wpilibc/Athena/src/PWM.cpp - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* Copyright (c) FIRST 2008-2016. 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 "PWM.h"

 #include "Resource.h"
 #include "Utility.h"
 #include "WPIErrors.h"
 #include "HAL/HAL.hpp"

 #include <sstream>

 constexpr float PWM::kDefaultPwmPeriod;
 constexpr float PWM::kDefaultPwmCenter;
 const int32_t PWM::kDefaultPwmStepsDown;
 const int32_t PWM::kPwmDisabled;

 /**
  * Allocate a PWM given a channel number.
  *
  * Checks channel value range and allocates the appropriate channel.
  * The allocation is only done to help users ensure that they don't double
  * assign channels.
  * @param channel The PWM channel number. 0-9 are on-board, 10-19 are on the MXP
  * port
  */
 PWM::PWM(uint32_t channel) {
   std::stringstream buf;

   if (!CheckPWMChannel(channel)) {
     buf << "PWM Channel " << channel;
     wpi_setWPIErrorWithContext(ChannelIndexOutOfRange, buf.str());
     return;
   }

   int32_t status = 0;
   allocatePWMChannel(m_pwm_ports[channel], &status);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));

   m_channel = channel;

   setPWM(m_pwm_ports[m_channel], kPwmDisabled, &status);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));

   m_eliminateDeadband = false;

   HALReport(HALUsageReporting::kResourceType_PWM, channel);
 }

 /**
  * Free the PWM channel.
  *
  * Free the resource associated with the PWM channel and set the value to 0.
  */
 PWM::~PWM() {
   int32_t status = 0;

   setPWM(m_pwm_ports[m_channel], kPwmDisabled, &status);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));

   freePWMChannel(m_pwm_ports[m_channel], &status);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));

   if (m_table != nullptr) m_table->RemoveTableListener(this);
 }

 /**
  * Optionally eliminate the deadband from a speed controller.
  * @param eliminateDeadband If true, set the motor curve on the Jaguar to
  * eliminate
  * the deadband in the middle of the range. Otherwise, keep the full range
  * without
  * modifying any values.
  */
 void PWM::EnableDeadbandElimination(bool eliminateDeadband) {
   if (StatusIsFatal()) return;
   m_eliminateDeadband = eliminateDeadband;
 }

 /**
  * Set the bounds on the PWM values.
  * This sets the bounds on the PWM values for a particular each type of
  * controller. The values
  * determine the upper and lower speeds as well as the deadband bracket.
  * @param max The Minimum pwm value
  * @param deadbandMax The high end of the deadband range
  * @param center The center speed (off)
  * @param deadbandMin The low end of the deadband range
  * @param min The minimum pwm value
  */
 void PWM::SetBounds(int32_t max, int32_t deadbandMax, int32_t center,
                     int32_t deadbandMin, int32_t min) {
   if (StatusIsFatal()) return;
   m_maxPwm = max;
   m_deadbandMaxPwm = deadbandMax;
   m_centerPwm = center;
   m_deadbandMinPwm = deadbandMin;
   m_minPwm = min;
 }

 /**
  * Set the bounds on the PWM pulse widths.
  * This sets the bounds on the PWM values for a particular type of controller.
  * The values
  * determine the upper and lower speeds as well as the deadband bracket.
  * @param max The max PWM pulse width in ms
  * @param deadbandMax The high end of the deadband range pulse width in ms
  * @param center The center (off) pulse width in ms
  * @param deadbandMin The low end of the deadband pulse width in ms
  * @param min The minimum pulse width in ms
  */
 void PWM::SetBounds(double max, double deadbandMax, double center,
                     double deadbandMin, double min) {
   // calculate the loop time in milliseconds
   int32_t status = 0;
   double loopTime =
       getLoopTiming(&status) / (kSystemClockTicksPerMicrosecond * 1e3);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));

   if (StatusIsFatal()) return;

   m_maxPwm = (int32_t)((max - kDefaultPwmCenter) / loopTime +
                        kDefaultPwmStepsDown - 1);
   m_deadbandMaxPwm = (int32_t)((deadbandMax - kDefaultPwmCenter) / loopTime +
                                kDefaultPwmStepsDown - 1);
   m_centerPwm = (int32_t)((center - kDefaultPwmCenter) / loopTime +
                           kDefaultPwmStepsDown - 1);
   m_deadbandMinPwm = (int32_t)((deadbandMin - kDefaultPwmCenter) / loopTime +
                                kDefaultPwmStepsDown - 1);
   m_minPwm = (int32_t)((min - kDefaultPwmCenter) / loopTime +
                        kDefaultPwmStepsDown - 1);
 }

 /**
  * Set the PWM value based on a position.
  *
  * This is intended to be used by servos.
  *
  * @pre SetMaxPositivePwm() called.
  * @pre SetMinNegativePwm() called.
  *
  * @param pos The position to set the servo between 0.0 and 1.0.
  */
 void PWM::SetPosition(float pos) {
   if (StatusIsFatal()) return;
   if (pos < 0.0) {
     pos = 0.0;
   } else if (pos > 1.0) {
     pos = 1.0;
   }

   // note, need to perform the multiplication below as floating point before
   // converting to int
   unsigned short rawValue =
       (int32_t)((pos * (float)GetFullRangeScaleFactor()) + GetMinNegativePwm());
   //	printf("MinNegPWM: %d FullRangeScaleFactor: %d Raw value: %5d   Input
   //value: %4.4f\n", GetMinNegativePwm(), GetFullRangeScaleFactor(), rawValue,
   //pos);

   //	wpi_assert((rawValue >= GetMinNegativePwm()) && (rawValue <=
   //GetMaxPositivePwm()));
   wpi_assert(rawValue != kPwmDisabled);

   // send the computed pwm value to the FPGA
   SetRaw((unsigned short)rawValue);
 }

 /**
  * Get the PWM value in terms of a position.
  *
  * This is intended to be used by servos.
  *
  * @pre SetMaxPositivePwm() called.
  * @pre SetMinNegativePwm() called.
  *
  * @return The position the servo is set to between 0.0 and 1.0.
  */
 float PWM::GetPosition() const {
   if (StatusIsFatal()) return 0.0;
   int32_t value = GetRaw();
   if (value < GetMinNegativePwm()) {
     return 0.0;
   } else if (value > GetMaxPositivePwm()) {
     return 1.0;
   } else {
     return (float)(value - GetMinNegativePwm()) /
            (float)GetFullRangeScaleFactor();
   }
 }

 /**
  * Set the PWM value based on a speed.
  *
  * This is intended to be used by speed controllers.
  *
  * @pre SetMaxPositivePwm() called.
  * @pre SetMinPositivePwm() called.
  * @pre SetCenterPwm() called.
  * @pre SetMaxNegativePwm() called.
  * @pre SetMinNegativePwm() called.
  *
  * @param speed The speed to set the speed controller between -1.0 and 1.0.
  */
 void PWM::SetSpeed(float speed) {
   if (StatusIsFatal()) return;
   // clamp speed to be in the range 1.0 >= speed >= -1.0
   if (speed < -1.0) {
     speed = -1.0;
   } else if (speed > 1.0) {
     speed = 1.0;
   }

   // calculate the desired output pwm value by scaling the speed appropriately
   int32_t rawValue;
   if (speed == 0.0) {
     rawValue = GetCenterPwm();
   } else if (speed > 0.0) {
     rawValue = (int32_t)(speed * ((float)GetPositiveScaleFactor()) +
                          ((float)GetMinPositivePwm()) + 0.5);
   } else {
     rawValue = (int32_t)(speed * ((float)GetNegativeScaleFactor()) +
                          ((float)GetMaxNegativePwm()) + 0.5);
   }

   // the above should result in a pwm_value in the valid range
   wpi_assert((rawValue >= GetMinNegativePwm()) &&
              (rawValue <= GetMaxPositivePwm()));
   wpi_assert(rawValue != kPwmDisabled);

   // send the computed pwm value to the FPGA
   SetRaw(rawValue);
 }

 /**
  * Get the PWM value in terms of speed.
  *
  * This is intended to be used by speed controllers.
  *
  * @pre SetMaxPositivePwm() called.
  * @pre SetMinPositivePwm() called.
  * @pre SetMaxNegativePwm() called.
  * @pre SetMinNegativePwm() called.
  *
  * @return The most recently set speed between -1.0 and 1.0.
  */
 float PWM::GetSpeed() const {
   if (StatusIsFatal()) return 0.0;
   int32_t value = GetRaw();
   if (value == PWM::kPwmDisabled) {
     return 0.0;
   } else if (value > GetMaxPositivePwm()) {
     return 1.0;
   } else if (value < GetMinNegativePwm()) {
     return -1.0;
   } else if (value > GetMinPositivePwm()) {
     return (float)(value - GetMinPositivePwm()) /
            (float)GetPositiveScaleFactor();
   } else if (value < GetMaxNegativePwm()) {
     return (float)(value - GetMaxNegativePwm()) /
            (float)GetNegativeScaleFactor();
   } else {
     return 0.0;
   }
 }

 /**
  * Set the PWM value directly to the hardware.
  *
  * Write a raw value to a PWM channel.
  *
  * @param value Raw PWM value.
  */
 void PWM::SetRaw(unsigned short value) {
   if (StatusIsFatal()) return;

   int32_t status = 0;
   setPWM(m_pwm_ports[m_channel], value, &status);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));
 }

 /**
  * Get the PWM value directly from the hardware.
  *
  * Read a raw value from a PWM channel.
  *
  * @return Raw PWM control value.
  */
 unsigned short PWM::GetRaw() const {
   if (StatusIsFatal()) return 0;

   int32_t status = 0;
   unsigned short value = getPWM(m_pwm_ports[m_channel], &status);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));

   return value;
 }

 /**
  * Slow down the PWM signal for old devices.
  *
  * @param mult The period multiplier to apply to this channel
  */
 void PWM::SetPeriodMultiplier(PeriodMultiplier mult) {
   if (StatusIsFatal()) return;

   int32_t status = 0;

   switch (mult) {
     case kPeriodMultiplier_4X:
       setPWMPeriodScale(m_pwm_ports[m_channel], 3,
                         &status);  // Squelch 3 out of 4 outputs
       break;
     case kPeriodMultiplier_2X:
       setPWMPeriodScale(m_pwm_ports[m_channel], 1,
                         &status);  // Squelch 1 out of 2 outputs
       break;
     case kPeriodMultiplier_1X:
       setPWMPeriodScale(m_pwm_ports[m_channel], 0,
                         &status);  // Don't squelch any outputs
       break;
     default:
       wpi_assert(false);
   }

   wpi_setErrorWithContext(status, getHALErrorMessage(status));
 }

 void PWM::SetZeroLatch() {
   if (StatusIsFatal()) return;

   int32_t status = 0;

   latchPWMZero(m_pwm_ports[m_channel], &status);
   wpi_setErrorWithContext(status, getHALErrorMessage(status));
 }

 void PWM::ValueChanged(ITable* source, llvm::StringRef key,
                        std::shared_ptr<nt::Value> value, bool isNew) {
   if (!value->IsDouble()) return;
   SetSpeed(value->GetDouble());
 }

 void PWM::UpdateTable() {
   if (m_table != nullptr) {
     m_table->PutNumber("Value", GetSpeed());
   }
 }

 void PWM::StartLiveWindowMode() {
   SetSpeed(0);
   if (m_table != nullptr) {
     m_table->AddTableListener("Value", this, true);
   }
 }

 void PWM::StopLiveWindowMode() {
   SetSpeed(0);
   if (m_table != nullptr) {
     m_table->RemoveTableListener(this);
   }
 }

 std::string PWM::GetSmartDashboardType() const { return "Speed Controller"; }

 void PWM::InitTable(std::shared_ptr<ITable> subTable) {
   m_table = subTable;
   UpdateTable();
 }

 std::shared_ptr<ITable> PWM::GetTable() const { return m_table; }
	/----------------------------------------------------------------------------/
	/* Copyright (c) FIRST 2008-2016. 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 "PWM.h"

	#include "Resource.h"
	#include "Utility.h"
	#include "WPIErrors.h"
	#include "HAL/HAL.hpp"

	#include <sstream>

	constexpr float PWM::kDefaultPwmPeriod;
	constexpr float PWM::kDefaultPwmCenter;
	const int32_t PWM::kDefaultPwmStepsDown;
	const int32_t PWM::kPwmDisabled;

	/**
	* Allocate a PWM given a channel number.
	*
	* Checks channel value range and allocates the appropriate channel.
	* The allocation is only done to help users ensure that they don't double
	* assign channels.
	* @param channel The PWM channel number. 0-9 are on-board, 10-19 are on the MXP
	* port
	*/
	PWM::PWM(uint32_t channel) {
	std::stringstream buf;

	if (!CheckPWMChannel(channel)) {
	buf << "PWM Channel " << channel;
	wpi_setWPIErrorWithContext(ChannelIndexOutOfRange, buf.str());
	return;
	}

	int32_t status = 0;
	allocatePWMChannel(m_pwm_ports[channel], &status);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));

	m_channel = channel;

	setPWM(m_pwm_ports[m_channel], kPwmDisabled, &status);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));

	m_eliminateDeadband = false;

	HALReport(HALUsageReporting::kResourceType_PWM, channel);
	}

	/**
	* Free the PWM channel.
	*
	* Free the resource associated with the PWM channel and set the value to 0.
	*/
	PWM::~PWM() {
	int32_t status = 0;

	setPWM(m_pwm_ports[m_channel], kPwmDisabled, &status);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));

	freePWMChannel(m_pwm_ports[m_channel], &status);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));

	if (m_table != nullptr) m_table->RemoveTableListener(this);
	}

	/**
	* Optionally eliminate the deadband from a speed controller.
	* @param eliminateDeadband If true, set the motor curve on the Jaguar to
	* eliminate
	* the deadband in the middle of the range. Otherwise, keep the full range
	* without
	* modifying any values.
	*/
	void PWM::EnableDeadbandElimination(bool eliminateDeadband) {
	if (StatusIsFatal()) return;
	m_eliminateDeadband = eliminateDeadband;
	}

	/**
	* Set the bounds on the PWM values.
	* This sets the bounds on the PWM values for a particular each type of
	* controller. The values
	* determine the upper and lower speeds as well as the deadband bracket.
	* @param max The Minimum pwm value
	* @param deadbandMax The high end of the deadband range
	* @param center The center speed (off)
	* @param deadbandMin The low end of the deadband range
	* @param min The minimum pwm value
	*/
	void PWM::SetBounds(int32_t max, int32_t deadbandMax, int32_t center,
	int32_t deadbandMin, int32_t min) {
	if (StatusIsFatal()) return;
	m_maxPwm = max;
	m_deadbandMaxPwm = deadbandMax;
	m_centerPwm = center;
	m_deadbandMinPwm = deadbandMin;
	m_minPwm = min;
	}

	/**
	* Set the bounds on the PWM pulse widths.
	* This sets the bounds on the PWM values for a particular type of controller.
	* The values
	* determine the upper and lower speeds as well as the deadband bracket.
	* @param max The max PWM pulse width in ms
	* @param deadbandMax The high end of the deadband range pulse width in ms
	* @param center The center (off) pulse width in ms
	* @param deadbandMin The low end of the deadband pulse width in ms
	* @param min The minimum pulse width in ms
	*/
	void PWM::SetBounds(double max, double deadbandMax, double center,
	double deadbandMin, double min) {
	// calculate the loop time in milliseconds
	int32_t status = 0;
	double loopTime =
	getLoopTiming(&status) / (kSystemClockTicksPerMicrosecond * 1e3);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));

	if (StatusIsFatal()) return;

	m_maxPwm = (int32_t)((max - kDefaultPwmCenter) / loopTime +
	kDefaultPwmStepsDown - 1);
	m_deadbandMaxPwm = (int32_t)((deadbandMax - kDefaultPwmCenter) / loopTime +
	kDefaultPwmStepsDown - 1);
	m_centerPwm = (int32_t)((center - kDefaultPwmCenter) / loopTime +
	kDefaultPwmStepsDown - 1);
	m_deadbandMinPwm = (int32_t)((deadbandMin - kDefaultPwmCenter) / loopTime +
	kDefaultPwmStepsDown - 1);
	m_minPwm = (int32_t)((min - kDefaultPwmCenter) / loopTime +
	kDefaultPwmStepsDown - 1);
	}

	/**
	* Set the PWM value based on a position.
	*
	* This is intended to be used by servos.
	*
	* @pre SetMaxPositivePwm() called.
	* @pre SetMinNegativePwm() called.
	*
	* @param pos The position to set the servo between 0.0 and 1.0.
	*/
	void PWM::SetPosition(float pos) {
	if (StatusIsFatal()) return;
	if (pos < 0.0) {
	pos = 0.0;
	} else if (pos > 1.0) {
	pos = 1.0;
	}

	// note, need to perform the multiplication below as floating point before
	// converting to int
	unsigned short rawValue =
	(int32_t)((pos * (float)GetFullRangeScaleFactor()) + GetMinNegativePwm());
	// printf("MinNegPWM: %d FullRangeScaleFactor: %d Raw value: %5d Input
	//value: %4.4f\n", GetMinNegativePwm(), GetFullRangeScaleFactor(), rawValue,
	//pos);

	// wpi_assert((rawValue >= GetMinNegativePwm()) && (rawValue <=
	//GetMaxPositivePwm()));
	wpi_assert(rawValue != kPwmDisabled);

	// send the computed pwm value to the FPGA
	SetRaw((unsigned short)rawValue);
	}

	/**
	* Get the PWM value in terms of a position.
	*
	* This is intended to be used by servos.
	*
	* @pre SetMaxPositivePwm() called.
	* @pre SetMinNegativePwm() called.
	*
	* @return The position the servo is set to between 0.0 and 1.0.
	*/
	float PWM::GetPosition() const {
	if (StatusIsFatal()) return 0.0;
	int32_t value = GetRaw();
	if (value < GetMinNegativePwm()) {
	return 0.0;
	} else if (value > GetMaxPositivePwm()) {
	return 1.0;
	} else {
	return (float)(value - GetMinNegativePwm()) /
	(float)GetFullRangeScaleFactor();
	}
	}

	/**
	* Set the PWM value based on a speed.
	*
	* This is intended to be used by speed controllers.
	*
	* @pre SetMaxPositivePwm() called.
	* @pre SetMinPositivePwm() called.
	* @pre SetCenterPwm() called.
	* @pre SetMaxNegativePwm() called.
	* @pre SetMinNegativePwm() called.
	*
	* @param speed The speed to set the speed controller between -1.0 and 1.0.
	*/
	void PWM::SetSpeed(float speed) {
	if (StatusIsFatal()) return;
	// clamp speed to be in the range 1.0 >= speed >= -1.0
	if (speed < -1.0) {
	speed = -1.0;
	} else if (speed > 1.0) {
	speed = 1.0;
	}

	// calculate the desired output pwm value by scaling the speed appropriately
	int32_t rawValue;
	if (speed == 0.0) {
	rawValue = GetCenterPwm();
	} else if (speed > 0.0) {
	rawValue = (int32_t)(speed * ((float)GetPositiveScaleFactor()) +
	((float)GetMinPositivePwm()) + 0.5);
	} else {
	rawValue = (int32_t)(speed * ((float)GetNegativeScaleFactor()) +
	((float)GetMaxNegativePwm()) + 0.5);
	}

	// the above should result in a pwm_value in the valid range
	wpi_assert((rawValue >= GetMinNegativePwm()) &&
	(rawValue <= GetMaxPositivePwm()));
	wpi_assert(rawValue != kPwmDisabled);

	// send the computed pwm value to the FPGA
	SetRaw(rawValue);
	}

	/**
	* Get the PWM value in terms of speed.
	*
	* This is intended to be used by speed controllers.
	*
	* @pre SetMaxPositivePwm() called.
	* @pre SetMinPositivePwm() called.
	* @pre SetMaxNegativePwm() called.
	* @pre SetMinNegativePwm() called.
	*
	* @return The most recently set speed between -1.0 and 1.0.
	*/
	float PWM::GetSpeed() const {
	if (StatusIsFatal()) return 0.0;
	int32_t value = GetRaw();
	if (value == PWM::kPwmDisabled) {
	return 0.0;
	} else if (value > GetMaxPositivePwm()) {
	return 1.0;
	} else if (value < GetMinNegativePwm()) {
	return -1.0;
	} else if (value > GetMinPositivePwm()) {
	return (float)(value - GetMinPositivePwm()) /
	(float)GetPositiveScaleFactor();
	} else if (value < GetMaxNegativePwm()) {
	return (float)(value - GetMaxNegativePwm()) /
	(float)GetNegativeScaleFactor();
	} else {
	return 0.0;
	}
	}

	/**
	* Set the PWM value directly to the hardware.
	*
	* Write a raw value to a PWM channel.
	*
	* @param value Raw PWM value.
	*/
	void PWM::SetRaw(unsigned short value) {
	if (StatusIsFatal()) return;

	int32_t status = 0;
	setPWM(m_pwm_ports[m_channel], value, &status);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));
	}

	/**
	* Get the PWM value directly from the hardware.
	*
	* Read a raw value from a PWM channel.
	*
	* @return Raw PWM control value.
	*/
	unsigned short PWM::GetRaw() const {
	if (StatusIsFatal()) return 0;

	int32_t status = 0;
	unsigned short value = getPWM(m_pwm_ports[m_channel], &status);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));

	return value;
	}

	/**
	* Slow down the PWM signal for old devices.
	*
	* @param mult The period multiplier to apply to this channel
	*/
	void PWM::SetPeriodMultiplier(PeriodMultiplier mult) {
	if (StatusIsFatal()) return;

	int32_t status = 0;

	switch (mult) {
	case kPeriodMultiplier_4X:
	setPWMPeriodScale(m_pwm_ports[m_channel], 3,
	&status); // Squelch 3 out of 4 outputs
	break;
	case kPeriodMultiplier_2X:
	setPWMPeriodScale(m_pwm_ports[m_channel], 1,
	&status); // Squelch 1 out of 2 outputs
	break;
	case kPeriodMultiplier_1X:
	setPWMPeriodScale(m_pwm_ports[m_channel], 0,
	&status); // Don't squelch any outputs
	break;
	default:
	wpi_assert(false);
	}

	wpi_setErrorWithContext(status, getHALErrorMessage(status));
	}

	void PWM::SetZeroLatch() {
	if (StatusIsFatal()) return;

	int32_t status = 0;

	latchPWMZero(m_pwm_ports[m_channel], &status);
	wpi_setErrorWithContext(status, getHALErrorMessage(status));
	}

	void PWM::ValueChanged(ITable* source, llvm::StringRef key,
	std::shared_ptr<nt::Value> value, bool isNew) {
	if (!value->IsDouble()) return;
	SetSpeed(value->GetDouble());
	}

	void PWM::UpdateTable() {
	if (m_table != nullptr) {
	m_table->PutNumber("Value", GetSpeed());
	}
	}

	void PWM::StartLiveWindowMode() {
	SetSpeed(0);
	if (m_table != nullptr) {
	m_table->AddTableListener("Value", this, true);
	}
	}

	void PWM::StopLiveWindowMode() {
	SetSpeed(0);
	if (m_table != nullptr) {
	m_table->RemoveTableListener(this);
	}
	}

	std::string PWM::GetSmartDashboardType() const { return "Speed Controller"; }

	void PWM::InitTable(std::shared_ptr<ITable> subTable) {
	m_table = subTable;
	UpdateTable();
	}

	std::shared_ptr<ITable> PWM::GetTable() const { return m_table; }