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package org.firstinspires.ftc.robotcontroller.external.samples;

import com.qualcomm.hardware.modernrobotics.ModernRoboticsI2cGyro;
import com.qualcomm.robotcore.eventloop.opmode.Disabled;
import com.qualcomm.robotcore.eventloop.opmode.LinearOpMode;
import com.qualcomm.robotcore.eventloop.opmode.TeleOp;
import com.qualcomm.robotcore.hardware.Gyroscope;
import com.qualcomm.robotcore.hardware.IntegratingGyroscope;
import com.qualcomm.robotcore.util.ElapsedTime;

import org.firstinspires.ftc.robotcore.external.navigation.AngleUnit;
import org.firstinspires.ftc.robotcore.external.navigation.AngularVelocity;
import org.firstinspires.ftc.robotcore.external.navigation.AxesOrder;
import org.firstinspires.ftc.robotcore.external.navigation.AxesReference;

/*
 * This is an example LinearOpMode that shows how to use the Modern Robotics Gyro.
 *
 * The op mode assumes that the gyro sensor is attached to a Device Interface Module
 * I2C channel and is configured with a name of "gyro".
 *
 * Use Android Studio to Copy this Class, and Paste it into your team's code folder with a new name.
 * Remove or comment out the @Disabled line to add this opmode to the Driver Station OpMode list
*/
@TeleOp(name = "Sensor: MR Gyro", group = "Sensor")
@Disabled
public class SensorMRGyro extends LinearOpMode {

  /** In this sample, for illustration purposes we use two interfaces on the one gyro object.
   * That's likely atypical: you'll probably use one or the other in any given situation,
   * depending on what you're trying to do. {@link IntegratingGyroscope} (and it's base interface,
   * {@link Gyroscope}) are common interfaces supported by possibly several different gyro
   * implementations. {@link ModernRoboticsI2cGyro}, by contrast, provides functionality that
   * is unique to the Modern Robotics gyro sensor.
   */
  IntegratingGyroscope gyro;
  ModernRoboticsI2cGyro modernRoboticsI2cGyro;

  // A timer helps provide feedback while calibration is taking place
  ElapsedTime timer = new ElapsedTime();

  @Override
  public void runOpMode() {

    boolean lastResetState = false;
    boolean curResetState  = false;

    // Get a reference to a Modern Robotics gyro object. We use several interfaces
    // on this object to illustrate which interfaces support which functionality.
    modernRoboticsI2cGyro = hardwareMap.get(ModernRoboticsI2cGyro.class, "gyro");
    gyro = (IntegratingGyroscope)modernRoboticsI2cGyro;
    // If you're only interested int the IntegratingGyroscope interface, the following will suffice.
    // gyro = hardwareMap.get(IntegratingGyroscope.class, "gyro");
    // A similar approach will work for the Gyroscope interface, if that's all you need.

    // Start calibrating the gyro. This takes a few seconds and is worth performing
    // during the initialization phase at the start of each opMode.
    telemetry.log().add("Gyro Calibrating. Do Not Move!");
    modernRoboticsI2cGyro.calibrate();

    // Wait until the gyro calibration is complete
    timer.reset();
    while (!isStopRequested() && modernRoboticsI2cGyro.isCalibrating())  {
      telemetry.addData("calibrating", "%s", Math.round(timer.seconds())%2==0 ? "|.." : "..|");
      telemetry.update();
      sleep(50);
    }

    telemetry.log().clear(); telemetry.log().add("Gyro Calibrated. Press Start.");
    telemetry.clear(); telemetry.update();

    // Wait for the start button to be pressed
    waitForStart();
    telemetry.log().clear();
    telemetry.log().add("Press A & B to reset heading");

    // Loop until we're asked to stop
    while (opModeIsActive())  {

      // If the A and B buttons are pressed just now, reset Z heading.
      curResetState = (gamepad1.a && gamepad1.b);
      if (curResetState && !lastResetState) {
        modernRoboticsI2cGyro.resetZAxisIntegrator();
      }
      lastResetState = curResetState;

      // The raw() methods report the angular rate of change about each of the
      // three axes directly as reported by the underlying sensor IC.
      int rawX = modernRoboticsI2cGyro.rawX();
      int rawY = modernRoboticsI2cGyro.rawY();
      int rawZ = modernRoboticsI2cGyro.rawZ();
      int heading = modernRoboticsI2cGyro.getHeading();
      int integratedZ = modernRoboticsI2cGyro.getIntegratedZValue();

      // Read dimensionalized data from the gyro. This gyro can report angular velocities
      // about all three axes. Additionally, it internally integrates the Z axis to
      // be able to report an absolute angular Z orientation.
      AngularVelocity rates = gyro.getAngularVelocity(AngleUnit.DEGREES);
      float zAngle = gyro.getAngularOrientation(AxesReference.INTRINSIC, AxesOrder.ZYX, AngleUnit.DEGREES).firstAngle;

      // Read administrative information from the gyro
      int zAxisOffset = modernRoboticsI2cGyro.getZAxisOffset();
      int zAxisScalingCoefficient = modernRoboticsI2cGyro.getZAxisScalingCoefficient();

      telemetry.addLine()
        .addData("dx", formatRate(rates.xRotationRate))
        .addData("dy", formatRate(rates.yRotationRate))
        .addData("dz", "%s deg/s", formatRate(rates.zRotationRate));
      telemetry.addData("angle", "%s deg", formatFloat(zAngle));
      telemetry.addData("heading", "%3d deg", heading);
      telemetry.addData("integrated Z", "%3d", integratedZ);
      telemetry.addLine()
        .addData("rawX", formatRaw(rawX))
        .addData("rawY", formatRaw(rawY))
        .addData("rawZ", formatRaw(rawZ));
      telemetry.addLine().addData("z offset", zAxisOffset).addData("z coeff", zAxisScalingCoefficient);
      telemetry.update();
    }
  }

  String formatRaw(int rawValue) {
    return String.format("%d", rawValue);
  }

  String formatRate(float rate) {
    return String.format("%.3f", rate);
  }

  String formatFloat(float rate) {
    return String.format("%.3f", rate);
  }

}