;
public static final int Three = 4;
public static final int Four = 5;
public static final int Five = 6;
public static final int Six = 7;
public static final int Seven = 8;
public static final int Eight = 9;
public ButtonBox(int ID){
super(ID);
}
}
src/main/java/frc4388/utility/controller/DeadbandedXboxController.java
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package frc4388.utility.controller;
import static frc4388.robot.constants.Constants.OIConstants.LEFT_AXIS_DEADBAND;
import edu.wpi.first.math.geometry.Translation2d;
import edu.wpi.first.wpilibj.XboxController;
public class DeadbandedXboxController extends XboxController {
public DeadbandedXboxController(int port) { super(port); }
@Override public double getLeftX() { return getLeft().getX(); }
@Override public double getLeftY() { return getLeft().getY(); }
@Override public double getRightX() { return getRight().getX(); }
@Override public double getRightY() { return getRight().getY(); }
public Translation2d getLeft() { return skewToDeadzonedCircle(super.getLeftX(), super.getLeftY()); }
public Translation2d getRight() { return skewToDeadzonedCircle(-super.getRightX(), super.getRightY()); }
public static Translation2d skewToDeadzonedCircle(double x, double y) {
Translation2d translation2d = new Translation2d(x, y);
double magnitude = translation2d.getNorm();
if (magnitude < LEFT_AXIS_DEADBAND) return new Translation2d(0,0);
return translation2d;
}
}
src/main/java/frc4388/utility/controller/IHandController.java
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package frc4388.utility.controller;
/**
* Add your docs here.
*/
public interface IHandController {
public double getLeftXAxis();
public double getLeftYAxis();
public double getRightXAxis();
public double getRightYAxis();
public double getLeftTriggerAxis();
public double getRightTriggerAxis();
public int getDpadAngle();
}
src/main/java/frc4388/utility/controller/VirtualController.java
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package frc4388.utility.controller;
import edu.wpi.first.wpilibj.GenericHID;
/**
* A virtual controller that can be bound like an standard controller.
* @author Zachary Wilke
*/
public class VirtualController extends GenericHID {
private short m_buttonStates = 0;
private short m_buttonStatesLastFrame = 0;
private double[] m_axes = new double[6];
private short[] m_pov = new short[1];
/**
* Create an virtual controller
* @param port virtual port (merely a formality).
*/
public VirtualController(int port) {
super(port);
}
/**
* Set the curent inputs to the new frames.
* @param axes joystick axes, (i.e. joysticks and triggers).
* @param buttonFlags the bit packed button states.
* @param pov the array of dpads.
*/
public void setFrame(double[] axes, short buttonFlags, short[] pov) {
m_axes = axes;
setOutputs(buttonFlags);
m_pov = pov;
}
/**
* Zero outs the controls.
*/
public void zeroControls() {
m_axes = new double[6];
m_buttonStates = 0;
m_buttonStatesLastFrame = 0;
m_pov = new short[] {-1};
}
/**
* Gets the value of a bitflag from an int
* @param value int to search
* @param index index of bit
* @return if the bit is set
*/
public static boolean getFlag(int value, int index) {
return ((value & 1 << index) != 0);
}
@Override
public boolean getRawButton(int button) { // man why are buttons indexed at 1.
return getFlag(m_buttonStates, button - 1);
}
@Override
public boolean getRawButtonPressed(int button) {
return (!getFlag(m_buttonStatesLastFrame, button - 1) && getRawButton(button));
}
@Override
public boolean getRawButtonReleased(int button) {
return (getFlag(m_buttonStatesLastFrame, button - 1) && !getRawButton(button));
}
@Override
public double getRawAxis(int axis) {
return m_axes[axis];
}
@Override
public int getPOV(int pov) {
return m_pov[pov];
}
@Override
public int getAxisCount() {
return m_axes.length;
}
@Override
public int getPOVCount() {
return m_pov.length;
}
@Override
public int getButtonCount() {
return 10;
}
@Override
public boolean isConnected() {
return true;
}
@Override
public HIDType getType() {
return HIDType.kXInputGamepad;
}
@Override
public String getName() {
return "Virtual Controller";
}
@Override
public int getAxisType(int axis) {
return 1; /* ! Warning, does not return accurate data.
Hopefully this isn't a problem */
}
/**
* Use {@link VirtualController#setFrame} or {@link VirtualController#setOutputs}.
* this is an no-op overide.
*/
@Override
public void setOutput(int outputNumber, boolean value) {
// do not use
//m_buttonStatesLastFrame[outputNumber - 1] = m_buttonStates[outputNumber - 1];
//m_buttonStates[outputNumber - 1] = value;
}
/**
* Set buttons from a packed int, if you want to set joysticks and dpad use {@link VirtualController#SetFrame}
*/
@Override
public void setOutputs(int value) {
m_buttonStatesLastFrame = m_buttonStates;
m_buttonStates = (short) value;
}
/**
* Why are you Setting rumble on an virtual controller?
* @param type the rumble type (even though it won't do anything)
* @param value the rumble strength (always multiplyed by 0.0)
*/
@Override
public void setRumble(RumbleType type, double value) {
System.out.println("Why are you Setting rumble on an virtual controller?");
}
}
src/main/java/frc4388/utility/controller/XboxController.java
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package frc4388.utility.controller;
import edu.wpi.first.wpilibj.Joystick;
/**
* This is a wrapper for the WPILib Joystick class that represents an XBox
* controller.
* @author frc1675
*/
public class XboxController implements IHandController
{
public static final int LEFT_X_AXIS = 0;
public static final int LEFT_Y_AXIS = 1;
public static final int LEFT_TRIGGER_AXIS = 2;
public static final int RIGHT_TRIGGER_AXIS = 3;
public static final int RIGHT_X_AXIS = 4;
public static final int RIGHT_Y_AXIS = 5;
public static final int LEFT_RIGHT_DPAD_AXIS = 6;
public static final int TOP_BOTTOM_DPAD_AXIS = 6;
public static final int A_BUTTON = 1;
public static final int B_BUTTON = 2;
public static final int X_BUTTON = 3;
public static final int Y_BUTTON = 4;
public static final int LEFT_BUMPER_BUTTON = 5;
public static final int RIGHT_BUMPER_BUTTON = 6;
public static final int BACK_BUTTON = 7;
public static final int START_BUTTON = 8;
public static final int LEFT_JOYSTICK_BUTTON = 9;
public static final int RIGHT_JOYSTICK_BUTTON = 10;
private static final double LEFT_DPAD_TOLERANCE = -0.9;
private static final double RIGHT_DPAD_TOLERANCE = 0.9;
private static final double BOTTOM_DPAD_TOLERANCE = -0.9;
private static final double TOP_DPAD_TOLERANCE = 0.9;
private static final double LEFT_TRIGGER_TOLERANCE = 0.5;
private static final double RIGHT_TRIGGER_TOLERANCE = 0.5;
private static final double RIGHT_AXIS_UP_TOLERANCE = -0.9;
private static final double RIGHT_AXIS_DOWN_TOLERANCE = 0.9;
private static final double RIGHT_AXIS_RIGHT_TOLERANCE = 0.9;
private static final double RIGHT_AXIS_LEFT_TOLERANCE = -0.9;
private static final double LEFT_AXIS_UP_TOLERANCE = -0.9;
private static final double LEFT_AXIS_DOWN_TOLERANCE = 0.9;
private static final double LEFT_AXIS_RIGHT_TOLERANCE = 0.9;
private static final double LEFT_AXIS_LEFT_TOLERANCE = -0.9;
private static final double DEADZONE = 0.1;
private Joystick m_stick;
/**
* Add your docs here.
*/
public XboxController(int portNumber){
m_stick = new Joystick(portNumber);
}
/**
* Add your docs here.
*/
public Joystick getJoyStick() {
return m_stick;
}
/**
* Checks if the input falls within the deadzone.
* @param input from an axis on the controller
* @return true if input falls in deadzone, false if input falls outside deadzone
*/
private boolean inDeadZone(double input){
return (Math.abs(input) < DEADZONE);
}
/**
* Updates an input to have a deadzone around the 0 position
* @param input from an axis on the controller
* @return updated input
*/
private double getAxisWithDeadZoneCheck(double input){
if(inDeadZone(input)){
return 0.0;
} else {
return input;
}
}
public boolean getAButton(){
return m_stick.getRawButton(A_BUTTON);
}
public boolean getXButton(){
return m_stick.getRawButton(X_BUTTON);
}
public boolean getBButton(){
return m_stick.getRawButton(B_BUTTON);
}
public boolean getYButton(){
return m_stick.getRawButton(Y_BUTTON);
}
public boolean getBackButton(){
return m_stick.getRawButton(BACK_BUTTON);
}
public boolean getStartButton(){
return m_stick.getRawButton(START_BUTTON);
}
public boolean getLeftBumperButton(){
return m_stick.getRawButton(LEFT_BUMPER_BUTTON);
}
public boolean getRightBumperButton(){
return m_stick.getRawButton(RIGHT_BUMPER_BUTTON);
}
public boolean getLeftJoystickButton(){
return m_stick.getRawButton(LEFT_JOYSTICK_BUTTON);
}
public boolean getRightJoystickButton(){
return m_stick.getRawButton(RIGHT_JOYSTICK_BUTTON);
}
public double getLeftXAxis(){
return getAxisWithDeadZoneCheck(m_stick.getRawAxis(LEFT_X_AXIS));
}
public double getLeftYAxis(){
return getAxisWithDeadZoneCheck(m_stick.getRawAxis(LEFT_Y_AXIS));
}
public double getRightXAxis(){
return getAxisWithDeadZoneCheck(m_stick.getRawAxis(RIGHT_X_AXIS));
}
public double getRightYAxis(){
return getAxisWithDeadZoneCheck(m_stick.getRawAxis(RIGHT_Y_AXIS));
}
public double getLeftTriggerAxis(){
return getAxisWithDeadZoneCheck(m_stick.getRawAxis(LEFT_TRIGGER_AXIS));
}
public double getRightTriggerAxis(){
return getAxisWithDeadZoneCheck(m_stick.getRawAxis(RIGHT_TRIGGER_AXIS));
}
/**
* Get the angle input from the dpad.
* @return -1 if nothing is pressed, or the angle of the button pressed. 0 = up, 90 = right, etc.
*/
public int getDpadAngle() {
return m_stick.getPOV(0);
}
public boolean getDPadLeft(){
return (m_stick.getRawAxis(LEFT_RIGHT_DPAD_AXIS) < LEFT_DPAD_TOLERANCE);
}
public boolean getDPadRight(){
return (m_stick.getRawAxis(LEFT_RIGHT_DPAD_AXIS) > RIGHT_DPAD_TOLERANCE);
}
public boolean getDPadTop(){
return (m_stick.getRawAxis(TOP_BOTTOM_DPAD_AXIS) < TOP_DPAD_TOLERANCE);
}
public boolean getDPadBottom(){
return (m_stick.getRawAxis(TOP_BOTTOM_DPAD_AXIS) > BOTTOM_DPAD_TOLERANCE);
}
public boolean getLeftTrigger(){
return (getLeftTriggerAxis() > LEFT_TRIGGER_TOLERANCE);
}
public boolean getRightTrigger(){
return (getRightTriggerAxis() > RIGHT_TRIGGER_TOLERANCE);
}
public boolean getRightAxisUpTrigger(){
return (getRightYAxis() < RIGHT_AXIS_UP_TOLERANCE);
}
public boolean getRightAxisDownTrigger(){
return (getRightYAxis() > RIGHT_AXIS_DOWN_TOLERANCE);
}
public boolean getRightAxisLeftTrigger(){
return (getRightXAxis() > RIGHT_AXIS_LEFT_TOLERANCE);
}
public boolean getRightAxisRightTrigger(){
return (getRightXAxis() > RIGHT_AXIS_RIGHT_TOLERANCE);
}
public boolean getLeftAxisUpTrigger(){
return (getLeftYAxis() < LEFT_AXIS_UP_TOLERANCE);
}
public boolean getLeftAxisDownTrigger(){
return (getLeftYAxis() > LEFT_AXIS_DOWN_TOLERANCE);
}
public boolean getLeftAxisLeftTrigger(){
return (getLeftXAxis() > LEFT_AXIS_LEFT_TOLERANCE);
}
public boolean getLeftAxisRightTrigger(){
return (getLeftXAxis() > LEFT_AXIS_RIGHT_TOLERANCE);
}
}
src/main/java/frc4388/utility/controller/XboxTriggerButton.java
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package frc4388.utility.controller;
//import edu.wpi.first.wpilibj2.command.button.Trigger;
/**
* Mapping for the Xbox controller triggers to allow triggers to be defined as
* buttons in {@link frc4388.robot.OI}. Checks to see if the given trigger
* exceeds a tolerance defined in {@link XboxController}.
*/
public class XboxTriggerButton {//extends Trigger {
public static final int RIGHT_TRIGGER = 0;
public static final int LEFT_TRIGGER = 1;
public static final int RIGHT_AXIS_UP_TRIGGER = 2;
public static final int RIGHT_AXIS_DOWN_TRIGGER = 3;
public static final int RIGHT_AXIS_RIGHT_TRIGGER = 4;
public static final int RIGHT_AXIS_LEFT_TRIGGER = 5;
public static final int LEFT_AXIS_UP_TRIGGER = 6;
public static final int LEFT_AXIS_DOWN_TRIGGER = 7;
public static final int LEFT_AXIS_RIGHT_TRIGGER = 8;
public static final int LEFT_AXIS_LEFT_TRIGGER = 9;
private XboxController m_controller;
private int m_trigger;
/**
* Creates a Trigger-Button mapped to a specific Xbox controller and trigger
*/
public XboxTriggerButton(XboxController controller, int trigger) {
m_controller = controller;
m_trigger = trigger;
}
/** {@inheritDoc} */
// @Override
public boolean get() {
if (m_trigger == RIGHT_TRIGGER) {
return m_controller.getRightTrigger();
}
else if (m_trigger == LEFT_TRIGGER) {
return m_controller.getLeftTrigger();
}
else if (m_trigger == RIGHT_AXIS_UP_TRIGGER) {
return m_controller.getRightAxisUpTrigger();
}
else if (m_trigger == RIGHT_AXIS_DOWN_TRIGGER) {
return m_controller.getRightAxisDownTrigger();
}
else if (m_trigger == RIGHT_AXIS_RIGHT_TRIGGER) {
return m_controller.getRightAxisRightTrigger();
}
else if (m_trigger == RIGHT_AXIS_LEFT_TRIGGER) {
return m_controller.getRightAxisLeftTrigger();
}
else if (m_trigger == LEFT_AXIS_UP_TRIGGER) {
return m_controller.getLeftAxisUpTrigger();
}
else if (m_trigger == LEFT_AXIS_DOWN_TRIGGER) {
return m_controller.getLeftAxisDownTrigger();
}
else if (m_trigger == LEFT_AXIS_RIGHT_TRIGGER) {
return m_controller.getLeftAxisRightTrigger();
}
else if (m_trigger == LEFT_AXIS_LEFT_TRIGGER) {
return m_controller.getLeftAxisLeftTrigger();
}
return false;
}
}
src/main/java/frc4388/utility/status/Alerts.java
+10
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package frc4388.utility.status;
import edu.wpi.first.wpilibj.Alert;
import edu.wpi.first.wpilibj.Alert.AlertType;
import frc4388.robot.RobotContainer;
// Class to update a series of WPILIB Alerts
public class Alerts {
public static Alert no_auto = new Alert("No auto has been selected!", AlertType.kError);
}
src/main/java/frc4388/utility/status/CanDevice.java
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package frc4388.utility.status;
import java.util.ArrayList;
import java.util.List;
import frc4388.utility.status.Status.ReportLevel;
public class CanDevice {
public static List<CanDevice> devices = new ArrayList<>();
public String name;
public int id;
public CanDevice(String name, int id) {
this.name = name;
this.id = id;
devices.add(this);
}
private boolean isAlive() {
return true; //TODO: Link this with Device Finder
}
public String getName() {
return "CAN ID " + this.id + " ( " + this.name + " ) ";
}
public void Log(String str){
System.out.println(getName() + " - " + str);
}
// public Status queryStatus() {
// Status s = new Status();
// s.addReport(ReportLevel.INFO, "TODO");
// return s;
// }
public Status diagnosticStatus() {
Status s = new Status();
//TODO
s.addReport(ReportLevel.INFO, "Add CAN magic here");
boolean isAlive = isAlive();
s.addReport(isAlive ? ReportLevel.INFO : ReportLevel.ERROR, "Is Alive: " + isAlive);
return s;
}
}
src/main/java/frc4388/utility/status/FaultCANCoder.java
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package frc4388.utility.status;
import com.ctre.phoenix6.controls.EmptyControl;
import com.ctre.phoenix6.hardware.CANcoder;
import frc4388.utility.status.Status.ReportLevel;
public class FaultCANCoder implements Queryable {
private String name;
private CANcoder cancoder;
public static void addDevice(CANcoder cancoder, String name) {
FaultCANCoder p = new FaultCANCoder();
p.name = name;
p.cancoder = cancoder;
FaultReporter.register(p);
}
@Override
public String getName() {
return name;
}
@Override
public Status diagnosticStatus() {
Status s = new Status();
boolean debounceBad = !QueryUtils.isDebounceOk(cancoder.getSupplyVoltage());
boolean emptyControlBad = cancoder.setControl(new EmptyControl()).value != 0;
if(debounceBad || emptyControlBad) {
s.addReport(ReportLevel.ERROR, "device is unreachable - Failed" +
(debounceBad ? " Failed debounce test" : "") +
(emptyControlBad ? " Failed empty control test" : "")
);
}
// faults
if (cancoder.getFault_Hardware().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Hardware fault detected");
}
if (cancoder.getFault_BootDuringEnable().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Device booted while enabled");
}
if (cancoder.getFault_BadMagnet().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Bad magnet");
}
if (cancoder.getFault_Undervoltage().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Device supply voltage near brownout");
}
if (cancoder.getFault_UnlicensedFeatureInUse().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Unlicensed feature in use");
}
// sticky faults
if (cancoder.getStickyFault_Hardware().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Hardware fault detected");
}
if (cancoder.getStickyFault_BootDuringEnable().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Device booted while enabled");
}
if (cancoder.getStickyFault_BadMagnet().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Bad magnet");
}
if (cancoder.getStickyFault_Undervoltage().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Device supply voltage near brownout");
}
if (cancoder.getStickyFault_UnlicensedFeatureInUse().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Unlicensed feature in use");
}
return s;
}
}
src/main/java/frc4388/utility/status/FaultPhotonCamera.java
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package frc4388.utility.status;
import org.photonvision.PhotonCamera;
import frc4388.utility.status.Status.ReportLevel;
public class FaultPhotonCamera implements Queryable {
private String name;
private PhotonCamera cam;
public static void addDevice(PhotonCamera cam, String name) {
FaultPhotonCamera p = new FaultPhotonCamera();
p.name = name;
p.cam = cam;
FaultReporter.register(p);
}
@Override
public String getName() {
return name;
}
@Override
public Status diagnosticStatus() {
Status s = new Status();
if(!cam.isConnected())
s.addReport(ReportLevel.ERROR, "Not Connected!");
return s;
}
}
src/main/java/frc4388/utility/status/FaultPidgeon2.java
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package frc4388.utility.status;
import com.ctre.phoenix6.controls.EmptyControl;
import com.ctre.phoenix6.hardware.Pigeon2;
import frc4388.utility.status.Status.ReportLevel;
public class FaultPidgeon2 implements Queryable {
private String name;
private Pigeon2 pigeon2;
public static void addDevice(Pigeon2 pigeon2, String name) {
FaultPidgeon2 p = new FaultPidgeon2();
p.name = name;
p.pigeon2 = pigeon2;
FaultReporter.register(p);
}
@Override
public String getName() {
return name;
}
@Override
public Status diagnosticStatus() {
Status s = new Status();
boolean debounceBad = !QueryUtils.isDebounceOk(pigeon2.getSupplyVoltage());
boolean emptyControlBad = pigeon2.setControl(new EmptyControl()).value != 0;
if(debounceBad || emptyControlBad) {
s.addReport(ReportLevel.ERROR, "device is unreachable - Failed" +
(debounceBad ? " Failed debounce test" : "") +
(emptyControlBad ? " Failed empty control test" : "")
);
}
s.addReport(ReportLevel.INFO, "Voltage: " + pigeon2.getSupplyVoltage());
s.addReport(ReportLevel.INFO, "Pitch: " + pigeon2.getPitch());
s.addReport(ReportLevel.INFO, "Yaw: " + pigeon2.getYaw());
s.addReport(ReportLevel.INFO, "Roll: " + pigeon2.getRoll());
s.addReport(ReportLevel.INFO, "Acceleration X: " + pigeon2.getAccelerationX());
s.addReport(ReportLevel.INFO, "Acceleration Y: " + pigeon2.getAccelerationY());
s.addReport(ReportLevel.INFO, "Acceleration Z: " + pigeon2.getAccelerationZ());
s.addReport(ReportLevel.INFO, "Magnomiter X: " + pigeon2.getMagneticFieldX());
s.addReport(ReportLevel.INFO, "Magnomiter Y: " + pigeon2.getMagneticFieldY());
s.addReport(ReportLevel.INFO, "Magnomiter Z: " + pigeon2.getMagneticFieldZ());
// faults
if (pigeon2.getFault_BootDuringEnable().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Device booted while enabled");
}
if (pigeon2.getFault_BootIntoMotion().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Device booted while in motion");
}
if (pigeon2.getFault_BootupAccelerometer().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Accelerometer fault detected");
}
if (pigeon2.getFault_BootupGyroscope().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Gyro fault detected");
}
if (pigeon2.getFault_BootupMagnetometer().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Magnetometer fault detected");
}
if (pigeon2.getFault_DataAcquiredLate().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR,
"Motion stack data acquisition slower than expected");
}
if (pigeon2.getFault_Hardware().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Hardware fault detected");
}
if (pigeon2.getFault_LoopTimeSlow().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR,
"Motion stack loop time was slower than expected");
}
if (pigeon2.getFault_SaturatedAccelerometer().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "Accelerometer values are saturated");
}
if (pigeon2.getFault_SaturatedGyroscope().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Gyro values are saturated");
}
if (pigeon2.getFault_SaturatedMagnetometer().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "Magnetometer values are saturated");
}
if (pigeon2.getFault_Undervoltage().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "Device supply voltage near brownout");
}
if (pigeon2.getFault_UnlicensedFeatureInUse().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Unlicensed feature in use");
}
// sticky faults
if (pigeon2.getStickyFault_BootDuringEnable().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "[STICKY] Device booted while enabled");
}
if (pigeon2.getStickyFault_BootIntoMotion().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "[STICKY] Device booted while in motion");
}
if (pigeon2.getStickyFault_BootupAccelerometer().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "[STICKY] Accelerometer fault detected");
}
if (pigeon2.getStickyFault_BootupGyroscope().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Gyro fault detected");
}
if (pigeon2.getStickyFault_BootupMagnetometer().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "[STICKY] Magnetometer fault detected");
}
if (pigeon2.getStickyFault_DataAcquiredLate().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR,
String.format(
"[STICKY] Motion stack data acquisition slower than expected"));
}
if (pigeon2.getStickyFault_Hardware().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "[STICKY] Hardware fault detected");
}
if (pigeon2.getStickyFault_LoopTimeSlow().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR,
String.format(
"[STICKY] Motion stack loop time was slower than expected"));
}
if (pigeon2.getStickyFault_SaturatedAccelerometer().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR,
"[STICKY] Accelerometer values are saturated");
}
if (pigeon2.getStickyFault_SaturatedGyroscope().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "[STICKY] Gyro values are saturated");
}
if (pigeon2.getStickyFault_SaturatedMagnetometer().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR,
"[STICKY] Magnetometer values are saturated");
}
if (pigeon2.getStickyFault_Undervoltage().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR,
"[STICKY] Device supply voltage near brownout");
}
if (pigeon2.getStickyFault_UnlicensedFeatureInUse().getValue() == Boolean.TRUE) {
s.addReport(
ReportLevel.ERROR, "[STICKY] Unlicensed feature in use");
}
return s;
}
}
src/main/java/frc4388/utility/status/FaultReporter.java
+133
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package frc4388.utility.status;
import java.util.ArrayList;
import java.util.List;
import com.ctre.phoenix6.CANBus;
import com.ctre.phoenix6.CANBus.CANBusStatus;
import frc4388.robot.constants.Constants;
import frc4388.utility.status.Status.Report;
import frc4388.utility.status.Status.ReportLevel;
public class FaultReporter {
private static final String REPORTS_HEADER =
"###############\n" + //
"#.............#\n" + //
"#...Reports...#\n" + //
"#.............#\n" + //
"###############\n";
private static final String CAN_HEADER =
"###############\n" + //
"#.............#\n" + //
"#....CAN(t)...#\n" + //
"#.............#\n" + //
"###############\n";
private static final String ERROR_HEADER =
"###############\n" + //
"#.............#\n" + //
"#....ERRORS...#\n" + //
"#.............#\n" + //
"###############\n";
private static List<Queryable> queryables = new ArrayList<>();
// public static void startThread() {
// new Thread() {
// public void run() {
// try{
// while(!this.isInterrupted() && this.isAlive()){
// Thread.sleep(500);
// for(int i=0;i<queryables.size(); i++){
// queryables.get(i).queryStatus();
// }
// // System.out.println("Updated statuses!");
// }
// }catch(Exception e){
// e.printStackTrace();
// }
// }
// }.start();
// }
public static void register(Queryable q) {
queryables.add(q);
}
private static void Log(Queryable q, String s){
System.out.println(q.getName() + " - " + s);
}
public static void printReport() {
List<String> errors = new ArrayList<>();
// Subsystems header
System.out.println(REPORTS_HEADER);
for(int i=0;i< queryables.size();i++){
Queryable q = queryables.get(i);
System.out.println("** Subsystem diagnostic report for " + q.getName() + ":");
Status status = q.diagnosticStatus();
for(int a=0;a<status.reports.size();a++){
Report r = status.reports.get(a);
if(r.reportLevel == ReportLevel.ERROR)
errors.add(q.getName() + " - " + r.toString());
Log(q, r.toString());
}
}
// CAN header
System.out.println(CAN_HEADER);
CANBus canBus = new CANBus(Constants.CANBUS_NAME);
CANBusStatus canInfo = canBus.getStatus();
System.out.println("CANInfo BusOffCount - " + canInfo.BusOffCount);
System.out.println("CANInfo BusUtilization - " + canInfo.BusUtilization);
System.out.println("CANInfo RX Errors count - " + canInfo.REC);
System.out.println("CANInfo TX Errors count - " + canInfo.TEC);
System.out.println("CANInfo Transmit buffer full count - " + canInfo.TxFullCount);
// Broken turniary operator
ReportLevel canReportLevel = canInfo.Status.isOK() ? (canInfo.Status.isWarning() ? ReportLevel.WARNING : ReportLevel.ERROR) : ReportLevel.INFO;
String canStatus = "CAN " + canReportLevel.name() + " - " + canInfo.Status.getName() + " (" + canInfo.Status.getDescription() + ")";
if(canReportLevel == ReportLevel.ERROR) {
errors.add(canStatus);
}
System.out.println(canStatus);
// for(int i=0;i<CanDevice.devices.size();i++){
// CanDevice device = CanDevice.devices.get(i);
// System.out.println("** CAN diagnostic report for " + device.name + ":");
// Status status = device.diagnosticStatus();
// for(int a=0;a<status.reports.size();a++){
// Report r = status.reports.get(a);
// if(r.reportLevel == ReportLevel.ERROR)
// errors.add(device.getName() + " - " + r.toString());
// device.Log(r.toString());
// }
// }
// System.out.println("Found CAN devices: " + new DeviceFinder().Find());
if(errors.size() > 0) {
// Errors header
System.out.println(ERROR_HEADER);
for(int i=0;i<errors.size(); i++){
System.out.println(errors.get(i));
}
}
}
}
src/main/java/frc4388/utility/status/FaultTalonFX.java
+154
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package frc4388.utility.status;
import com.ctre.phoenix6.controls.EmptyControl;
import com.ctre.phoenix6.hardware.TalonFX;
import frc4388.utility.status.Status.ReportLevel;
public class FaultTalonFX implements Queryable {
private String name;
private TalonFX motor;
public static void addDevice(TalonFX motor, String name) {
FaultTalonFX p = new FaultTalonFX();
p.name = name;
p.motor = motor;
FaultReporter.register(p);
}
@Override
public String getName() {
return name;
}
@Override
public Status diagnosticStatus() {
Status s = new Status();
boolean debounceBad = !QueryUtils.isDebounceOk(motor.getSupplyVoltage());
boolean emptyControlBad = motor.setControl(new EmptyControl()).value != 0;
if(debounceBad || emptyControlBad) {
s.addReport(ReportLevel.ERROR, "device is unreachable - Failed" +
(debounceBad ? " Failed debounce test" : "") +
(emptyControlBad ? " Failed empty control test" : "")
);
}
s.addReport(ReportLevel.INFO, "Voltage: " + motor.getSupplyVoltage());
s.addReport(ReportLevel.INFO, "Current: " + motor.getSupplyCurrent());
s.addReport(ReportLevel.INFO, "Device temp: " + motor.getDeviceTemp());
s.addReport(ReportLevel.INFO, "Processor temp: " + motor.getProcessorTemp());
s.addReport(ReportLevel.INFO, "Position: " + motor.getPosition());
s.addReport(ReportLevel.INFO, "Velocity: " + motor.getVelocity());
s.addReport(ReportLevel.INFO, "Acceleration: " + motor.getAcceleration());
// faults<
if (motor.getFault_BootDuringEnable().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Device booted while enabled");
}
if (motor.getFault_BridgeBrownout().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Bridge was disabled most likely due to supply voltage dropping too low");
}
if (motor.getFault_DeviceTemp().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Device temperature exceeded limit");
}
if (motor.getFault_FusedSensorOutOfSync().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Remote sensor is out of sync");
}
if (motor.getFault_Hardware().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Hardware failure detected");
}
if (motor.getFault_MissingDifferentialFX().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "The remote Talon used for differential control is not present");
}
if (motor.getFault_MissingHardLimitRemote().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR,"The remote limit switch device is not present");
}
if (motor.getFault_MissingSoftLimitRemote().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "The remote soft limit device is not present");
}
if (motor.getFault_OverSupplyV().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Supply voltage exceeded limit");
}
if (motor.getFault_ProcTemp().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Processor temperature exceeded limit");
}
if (motor.getFault_RemoteSensorDataInvalid().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "The remote sensor's data is no longer trusted");
}
if (motor.getFault_RemoteSensorPosOverflow().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "remote sensor position has overflowed");
}
if (motor.getFault_RemoteSensorReset().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "The remote sensor has reset");
}
if (motor.getFault_Undervoltage().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, " Device supply voltage near brownout");
}
if (motor.getFault_UnlicensedFeatureInUse().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Unlicensed feature in use");
}
if (motor.getFault_UnstableSupplyV().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "Supply voltage is unstable");
}
// sticky faults
if (motor.getStickyFault_BootDuringEnable().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Device booted while enabled");
}
if (motor.getStickyFault_BridgeBrownout().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Bridge was disabled most likely due to supply voltage dropping too low");
}
if (motor.getStickyFault_DeviceTemp().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Device temperature exceeded limit");
}
if (motor.getStickyFault_FusedSensorOutOfSync().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Remote sensor is out of sync");
}
if (motor.getStickyFault_Hardware().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Hardware failure detected");
}
if (motor.getStickyFault_MissingDifferentialFX().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] The remote Talon used for differential control is not present");
}
if (motor.getStickyFault_MissingHardLimitRemote().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] The remote limit switch device is not present");
}
if (motor.getStickyFault_MissingSoftLimitRemote().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] The remote soft limit device is not present");
}
if (motor.getStickyFault_OverSupplyV().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Supply voltage exceeded limit");
}
if (motor.getStickyFault_ProcTemp().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Processor temperature exceeded limit");
}
if (motor.getStickyFault_RemoteSensorDataInvalid().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] The remote sensor's data is no longer trusted");
}
if (motor.getStickyFault_RemoteSensorPosOverflow().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] The remote sensor position has overflowed");
}
if (motor.getStickyFault_RemoteSensorReset().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] The remote sensor has reset");
}
if (motor.getStickyFault_Undervoltage().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Device supply voltage near brownout");
}
if (motor.getStickyFault_UnlicensedFeatureInUse().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Unlicensed feature in use");
}
if (motor.getStickyFault_UnstableSupplyV().getValue() == Boolean.TRUE) {
s.addReport(ReportLevel.ERROR, "[STICKY] Supply voltage is unstable");
}
return s;
}
}
src/main/java/frc4388/utility/status/QueryUtils.java
+13
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package frc4388.utility.status;
import com.ctre.phoenix6.StatusSignal;
import edu.wpi.first.math.filter.Debouncer;
public class QueryUtils {
public static boolean isDebounceOk(@SuppressWarnings("rawtypes") StatusSignal status) {
Debouncer connectedDebounce = new Debouncer(0.5);
status.refresh();
return connectedDebounce.calculate(status.getStatus().isOK());
};
}
src/main/java/frc4388/utility/status/Queryable.java
+8
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package frc4388.utility.status;
public interface Queryable {
// Get name of subsystem, for use in log.
String getName();
// Proactivly search for any errors in each subsystem
Status diagnosticStatus();
}
src/main/java/frc4388/utility/status/Status.java
+85
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package frc4388.utility.status;
import java.util.ArrayList;
import java.util.List;
import com.ctre.phoenix6.StatusCode;
import com.ctre.phoenix6.controls.EmptyControl;
import com.ctre.phoenix6.hardware.CANcoder;
import com.ctre.phoenix6.hardware.Pigeon2;
import com.ctre.phoenix6.hardware.TalonFX;
public class Status {
public enum ReportLevel {
INFO,
WARNING,
ERROR
}
public class Report {
public ReportLevel reportLevel;
public String description;
@Override
public String toString() {
return this.reportLevel.name() + ": " + this.description;
}
}
public List<Report> reports;
public Status() {
this.reports = new ArrayList<>();
}
public void addReport(ReportLevel level, String description) {
Report r = new Report();
r.reportLevel = level;
r.description = description;
this.reports.add(r);
}
private String printStatusCode(StatusCode status){
return status.getName() + " (" + status.value + ")";
}
public void diagnoseHardwareCTRE(String deviceName, TalonFX motor) {
addReport(ReportLevel.ERROR, deviceName + " Motor (TalonFX) Alive?: " + (motor.isAlive() ? "Alive." : "Dead!"));
if (motor.isAlive()) addReport(ReportLevel.INFO, deviceName + " Motor (TalonFX) Alive?: Alive.");
else addReport(ReportLevel.ERROR, deviceName + " Motor (TalonFX) Alive?: Dead!");
}
public void diagnoseHardwareCTRE(String deviceName, CANcoder coder) {
// Because the Cancoder has no method to check its alive, we send it a empty control which it should return a zero when it gets the control.
// If its not zero, that means that most likely that it had some communication error, I.e. It actually is powered off or not connected at all.
// TODO: validate that a CANCoder can actually do `EmptyControl`s
StatusCode status = coder.setControl(new EmptyControl());
if (status.value == 0) addReport(ReportLevel.INFO, deviceName + " Cancoder Alive?: Alive. " + printStatusCode(status));
else addReport(ReportLevel.ERROR, deviceName + " Cancoder Alive?: Dead! " + printStatusCode(status));
// StatusSignal<MagnetHealthValue> -> MagnetHealthValue -> int
int coderMagHealth = coder.getMagnetHealth().getValue().value;
if (coderMagHealth == 3) addReport(ReportLevel.INFO, deviceName + " Cancoder Magnet Strength?: Ideal."); // why is 3 the 'good value'?
if (coderMagHealth == 2) addReport(ReportLevel.WARNING, deviceName + " Cancoder Magnet Strength?: Subpar.");
if (coderMagHealth == 1) addReport(ReportLevel.ERROR, deviceName + " Cancoder Magnet Strength?: Too Close or Far!");
if (coderMagHealth == 0) addReport(ReportLevel.ERROR, deviceName + " Cancoder Magnet Strength?: Unkown!");
}
public void diagnoseHardwareCTRE(String deviceName, Pigeon2 pigeon) {
// Because the Pigeon has no method to check its alive, we send it a empty control which it should return a zero when it gets the control.
// If its not zero, that means that most likely that it had some communication error, I.e. It actually is powered off or not connected at all.
// TODO: validate that a Pigeon2 can actually do `EmptyControl`s
StatusCode status = pigeon.setControl(new EmptyControl());
if (status.value == 0) addReport(ReportLevel.INFO, deviceName + " Pigeon2 Alive?: Alive. " + printStatusCode(status));
else addReport(ReportLevel.ERROR, deviceName + " Pigeon2 Alive?: Dead! " + printStatusCode(status));
}
public boolean hasReport() {
return reports.size() == 0;
}
}
src/main/java/frc4388/utility/structs/Gains.java
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// 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.
package frc4388.utility.structs;
/** Add your docs here. */
public class Gains {
public double kP;
public double kI;
public double kD;
public double kF;
public int kIZone;
public double kPeakOutput;
public double kMaxOutput;
public double kMinOutput;
/**
* Creates Gains object for PIDs
* @param kP The P value.
* @param kI The I value.
* @param kD The D value.
* @param kF The F value.
* @param kIZone The zone of the I value.
* @param kPeakOutput The peak output setting the motors to run the gains at, in both forward and reverse directions. By default 1.0.
*/
public Gains(double kP, double kI, double kD, double kF, int kIZone, double kPeakOutput) {
this.kP = kP;
this.kI = kI;
this.kD = kD;
this.kF = kF;
this.kIZone = kIZone;
this.kPeakOutput = kPeakOutput;
this.kMaxOutput = kPeakOutput;
this.kMinOutput = -kPeakOutput;
}
/**
* Creates Gains object for PIDs
* @param kP The P value.
* @param kI The I value.
* @param kD The D value.
* @param kF The F value.
* @param kIZone The zone of the I value.
*/
public Gains(double kP, double kI, double kD, double kF, int kIZone) {
this.kP = kP;
this.kI = kI;
this.kD = kD;
this.kF = kF;
this.kIZone = kIZone;
this.kPeakOutput = 1.0;
this.kMaxOutput = 1.0;
this.kMinOutput = -1.0;
}
public Gains(double kP, double kI, double kD) {
this.kP = kP;
this.kI = kI;
this.kD = kD;
}
/**
* Creates Gains object for PIDs
* @param kP The P value.
* @param kI The I value.
* @param kD The D value.
* @param kF The F value.
* @param kIZone The zone of the I value.
* @param kMinOutput The lowest output setting to run the gains at, usually in the reverse direction. By default -1.0.
* @param kMaxOutput The highest output setting to run the gains at, usually in the forward direction. By default 1.0.
*/
public Gains(double kP, double kI, double kD, double kF, int kIZone, double kMaxOutput, double kMinOutput) {
this.kP = kP;
this.kI = kI;
this.kD = kD;
this.kF = kF;
this.kIZone = kIZone;
this.kMaxOutput = kMaxOutput;
this.kMinOutput = kMinOutput;
this.kPeakOutput = (Math.abs(kMinOutput) > Math.abs(kMaxOutput)) ? Math.abs(kMinOutput) : Math.abs(kMaxOutput);
}
}
src/main/java/frc4388/utility/structs/LEDPatterns.java
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package frc4388.utility.structs;
/**
* Add your docs here.
*/
public enum LEDPatterns {
/* PALLETTE PATTERNS */
RAINBOW_RAINBOW(-0.99f), PARTY_RAINBOW(-0.97f), OCEAN_RAINBOW(-0.95f), LAVA_RAINBOW(-0.93f), FOREST_RAINBOW(-0.91f),
RAINBOW_GLITTER(-0.89f), CONFETTI(-0.87f), RED_SHOT(-0.85f), BLUE_SHOT(-0.83f), WHITE_SHOT(-0.81f), RAINBOW_SINELON(-0.79f),
PARTY_SINELON(-0.77f), OCEAN_SINELON(-0.75f), LAVA_SINELON(-0.73f), FOREST_SINELON(-0.71f), RAINBOW_BPM(-0.69f),
PARTY_BPM(-0.67f), OCEAN_BPM(-0.65f), LAVA_BPM(-0.63f), FOREST_BPM(-0.61f), FIRE_MEDIUM(-0.59f), FIRE_LARGE(-0.57f),
RAINBOW_TWINKLES(-0.55f), PARTY_TWINKLES(-0.53f), OCEAN_TWINKLES(-0.51f), LAVA_TWINKLES(-0.49f), FOREST_TWINKLES(-0.47f),
RAINBOW_WAVES(-0.45f), PARTY_WAVES(-0.43f), OCEAN_WAVES(-0.41f), LAVA_WAVES(-0.39f), FOREST_WAVES(-0.37f),
RED_SCANNER(-0.35f), GRAY_SCANNER(-0.33f), RED_CHASE(-0.31f), BLUE_CHASE(-0.29f), GRAY_CHASE(-0.27f), RED_HEARTBEAT(-0.25f),
BLUE_HEARTBEAT(-0.23f), WHITE_HEARTBEAT(-0.21f), GRAY_HEARBEAT(-0.19f), RED_BREATH(-0.17f), BLUE_BREATH(-0.15f),
GRAY_BREATH(-0.13f), RED_STROBE(-0.11f), BLUE_STROBE(-0.09f), GOLD_STROBE(-0.07f), WHITE_STROBE(-0.05f),
/* COLOR 1 PATTERNS */
C1_END_TO_END(-0.03f), C1_SCANNER(-0.01f), C1_CHASE(0.01f), C1_HEARTBEAT_SLOW(0.03f), C1_HEARTBEAT_MEDIUM(0.05f),
C1_HEARTBEAT_FAST(0.07f), C1_BREATH_SLOW(0.09f), C1_BREATH_FAST(0.11f), C1_SHOT(0.13f), C1_STROBE(0.15f),
/* COLOR 2 PATTERNS */
C2_END_TO_END(0.17f), C2_SCANNER(0.19f), C2_CHASE(0.21f), C2_HEARTBEAT_SLOW(0.23f), C2_HEARTBEAT_MEDIUM(0.25f),
C2_HEARTBEAT_FAST(0.27f), C2_BREATH_SLOW(0.29f), C2_BREATH_FAST(0.31f), C2_SHOT(0.33f), C2_STROBE(0.35f),
/* COLOR 1 AND 2 PATTERNS */
C1C2_SPARKLE(0.37f), C2C1_SPARKLE(0.39f), C1C2_GRADIENT(0.41f), C1C2_BPM(0.43f), C1C2_BLEND(0.45f), C1C2_TWINKLES(0.51f),
C1C2_WAVES(0.53f), C1C2_SINELON(0.55f),
/* SOLID COLORS */
SOLID_PINK_HOT(0.57f), SOLID_RED_DARK(0.59f), SOLID_RED(0.61f), SOLID_RED_ORANGE(0.63f), SOLID_ORANGE(0.65f),
SOLID_GOLD(0.67f), SOLID_YELLOW(0.69f), SOLID_GREEN_LAWN(0.71f), SOLID_GREEN_LIME(0.73f), SOLID_GREEN_DARK(0.75f),
SOLID_GREEN(0.77f), SOLID_BLUE_GREEN(0.79f), SOLID_BLUE_AQUA(0.81f), SOLID_BLUE_SKY(0.83f), SOLID_BLUE_DARK(0.85f),
SOLID_BLUE(0.87f), SOLID_BLUE_VIOLET(0.89f), SOLID_VIOLET(0.91f), SOLID_WHITE(0.93f), SOLID_GRAY(0.95f),
SOLID_GRAY_DARK(0.97f), SOLID_BLACK(0.99f);
/* GETTERS/SETTERS */
private final float id;
LEDPatterns(float id) {
this.id = id;
}
public float getValue() {
return id;
}
}
src/main/java/frc4388/utility/structs/UtilityStructs.java
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package frc4388.utility.structs;
public class UtilityStructs {
public static class TimedOutput {
public double leftX = 0.0;
public double leftY = 0.0;
public double rightX = 0.0;
public double rightY = 0.0;
public boolean OPLB;
public boolean OPRB;
public long timedOffset = 0;
}
public static class AutoRecordingControllerFrame {
public double[] axes = new double[6];
public short button = 0;
public short[] POV = new short[1];
}
public static class AutoRecordingFrame {
public AutoRecordingControllerFrame[] controllerFrames = new AutoRecordingControllerFrame[2];
public int timeStamp;
}
}