FRC2016-old/wpilib/cpp/current/include/PWM.h

/*----------------------------------------------------------------------------*/
/* 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.                                                               */
/*----------------------------------------------------------------------------*/

#pragma once

#include "SensorBase.h"
#include "LiveWindow/LiveWindowSendable.h"
#include "tables/ITableListener.h"

#include <memory>

/**
 * Class implements the PWM generation in the FPGA.
 *
 * The values supplied as arguments for PWM outputs range from -1.0 to 1.0. They
 * are mapped
 * to the hardware dependent values, in this case 0-2000 for the FPGA.
 * Changes are immediately sent to the FPGA, and the update occurs at the next
 * FPGA cycle. There is no delay.
 *
 * As of revision 0.1.10 of the FPGA, the FPGA interprets the 0-2000 values as
 * follows:
 *   - 2000 = maximum pulse width
 *   - 1999 to 1001 = linear scaling from "full forward" to "center"
 *   - 1000 = center value
 *   - 999 to 2 = linear scaling from "center" to "full reverse"
 *   - 1 = minimum pulse width (currently .5ms)
 *   - 0 = disabled (i.e. PWM output is held low)
 */
class PWM : public SensorBase,
            public ITableListener,
            public LiveWindowSendable {
 public:
  enum PeriodMultiplier {
    kPeriodMultiplier_1X = 1,
    kPeriodMultiplier_2X = 2,
    kPeriodMultiplier_4X = 4
  };

  explicit PWM(uint32_t channel);
  virtual ~PWM();
  virtual void SetRaw(unsigned short value);
  virtual unsigned short GetRaw() const;
  void SetPeriodMultiplier(PeriodMultiplier mult);
  void SetZeroLatch();
  void EnableDeadbandElimination(bool eliminateDeadband);
  void SetBounds(int32_t max, int32_t deadbandMax, int32_t center,
                 int32_t deadbandMin, int32_t min);
  void SetBounds(double max, double deadbandMax, double center,
                 double deadbandMin, double min);
  uint32_t GetChannel() const { return m_channel; }

 protected:
  /**
   * kDefaultPwmPeriod is in ms
   *
   * - 20ms periods (50 Hz) are the "safest" setting in that this works for all
   * devices
   * - 20ms periods seem to be desirable for Vex Motors
   * - 20ms periods are the specified period for HS-322HD servos, but work
   * reliably down
   *      to 10.0 ms; starting at about 8.5ms, the servo sometimes hums and get
   *hot;
   *      by 5.0ms the hum is nearly continuous
   * - 10ms periods work well for Victor 884
   * - 5ms periods allows higher update rates for Luminary Micro Jaguar speed
   * controllers.
   *      Due to the shipping firmware on the Jaguar, we can't run the update
   * period less
   *      than 5.05 ms.
   *
   * kDefaultPwmPeriod is the 1x period (5.05 ms).  In hardware, the period
   * scaling is implemented as an
   * output squelch to get longer periods for old devices.
   */
  static constexpr float kDefaultPwmPeriod = 5.05;
  /**
   * kDefaultPwmCenter is the PWM range center in ms
   */
  static constexpr float kDefaultPwmCenter = 1.5;
  /**
   * kDefaultPWMStepsDown is the number of PWM steps below the centerpoint
   */
  static const int32_t kDefaultPwmStepsDown = 1000;
  static const int32_t kPwmDisabled = 0;

  virtual void SetPosition(float pos);
  virtual float GetPosition() const;
  virtual void SetSpeed(float speed);
  virtual float GetSpeed() const;

  bool m_eliminateDeadband;
  int32_t m_maxPwm;
  int32_t m_deadbandMaxPwm;
  int32_t m_centerPwm;
  int32_t m_deadbandMinPwm;
  int32_t m_minPwm;

  void ValueChanged(ITable* source, llvm::StringRef key,
                    std::shared_ptr<nt::Value> value, bool isNew) override;
  void UpdateTable() override;
  void StartLiveWindowMode() override;
  void StopLiveWindowMode() override;
  std::string GetSmartDashboardType() const override;
  void InitTable(std::shared_ptr<ITable> subTable) override;
  std::shared_ptr<ITable> GetTable() const override;

  std::shared_ptr<ITable> m_table;

 private:
  uint32_t m_channel;
  int32_t GetMaxPositivePwm() const { return m_maxPwm; }
  int32_t GetMinPositivePwm() const {
    return m_eliminateDeadband ? m_deadbandMaxPwm : m_centerPwm + 1;
  }
  int32_t GetCenterPwm() const { return m_centerPwm; }
  int32_t GetMaxNegativePwm() const {
    return m_eliminateDeadband ? m_deadbandMinPwm : m_centerPwm - 1;
  }
  int32_t GetMinNegativePwm() const { return m_minPwm; }
  int32_t GetPositiveScaleFactor() const {
    return GetMaxPositivePwm() - GetMinPositivePwm();
  }  ///< The scale for positive speeds.
  int32_t GetNegativeScaleFactor() const {
    return GetMaxNegativePwm() - GetMinNegativePwm();
  }  ///< The scale for negative speeds.
  int32_t GetFullRangeScaleFactor() const {
    return GetMaxPositivePwm() - GetMinNegativePwm();
  }  ///< The scale for positions.
};
Initial Commit 2016-01-28 11:33:19 -05:00			`/----------------------------------------------------------------------------/`
			`/* 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. */`
			`/----------------------------------------------------------------------------/`

			`#pragma once`

			`#include "SensorBase.h"`
			`#include "LiveWindow/LiveWindowSendable.h"`
			`#include "tables/ITableListener.h"`

			`#include <memory>`

			`/**`
			`* Class implements the PWM generation in the FPGA.`
			`*`
			`* The values supplied as arguments for PWM outputs range from -1.0 to 1.0. They`
			`* are mapped`
			`* to the hardware dependent values, in this case 0-2000 for the FPGA.`
			`* Changes are immediately sent to the FPGA, and the update occurs at the next`
			`* FPGA cycle. There is no delay.`
			`*`
			`* As of revision 0.1.10 of the FPGA, the FPGA interprets the 0-2000 values as`
			`* follows:`
			`* - 2000 = maximum pulse width`
			`* - 1999 to 1001 = linear scaling from "full forward" to "center"`
			`* - 1000 = center value`
			`* - 999 to 2 = linear scaling from "center" to "full reverse"`
			`* - 1 = minimum pulse width (currently .5ms)`
			`* - 0 = disabled (i.e. PWM output is held low)`
			`*/`
			`class PWM : public SensorBase,`
			`public ITableListener,`
			`public LiveWindowSendable {`
			`public:`
			`enum PeriodMultiplier {`
			`kPeriodMultiplier_1X = 1,`
			`kPeriodMultiplier_2X = 2,`
			`kPeriodMultiplier_4X = 4`
			`};`

			`explicit PWM(uint32_t channel);`
			`virtual ~PWM();`
			`virtual void SetRaw(unsigned short value);`
			`virtual unsigned short GetRaw() const;`
			`void SetPeriodMultiplier(PeriodMultiplier mult);`
			`void SetZeroLatch();`
			`void EnableDeadbandElimination(bool eliminateDeadband);`
			`void SetBounds(int32_t max, int32_t deadbandMax, int32_t center,`
			`int32_t deadbandMin, int32_t min);`
			`void SetBounds(double max, double deadbandMax, double center,`
			`double deadbandMin, double min);`
			`uint32_t GetChannel() const { return m_channel; }`

			`protected:`
			`/**`
			`* kDefaultPwmPeriod is in ms`
			`*`
			`* - 20ms periods (50 Hz) are the "safest" setting in that this works for all`
			`* devices`
			`* - 20ms periods seem to be desirable for Vex Motors`
			`* - 20ms periods are the specified period for HS-322HD servos, but work`
			`* reliably down`
			`* to 10.0 ms; starting at about 8.5ms, the servo sometimes hums and get`
			`*hot;`
			`* by 5.0ms the hum is nearly continuous`
			`* - 10ms periods work well for Victor 884`
			`* - 5ms periods allows higher update rates for Luminary Micro Jaguar speed`
			`* controllers.`
			`* Due to the shipping firmware on the Jaguar, we can't run the update`
			`* period less`
			`* than 5.05 ms.`
			`*`
			`* kDefaultPwmPeriod is the 1x period (5.05 ms). In hardware, the period`
			`* scaling is implemented as an`
			`* output squelch to get longer periods for old devices.`
			`*/`
			`static constexpr float kDefaultPwmPeriod = 5.05;`
			`/**`
			`* kDefaultPwmCenter is the PWM range center in ms`
			`*/`
			`static constexpr float kDefaultPwmCenter = 1.5;`
			`/**`
			`* kDefaultPWMStepsDown is the number of PWM steps below the centerpoint`
			`*/`
			`static const int32_t kDefaultPwmStepsDown = 1000;`
			`static const int32_t kPwmDisabled = 0;`

			`virtual void SetPosition(float pos);`
			`virtual float GetPosition() const;`
			`virtual void SetSpeed(float speed);`
			`virtual float GetSpeed() const;`

			`bool m_eliminateDeadband;`
			`int32_t m_maxPwm;`
			`int32_t m_deadbandMaxPwm;`
			`int32_t m_centerPwm;`
			`int32_t m_deadbandMinPwm;`
			`int32_t m_minPwm;`

			`void ValueChanged(ITable* source, llvm::StringRef key,`
			`std::shared_ptr<nt::Value> value, bool isNew) override;`
			`void UpdateTable() override;`
			`void StartLiveWindowMode() override;`
			`void StopLiveWindowMode() override;`
			`std::string GetSmartDashboardType() const override;`
			`void InitTable(std::shared_ptr<ITable> subTable) override;`
			`std::shared_ptr<ITable> GetTable() const override;`

			`std::shared_ptr<ITable> m_table;`

			`private:`
			`uint32_t m_channel;`
			`int32_t GetMaxPositivePwm() const { return m_maxPwm; }`
			`int32_t GetMinPositivePwm() const {`
			`return m_eliminateDeadband ? m_deadbandMaxPwm : m_centerPwm + 1;`
			`}`
			`int32_t GetCenterPwm() const { return m_centerPwm; }`
			`int32_t GetMaxNegativePwm() const {`
			`return m_eliminateDeadband ? m_deadbandMinPwm : m_centerPwm - 1;`
			`}`
			`int32_t GetMinNegativePwm() const { return m_minPwm; }`
			`int32_t GetPositiveScaleFactor() const {`
			`return GetMaxPositivePwm() - GetMinPositivePwm();`
			`} ///< The scale for positive speeds.`
			`int32_t GetNegativeScaleFactor() const {`
			`return GetMaxNegativePwm() - GetMinNegativePwm();`
			`} ///< The scale for negative speeds.`
			`int32_t GetFullRangeScaleFactor() const {`
			`return GetMaxPositivePwm() - GetMinNegativePwm();`
			`} ///< The scale for positions.`
			`};`