wpilibc/athena/src/AnalogGyro.cpp - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* Copyright (c) FIRST 2008-2017. All Rights Reserved.                        */
 /* Open Source Software - may be modified and shared by FRC teams. The code   */
 /* must be accompanied by the FIRST BSD license file in the root directory of */
 /* the project.                                                               */
 /*----------------------------------------------------------------------------*/

 #include "AnalogGyro.h"
 #include "HAL/AnalogGyro.h"

 #include <climits>

 #include "AnalogInput.h"
 #include "HAL/Errors.h"
 #include "HAL/HAL.h"
 #include "LiveWindow/LiveWindow.h"
 #include "Timer.h"
 #include "WPIErrors.h"

 using namespace frc;

 const int AnalogGyro::kOversampleBits;
 const int AnalogGyro::kAverageBits;
 constexpr double AnalogGyro::kSamplesPerSecond;
 constexpr double AnalogGyro::kCalibrationSampleTime;
 constexpr double AnalogGyro::kDefaultVoltsPerDegreePerSecond;

 /**
  * Gyro constructor using the Analog Input channel number.
  *
  * @param channel The analog channel the gyro is connected to. Gyros can only
  *                be used on on-board Analog Inputs 0-1.
  */
 AnalogGyro::AnalogGyro(int channel)
     : AnalogGyro(std::make_shared<AnalogInput>(channel)) {}

 /**
  * Gyro constructor with a precreated AnalogInput object.
  *
  * Use this constructor when the analog channel needs to be shared.
  * This object will not clean up the AnalogInput object when using this
  * constructor.
  *
  * Gyros can only be used on on-board channels 0-1.
  *
  * @param channel A pointer to the AnalogInput object that the gyro is
  *                connected to.
  */
 AnalogGyro::AnalogGyro(AnalogInput* channel)
     : AnalogGyro(
           std::shared_ptr<AnalogInput>(channel, NullDeleter<AnalogInput>())) {}

 /**
  * Gyro constructor with a precreated AnalogInput object.
  *
  * Use this constructor when the analog channel needs to be shared.
  * This object will not clean up the AnalogInput object when using this
  * constructor.
  *
  * @param channel A pointer to the AnalogInput object that the gyro is
  *                connected to.
  */
 AnalogGyro::AnalogGyro(std::shared_ptr<AnalogInput> channel)
     : m_analog(channel) {
   if (channel == nullptr) {
     wpi_setWPIError(NullParameter);
   } else {
     InitGyro();
     Calibrate();
   }
 }

 /**
  * Gyro constructor using the Analog Input channel number with parameters for
  * presetting the center and offset values. Bypasses calibration.
  *
  * @param channel The analog channel the gyro is connected to. Gyros can only
  *                be used on on-board Analog Inputs 0-1.
  * @param center  Preset uncalibrated value to use as the accumulator center
  *                value.
  * @param offset  Preset uncalibrated value to use as the gyro offset.
  */
 AnalogGyro::AnalogGyro(int channel, int center, double offset) {
   m_analog = std::make_shared<AnalogInput>(channel);
   InitGyro();
   int32_t status = 0;
   HAL_SetAnalogGyroParameters(m_gyroHandle, kDefaultVoltsPerDegreePerSecond,
                               offset, center, &status);
   if (status != 0) {
     wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
     m_gyroHandle = HAL_kInvalidHandle;
     return;
   }
   Reset();
 }

 /**
  * Gyro constructor with a precreated AnalogInput object and calibrated
  * parameters.
  *
  * Use this constructor when the analog channel needs to be shared.
  * This object will not clean up the AnalogInput object when using this
  * constructor.
  *
  * @param channel A pointer to the AnalogInput object that the gyro is
  *                connected to.
  */
 AnalogGyro::AnalogGyro(std::shared_ptr<AnalogInput> channel, int center,
                        double offset)
     : m_analog(channel) {
   if (channel == nullptr) {
     wpi_setWPIError(NullParameter);
   } else {
     InitGyro();
     int32_t status = 0;
     HAL_SetAnalogGyroParameters(m_gyroHandle, kDefaultVoltsPerDegreePerSecond,
                                 offset, center, &status);
     if (status != 0) {
       wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
       m_gyroHandle = HAL_kInvalidHandle;
       return;
     }
     Reset();
   }
 }

 /**
  * AnalogGyro Destructor
  *
  */
 AnalogGyro::~AnalogGyro() { HAL_FreeAnalogGyro(m_gyroHandle); }

 /**
  * Reset the gyro.
  *
  * Resets the gyro to a heading of zero. This can be used if there is
  * significant drift in the gyro and it needs to be recalibrated after it has
  * been running.
  */
 void AnalogGyro::Reset() {
   if (StatusIsFatal()) return;
   int32_t status = 0;
   HAL_ResetAnalogGyro(m_gyroHandle, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
 }

 /**
  * Initialize the gyro.  Calibration is handled by Calibrate().
  */
 void AnalogGyro::InitGyro() {
   if (StatusIsFatal()) return;
   if (m_gyroHandle == HAL_kInvalidHandle) {
     int32_t status = 0;
     m_gyroHandle = HAL_InitializeAnalogGyro(m_analog->m_port, &status);
     if (status == PARAMETER_OUT_OF_RANGE) {
       wpi_setWPIErrorWithContext(ParameterOutOfRange,
                                  " channel (must be accumulator channel)");
       m_analog = nullptr;
       m_gyroHandle = HAL_kInvalidHandle;
       return;
     }
     if (status != 0) {
       wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
       m_analog = nullptr;
       m_gyroHandle = HAL_kInvalidHandle;
       return;
     }
   }

   int32_t status = 0;
   HAL_SetupAnalogGyro(m_gyroHandle, &status);
   if (status != 0) {
     wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
     m_analog = nullptr;
     m_gyroHandle = HAL_kInvalidHandle;
     return;
   }

   HAL_Report(HALUsageReporting::kResourceType_Gyro, m_analog->GetChannel());
   LiveWindow::GetInstance()->AddSensor("AnalogGyro", m_analog->GetChannel(),
                                        this);
 }

 void AnalogGyro::Calibrate() {
   if (StatusIsFatal()) return;
   int32_t status = 0;
   HAL_CalibrateAnalogGyro(m_gyroHandle, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
 }

 /**
  * Return the actual angle in degrees that the robot is currently facing.
  *
  * The angle is based on the current accumulator value corrected by the
  * oversampling rate, the gyro type and the A/D calibration values.
  * The angle is continuous, that is it will continue from 360->361 degrees. This
  * allows algorithms that wouldn't want to see a discontinuity in the gyro
  * output as it sweeps from 360 to 0 on the second time around.
  *
  * @return the current heading of the robot in degrees. This heading is based on
  *         integration of the returned rate from the gyro.
  */
 double AnalogGyro::GetAngle() const {
   if (StatusIsFatal()) return 0.0;
   int32_t status = 0;
   double value = HAL_GetAnalogGyroAngle(m_gyroHandle, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
   return value;
 }

 /**
  * Return the rate of rotation of the gyro
  *
  * The rate is based on the most recent reading of the gyro analog value
  *
  * @return the current rate in degrees per second
  */
 double AnalogGyro::GetRate() const {
   if (StatusIsFatal()) return 0.0;
   int32_t status = 0;
   double value = HAL_GetAnalogGyroRate(m_gyroHandle, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
   return value;
 }

 /**
  * Return the gyro offset value. If run after calibration,
  * the offset value can be used as a preset later.
  *
  * @return the current offset value
  */
 double AnalogGyro::GetOffset() const {
   if (StatusIsFatal()) return 0.0;
   int32_t status = 0;
   double value = HAL_GetAnalogGyroOffset(m_gyroHandle, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
   return value;
 }

 /**
  * Return the gyro center value. If run after calibration,
  * the center value can be used as a preset later.
  *
  * @return the current center value
  */
 int AnalogGyro::GetCenter() const {
   if (StatusIsFatal()) return 0;
   int32_t status = 0;
   int value = HAL_GetAnalogGyroCenter(m_gyroHandle, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
   return value;
 }

 /**
  * Set the gyro sensitivity.
  *
  * This takes the number of volts/degree/second sensitivity of the gyro and uses
  * it in subsequent calculations to allow the code to work with multiple gyros.
  * This value is typically found in the gyro datasheet.
  *
  * @param voltsPerDegreePerSecond The sensitivity in Volts/degree/second
  */
 void AnalogGyro::SetSensitivity(double voltsPerDegreePerSecond) {
   int32_t status = 0;
   HAL_SetAnalogGyroVoltsPerDegreePerSecond(m_gyroHandle,
                                            voltsPerDegreePerSecond, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
 }

 /**
  * Set the size of the neutral zone.
  *
  * Any voltage from the gyro less than this amount from the center is
  * considered stationary.  Setting a deadband will decrease the amount of drift
  * when the gyro isn't rotating, but will make it less accurate.
  *
  * @param volts The size of the deadband in volts
  */
 void AnalogGyro::SetDeadband(double volts) {
   if (StatusIsFatal()) return;
   int32_t status = 0;
   HAL_SetAnalogGyroDeadband(m_gyroHandle, volts, &status);
   wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
 }
	/----------------------------------------------------------------------------/
	/* Copyright (c) FIRST 2008-2017. All Rights Reserved. */
	/* Open Source Software - may be modified and shared by FRC teams. The code */
	/* must be accompanied by the FIRST BSD license file in the root directory of */
	/* the project. */
	/----------------------------------------------------------------------------/

	#include "AnalogGyro.h"
	#include "HAL/AnalogGyro.h"

	#include <climits>

	#include "AnalogInput.h"
	#include "HAL/Errors.h"
	#include "HAL/HAL.h"
	#include "LiveWindow/LiveWindow.h"
	#include "Timer.h"
	#include "WPIErrors.h"

	using namespace frc;

	const int AnalogGyro::kOversampleBits;
	const int AnalogGyro::kAverageBits;
	constexpr double AnalogGyro::kSamplesPerSecond;
	constexpr double AnalogGyro::kCalibrationSampleTime;
	constexpr double AnalogGyro::kDefaultVoltsPerDegreePerSecond;

	/**
	* Gyro constructor using the Analog Input channel number.
	*
	* @param channel The analog channel the gyro is connected to. Gyros can only
	* be used on on-board Analog Inputs 0-1.
	*/
	AnalogGyro::AnalogGyro(int channel)
	: AnalogGyro(std::make_shared<AnalogInput>(channel)) {}

	/**
	* Gyro constructor with a precreated AnalogInput object.
	*
	* Use this constructor when the analog channel needs to be shared.
	* This object will not clean up the AnalogInput object when using this
	* constructor.
	*
	* Gyros can only be used on on-board channels 0-1.
	*
	* @param channel A pointer to the AnalogInput object that the gyro is
	* connected to.
	*/
	AnalogGyro::AnalogGyro(AnalogInput* channel)
	: AnalogGyro(
	std::shared_ptr<AnalogInput>(channel, NullDeleter<AnalogInput>())) {}

	/**
	* Gyro constructor with a precreated AnalogInput object.
	*
	* Use this constructor when the analog channel needs to be shared.
	* This object will not clean up the AnalogInput object when using this
	* constructor.
	*
	* @param channel A pointer to the AnalogInput object that the gyro is
	* connected to.
	*/
	AnalogGyro::AnalogGyro(std::shared_ptr<AnalogInput> channel)
	: m_analog(channel) {
	if (channel == nullptr) {
	wpi_setWPIError(NullParameter);
	} else {
	InitGyro();
	Calibrate();
	}
	}

	/**
	* Gyro constructor using the Analog Input channel number with parameters for
	* presetting the center and offset values. Bypasses calibration.
	*
	* @param channel The analog channel the gyro is connected to. Gyros can only
	* be used on on-board Analog Inputs 0-1.
	* @param center Preset uncalibrated value to use as the accumulator center
	* value.
	* @param offset Preset uncalibrated value to use as the gyro offset.
	*/
	AnalogGyro::AnalogGyro(int channel, int center, double offset) {
	m_analog = std::make_shared<AnalogInput>(channel);
	InitGyro();
	int32_t status = 0;
	HAL_SetAnalogGyroParameters(m_gyroHandle, kDefaultVoltsPerDegreePerSecond,
	offset, center, &status);
	if (status != 0) {
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	m_gyroHandle = HAL_kInvalidHandle;
	return;
	}
	Reset();
	}

	/**
	* Gyro constructor with a precreated AnalogInput object and calibrated
	* parameters.
	*
	* Use this constructor when the analog channel needs to be shared.
	* This object will not clean up the AnalogInput object when using this
	* constructor.
	*
	* @param channel A pointer to the AnalogInput object that the gyro is
	* connected to.
	*/
	AnalogGyro::AnalogGyro(std::shared_ptr<AnalogInput> channel, int center,
	double offset)
	: m_analog(channel) {
	if (channel == nullptr) {
	wpi_setWPIError(NullParameter);
	} else {
	InitGyro();
	int32_t status = 0;
	HAL_SetAnalogGyroParameters(m_gyroHandle, kDefaultVoltsPerDegreePerSecond,
	offset, center, &status);
	if (status != 0) {
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	m_gyroHandle = HAL_kInvalidHandle;
	return;
	}
	Reset();
	}
	}

	/**
	* AnalogGyro Destructor
	*
	*/
	AnalogGyro::~AnalogGyro() { HAL_FreeAnalogGyro(m_gyroHandle); }

	/**
	* Reset the gyro.
	*
	* Resets the gyro to a heading of zero. This can be used if there is
	* significant drift in the gyro and it needs to be recalibrated after it has
	* been running.
	*/
	void AnalogGyro::Reset() {
	if (StatusIsFatal()) return;
	int32_t status = 0;
	HAL_ResetAnalogGyro(m_gyroHandle, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	}

	/**
	* Initialize the gyro. Calibration is handled by Calibrate().
	*/
	void AnalogGyro::InitGyro() {
	if (StatusIsFatal()) return;
	if (m_gyroHandle == HAL_kInvalidHandle) {
	int32_t status = 0;
	m_gyroHandle = HAL_InitializeAnalogGyro(m_analog->m_port, &status);
	if (status == PARAMETER_OUT_OF_RANGE) {
	wpi_setWPIErrorWithContext(ParameterOutOfRange,
	" channel (must be accumulator channel)");
	m_analog = nullptr;
	m_gyroHandle = HAL_kInvalidHandle;
	return;
	}
	if (status != 0) {
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	m_analog = nullptr;
	m_gyroHandle = HAL_kInvalidHandle;
	return;
	}
	}

	int32_t status = 0;
	HAL_SetupAnalogGyro(m_gyroHandle, &status);
	if (status != 0) {
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	m_analog = nullptr;
	m_gyroHandle = HAL_kInvalidHandle;
	return;
	}

	HAL_Report(HALUsageReporting::kResourceType_Gyro, m_analog->GetChannel());
	LiveWindow::GetInstance()->AddSensor("AnalogGyro", m_analog->GetChannel(),
	this);
	}

	void AnalogGyro::Calibrate() {
	if (StatusIsFatal()) return;
	int32_t status = 0;
	HAL_CalibrateAnalogGyro(m_gyroHandle, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	}

	/**
	* Return the actual angle in degrees that the robot is currently facing.
	*
	* The angle is based on the current accumulator value corrected by the
	* oversampling rate, the gyro type and the A/D calibration values.
	* The angle is continuous, that is it will continue from 360->361 degrees. This
	* allows algorithms that wouldn't want to see a discontinuity in the gyro
	* output as it sweeps from 360 to 0 on the second time around.
	*
	* @return the current heading of the robot in degrees. This heading is based on
	* integration of the returned rate from the gyro.
	*/
	double AnalogGyro::GetAngle() const {
	if (StatusIsFatal()) return 0.0;
	int32_t status = 0;
	double value = HAL_GetAnalogGyroAngle(m_gyroHandle, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	return value;
	}

	/**
	* Return the rate of rotation of the gyro
	*
	* The rate is based on the most recent reading of the gyro analog value
	*
	* @return the current rate in degrees per second
	*/
	double AnalogGyro::GetRate() const {
	if (StatusIsFatal()) return 0.0;
	int32_t status = 0;
	double value = HAL_GetAnalogGyroRate(m_gyroHandle, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	return value;
	}

	/**
	* Return the gyro offset value. If run after calibration,
	* the offset value can be used as a preset later.
	*
	* @return the current offset value
	*/
	double AnalogGyro::GetOffset() const {
	if (StatusIsFatal()) return 0.0;
	int32_t status = 0;
	double value = HAL_GetAnalogGyroOffset(m_gyroHandle, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	return value;
	}

	/**
	* Return the gyro center value. If run after calibration,
	* the center value can be used as a preset later.
	*
	* @return the current center value
	*/
	int AnalogGyro::GetCenter() const {
	if (StatusIsFatal()) return 0;
	int32_t status = 0;
	int value = HAL_GetAnalogGyroCenter(m_gyroHandle, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	return value;
	}

	/**
	* Set the gyro sensitivity.
	*
	* This takes the number of volts/degree/second sensitivity of the gyro and uses
	* it in subsequent calculations to allow the code to work with multiple gyros.
	* This value is typically found in the gyro datasheet.
	*
	* @param voltsPerDegreePerSecond The sensitivity in Volts/degree/second
	*/
	void AnalogGyro::SetSensitivity(double voltsPerDegreePerSecond) {
	int32_t status = 0;
	HAL_SetAnalogGyroVoltsPerDegreePerSecond(m_gyroHandle,
	voltsPerDegreePerSecond, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	}

	/**
	* Set the size of the neutral zone.
	*
	* Any voltage from the gyro less than this amount from the center is
	* considered stationary. Setting a deadband will decrease the amount of drift
	* when the gyro isn't rotating, but will make it less accurate.
	*
	* @param volts The size of the deadband in volts
	*/
	void AnalogGyro::SetDeadband(double volts) {
	if (StatusIsFatal()) return;
	int32_t status = 0;
	HAL_SetAnalogGyroDeadband(m_gyroHandle, volts, &status);
	wpi_setErrorWithContext(status, HAL_GetErrorMessage(status));
	}