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FRC2016-old/Robot2016/wpilib/cpp/current/include/CANTalon.h

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/*----------------------------------------------------------------------------*/
/* Copyright (c) FIRST 2014-2016. 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 "SafePWM.h"
#include "CANSpeedController.h"
#include "PIDOutput.h"
#include "PIDSource.h"
#include "PIDInterface.h"
#include "HAL/CanTalonSRX.h"
#include "MotorSafetyHelper.h"
#include "LiveWindow/LiveWindowSendable.h"
#include "tables/ITable.h"
#include <memory>
/**
* CTRE Talon SRX Speed Controller with CAN Control
*/
class CANTalon : public MotorSafety,
public CANSpeedController,
public ErrorBase,
public LiveWindowSendable,
public ITableListener,
public PIDSource,
public PIDInterface {
public:
enum FeedbackDevice {
QuadEncoder = 0,
AnalogPot = 2,
AnalogEncoder = 3,
EncRising = 4,
EncFalling = 5,
CtreMagEncoder_Relative = 6, //!< Cross The Road Electronics Magnetic Encoder in Absolute/PulseWidth Mode
CtreMagEncoder_Absolute = 7, //!< Cross The Road Electronics Magnetic Encoder in Relative/Quadrature Mode
PulseWidth = 8,
};
/**
* Depending on the sensor type, Talon can determine if sensor is plugged in ot not.
*/
enum FeedbackDeviceStatus {
FeedbackStatusUnknown = 0, //!< Sensor status could not be determined. Not all sensors can do this.
FeedbackStatusPresent = 1, //!< Sensor is present and working okay.
FeedbackStatusNotPresent = 2, //!< Sensor is not present, not plugged in, not powered, etc...
};
enum StatusFrameRate {
StatusFrameRateGeneral = 0,
StatusFrameRateFeedback = 1,
StatusFrameRateQuadEncoder = 2,
StatusFrameRateAnalogTempVbat = 3,
StatusFrameRatePulseWidthMeas = 4,
};
/**
* Enumerated types for Motion Control Set Values.
* When in Motion Profile control mode, these constants are paseed
* into set() to manipulate the motion profile executer.
* When changing modes, be sure to read the value back using getMotionProfileStatus()
* to ensure changes in output take effect before performing buffering actions.
* Disable will signal Talon to put motor output into neutral drive.
* Talon will stop processing motion profile points. This means the buffer is
* effectively disconnected from the executer, allowing the robot to gracefully
* clear and push new traj points. isUnderrun will get cleared.
* The active trajectory is also cleared.
* Enable will signal Talon to pop a trajectory point from it's buffer and process it.
* If the active trajectory is empty, Talon will shift in the next point.
* If the active traj is empty, and so is the buffer, the motor drive is neutral and
* isUnderrun is set. When active traj times out, and buffer has at least one point,
* Talon shifts in next one, and isUnderrun is cleared. When active traj times out,
* and buffer is empty, Talon keeps processing active traj and sets IsUnderrun.
* Hold will signal Talon keep processing the active trajectory indefinitely.
* If the active traj is cleared, Talon will neutral motor drive. Otherwise
* Talon will keep processing the active traj but it will not shift in
* points from the buffer. This means the buffer is effectively disconnected
* from the executer, allowing the robot to gracefully clear and push
* new traj points.
* isUnderrun is set if active traj is empty, otherwise it is cleared.
* isLast signal is also cleared.
*
* Typical workflow:
* set(Disable),
* Confirm Disable takes effect,
* clear buffer and push buffer points,
* set(Enable) when enough points have been pushed to ensure no underruns,
* wait for MP to finish or decide abort,
* If MP finished gracefully set(Hold) to hold position servo and disconnect buffer,
* If MP is being aborted set(Disable) to neutral the motor and disconnect buffer,
* Confirm mode takes effect,
* clear buffer and push buffer points, and rinse-repeat.
*/
enum SetValueMotionProfile {
SetValueMotionProfileDisable = 0,
SetValueMotionProfileEnable = 1,
SetValueMotionProfileHold = 2,
};
/**
* Motion Profile Trajectory Point
* This is simply a data transer object.
*/
struct TrajectoryPoint {
double position; //!< The position to servo to.
double velocity; //!< The velocity to feed-forward.
/**
* Time in milliseconds to process this point.
* Value should be between 1ms and 255ms. If value is zero
* then Talon will default to 1ms. If value exceeds 255ms API will cap it.
*/
unsigned int timeDurMs;
/**
* Which slot to get PIDF gains.
* PID is used for position servo.
* F is used as the Kv constant for velocity feed-forward.
* Typically this is hardcoded to the a particular slot, but you are free
* gain schedule if need be.
*/
unsigned int profileSlotSelect;
/**
* Set to true to only perform the velocity feed-forward and not perform
* position servo. This is useful when learning how the position servo
* changes the motor response. The same could be accomplish by clearing the
* PID gains, however this is synchronous the streaming, and doesn't require restoing
* gains when finished.
*
* Additionaly setting this basically gives you direct control of the motor output
* since motor output = targetVelocity X Kv, where Kv is our Fgain.
* This means you can also scheduling straight-throttle curves without relying on
* a sensor.
*/
bool velocityOnly;
/**
* Set to true to signal Talon that this is the final point, so do not
* attempt to pop another trajectory point from out of the Talon buffer.
* Instead continue processing this way point. Typically the velocity
* member variable should be zero so that the motor doesn't spin indefinitely.
*/
bool isLastPoint;
/**
* Set to true to signal Talon to zero the selected sensor.
* When generating MPs, one simple method is to make the first target position zero,
* and the final target position the target distance from the current position.
* Then when you fire the MP, the current position gets set to zero.
* If this is the intent, you can set zeroPos on the first trajectory point.
*
* Otherwise you can leave this false for all points, and offset the positions
* of all trajectory points so they are correct.
*/
bool zeroPos;
};
/**
* Motion Profile Status
* This is simply a data transer object.
*/
struct MotionProfileStatus {
/**
* The available empty slots in the trajectory buffer.
*
* The robot API holds a "top buffer" of trajectory points, so your applicaion
* can dump several points at once. The API will then stream them into the Talon's
* low-level buffer, allowing the Talon to act on them.
*/
unsigned int topBufferRem;
/**
* The number of points in the top trajectory buffer.
*/
unsigned int topBufferCnt;
/**
* The number of points in the low level Talon buffer.
*/
unsigned int btmBufferCnt;
/**
* Set if isUnderrun ever gets set.
* Only is cleared by clearMotionProfileHasUnderrun() to ensure
* robot logic can react or instrument it.
* @see clearMotionProfileHasUnderrun()
*/
bool hasUnderrun;
/**
* This is set if Talon needs to shift a point from its buffer into
* the active trajectory point however the buffer is empty. This gets cleared
* automatically when is resolved.
*/
bool isUnderrun;
/**
* True if the active trajectory point has not empty, false otherwise.
* The members in activePoint are only valid if this signal is set.
*/
bool activePointValid;
/**
* The number of points in the low level Talon buffer.
*/
TrajectoryPoint activePoint;
/**
* The current output mode of the motion profile executer (disabled, enabled, or hold).
* When changing the set() value in MP mode, it's important to check this signal to
* confirm the change takes effect before interacting with the top buffer.
*/
SetValueMotionProfile outputEnable;
};
explicit CANTalon(int deviceNumber);
explicit CANTalon(int deviceNumber, int controlPeriodMs);
DEFAULT_MOVE_CONSTRUCTOR(CANTalon);
virtual ~CANTalon();
// PIDOutput interface
virtual void PIDWrite(float output) override;
// PIDSource interface
virtual double PIDGet() override;
// MotorSafety interface
virtual void SetExpiration(float timeout) override;
virtual float GetExpiration() const override;
virtual bool IsAlive() const override;
virtual void StopMotor() override;
virtual void SetSafetyEnabled(bool enabled) override;
virtual bool IsSafetyEnabled() const override;
virtual void GetDescription(std::ostringstream& desc) const override;
// CANSpeedController interface
virtual float Get() const override;
virtual void Set(float value, uint8_t syncGroup = 0) override;
virtual void Reset() override;
virtual void SetSetpoint(float value) override;
virtual void Disable() override;
virtual void EnableControl();
virtual void Enable() override;
virtual void SetP(double p) override;
virtual void SetI(double i) override;
virtual void SetD(double d) override;
void SetF(double f);
void SetIzone(unsigned iz);
virtual void SetPID(double p, double i, double d) override;
virtual void SetPID(double p, double i, double d, double f);
virtual double GetP() const override;
virtual double GetI() const override;
virtual double GetD() const override;
virtual double GetF() const;
virtual bool IsModePID(CANSpeedController::ControlMode mode) const override;
virtual float GetBusVoltage() const override;
virtual float GetOutputVoltage() const override;
virtual float GetOutputCurrent() const override;
virtual float GetTemperature() const override;
void SetPosition(double pos);
virtual double GetPosition() const override;
virtual double GetSpeed() const override;
virtual int GetClosedLoopError() const;
virtual void SetAllowableClosedLoopErr(uint32_t allowableCloseLoopError);
virtual int GetAnalogIn() const;
virtual void SetAnalogPosition(int newPosition);
virtual int GetAnalogInRaw() const;
virtual int GetAnalogInVel() const;
virtual int GetEncPosition() const;
virtual void SetEncPosition(int);
virtual int GetEncVel() const;
int GetPinStateQuadA() const;
int GetPinStateQuadB() const;
int GetPinStateQuadIdx() const;
int IsFwdLimitSwitchClosed() const;
int IsRevLimitSwitchClosed() const;
int GetNumberOfQuadIdxRises() const;
void SetNumberOfQuadIdxRises(int rises);
virtual int GetPulseWidthPosition() const;
virtual void SetPulseWidthPosition(int newpos);
virtual int GetPulseWidthVelocity() const;
virtual int GetPulseWidthRiseToFallUs() const;
virtual int GetPulseWidthRiseToRiseUs() const;
virtual FeedbackDeviceStatus IsSensorPresent(FeedbackDevice feedbackDevice)const;
virtual bool GetForwardLimitOK() const override;
virtual bool GetReverseLimitOK() const override;
virtual uint16_t GetFaults() const override;
uint16_t GetStickyFaults() const;
void ClearStickyFaults();
virtual void SetVoltageRampRate(double rampRate) override;
virtual void SetVoltageCompensationRampRate(double rampRate);
virtual uint32_t GetFirmwareVersion() const override;
virtual void ConfigNeutralMode(NeutralMode mode) override;
virtual void ConfigEncoderCodesPerRev(uint16_t codesPerRev) override;
virtual void ConfigPotentiometerTurns(uint16_t turns) override;
virtual void ConfigSoftPositionLimits(double forwardLimitPosition,
double reverseLimitPosition) override;
virtual void DisableSoftPositionLimits() override;
virtual void ConfigLimitMode(LimitMode mode) override;
virtual void ConfigForwardLimit(double forwardLimitPosition) override;
virtual void ConfigReverseLimit(double reverseLimitPosition) override;
/**
* Change the fwd limit switch setting to normally open or closed.
* Talon will disable momentarilly if the Talon's current setting
* is dissimilar to the caller's requested setting.
*
* Since Talon saves setting to flash this should only affect
* a given Talon initially during robot install.
*
* @param normallyOpen true for normally open. false for normally closed.
*/
void ConfigFwdLimitSwitchNormallyOpen(bool normallyOpen);
/**
* Change the rev limit switch setting to normally open or closed.
* Talon will disable momentarilly if the Talon's current setting
* is dissimilar to the caller's requested setting.
*
* Since Talon saves setting to flash this should only affect
* a given Talon initially during robot install.
*
* @param normallyOpen true for normally open. false for normally closed.
*/
void ConfigRevLimitSwitchNormallyOpen(bool normallyOpen);
virtual void ConfigMaxOutputVoltage(double voltage) override;
void ConfigPeakOutputVoltage(double forwardVoltage,double reverseVoltage);
void ConfigNominalOutputVoltage(double forwardVoltage,double reverseVoltage);
/**
* Enables Talon SRX to automatically zero the Sensor Position whenever an
* edge is detected on the index signal.
* @param enable boolean input, pass true to enable feature or false to disable.
* @param risingEdge boolean input, pass true to clear the position on rising edge,
* pass false to clear the position on falling edge.
*/
void EnableZeroSensorPositionOnIndex(bool enable, bool risingEdge);
void ConfigSetParameter(uint32_t paramEnum, double value);
bool GetParameter(uint32_t paramEnum, double & dvalue) const;
virtual void ConfigFaultTime(float faultTime) override;
virtual void SetControlMode(ControlMode mode);
void SetFeedbackDevice(FeedbackDevice device);
void SetStatusFrameRateMs(StatusFrameRate stateFrame, int periodMs);
virtual ControlMode GetControlMode() const;
void SetSensorDirection(bool reverseSensor);
void SetClosedLoopOutputDirection(bool reverseOutput);
void SetCloseLoopRampRate(double rampRate);
void SelectProfileSlot(int slotIdx);
int GetIzone() const;
int GetIaccum() const;
void ClearIaccum();
int GetBrakeEnableDuringNeutral() const;
bool IsControlEnabled() const;
bool IsEnabled() const override;
double GetSetpoint() const override;
/**
* Calling application can opt to speed up the handshaking between the robot API and the Talon to increase the
* download rate of the Talon's Motion Profile. Ideally the period should be no more than half the period
* of a trajectory point.
*/
void ChangeMotionControlFramePeriod(int periodMs);
/**
* Clear the buffered motion profile in both Talon RAM (bottom), and in the API (top).
* Be sure to check GetMotionProfileStatus() to know when the buffer is actually cleared.
*/
void ClearMotionProfileTrajectories();
/**
* Retrieve just the buffer count for the api-level (top) buffer.
* This routine performs no CAN or data structure lookups, so its fast and ideal
* if caller needs to quickly poll the progress of trajectory points being emptied
* into Talon's RAM. Otherwise just use GetMotionProfileStatus.
* @return number of trajectory points in the top buffer.
*/
int GetMotionProfileTopLevelBufferCount();
/**
* Push another trajectory point into the top level buffer (which is emptied into
* the Talon's bottom buffer as room allows).
* @param trajPt the trajectory point to insert into buffer.
* @return true if trajectory point push ok. CTR_BufferFull if buffer is full
* due to kMotionProfileTopBufferCapacity.
*/
bool PushMotionProfileTrajectory(const TrajectoryPoint & trajPt);
/**
* @return true if api-level (top) buffer is full.
*/
bool IsMotionProfileTopLevelBufferFull();
/**
* This must be called periodically to funnel the trajectory points from the API's top level buffer to
* the Talon's bottom level buffer. Recommendation is to call this twice as fast as the executation rate of the motion profile.
* So if MP is running with 20ms trajectory points, try calling this routine every 10ms. All motion profile functions are thread-safe
* through the use of a mutex, so there is no harm in having the caller utilize threading.
*/
void ProcessMotionProfileBuffer();
/**
* Retrieve all status information.
* Since this all comes from one CAN frame, its ideal to have one routine to retrieve the frame once and decode everything.
* @param [out] motionProfileStatus contains all progress information on the currently running MP.
*/
void GetMotionProfileStatus(MotionProfileStatus & motionProfileStatus);
/**
* Clear the hasUnderrun flag in Talon's Motion Profile Executer when MPE is ready for another point,
* but the low level buffer is empty.
*
* Once the Motion Profile Executer sets the hasUnderrun flag, it stays set until
* Robot Application clears it with this routine, which ensures Robot Application
* gets a chance to instrument or react. Caller could also check the isUnderrun flag
* which automatically clears when fault condition is removed.
*/
void ClearMotionProfileHasUnderrun();
// LiveWindow stuff.
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;
// SpeedController overrides
virtual void SetInverted(bool isInverted) override;
virtual bool GetInverted() const override;
private:
// Values for various modes as is sent in the CAN packets for the Talon.
enum TalonControlMode {
kThrottle = 0,
kFollowerMode = 5,
kVoltageMode = 4,
kPositionMode = 1,
kSpeedMode = 2,
kCurrentMode = 3,
kMotionProfileMode = 6,
kDisabled = 15
};
int m_deviceNumber;
std::unique_ptr<CanTalonSRX> m_impl;
std::unique_ptr<MotorSafetyHelper> m_safetyHelper;
int m_profile = 0; // Profile from CANTalon to use. Set to zero until we can
// actually test this.
bool m_controlEnabled = true;
ControlMode m_controlMode = kPercentVbus;
TalonControlMode m_sendMode;
double m_setPoint = 0;
/**
* Encoder CPR, counts per rotations, also called codes per revoluion.
* Default value of zero means the API behaves as it did during the 2015 season, each position
* unit is a single pulse and there are four pulses per count (4X).
* Caller can use ConfigEncoderCodesPerRev to set the quadrature encoder CPR.
*/
uint32_t m_codesPerRev = 0;
/**
* Number of turns per rotation. For example, a 10-turn pot spins ten full rotations from
* a wiper voltage of zero to 3.3 volts. Therefore knowing the
* number of turns a full voltage sweep represents is necessary for calculating rotations
* and velocity.
* A default value of zero means the API behaves as it did during the 2015 season, there are 1024
* position units from zero to 3.3V.
*/
uint32_t m_numPotTurns = 0;
/**
* Although the Talon handles feedback selection, caching the feedback selection is helpful at the API level
* for scaling into rotations and RPM.
*/
FeedbackDevice m_feedbackDevice = QuadEncoder;
static const unsigned int kDelayForSolicitedSignalsUs = 4000;
/**
* @param devToLookup FeedbackDevice to lookup the scalar for. Because Talon
* allows multiple sensors to be attached simultaneously, caller must
* specify which sensor to lookup.
* @return The number of native Talon units per rotation of the selected sensor.
* Zero if the necessary sensor information is not available.
* @see ConfigEncoderCodesPerRev
* @see ConfigPotentiometerTurns
*/
double GetNativeUnitsPerRotationScalar(FeedbackDevice devToLookup)const;
/**
* Fixup the sendMode so Set() serializes the correct demand value.
* Also fills the modeSelecet in the control frame to disabled.
* @param mode Control mode to ultimately enter once user calls Set().
* @see Set()
*/
void ApplyControlMode(CANSpeedController::ControlMode mode);
/**
* @param fullRotations double precision value representing number of rotations of selected feedback sensor.
* If user has never called the config routine for the selected sensor, then the caller
* is likely passing rotations in engineering units already, in which case it is returned
* as is.
* @see ConfigPotentiometerTurns
* @see ConfigEncoderCodesPerRev
* @return fullRotations in native engineering units of the Talon SRX firmware.
*/
int32_t ScaleRotationsToNativeUnits(FeedbackDevice devToLookup, double fullRotations) const;
/**
* @param rpm double precision value representing number of rotations per minute of selected feedback sensor.
* If user has never called the config routine for the selected sensor, then the caller
* is likely passing rotations in engineering units already, in which case it is returned
* as is.
* @see ConfigPotentiometerTurns
* @see ConfigEncoderCodesPerRev
* @return sensor velocity in native engineering units of the Talon SRX firmware.
*/
int32_t ScaleVelocityToNativeUnits(FeedbackDevice devToLookup, double rpm) const;
/**
* @param nativePos integral position of the feedback sensor in native Talon SRX units.
* If user has never called the config routine for the selected sensor, then the return
* will be in TALON SRX units as well to match the behavior in the 2015 season.
* @see ConfigPotentiometerTurns
* @see ConfigEncoderCodesPerRev
* @return double precision number of rotations, unless config was never performed.
*/
double ScaleNativeUnitsToRotations(FeedbackDevice devToLookup, int32_t nativePos) const;
/**
* @param nativeVel integral velocity of the feedback sensor in native Talon SRX units.
* If user has never called the config routine for the selected sensor, then the return
* will be in TALON SRX units as well to match the behavior in the 2015 season.
* @see ConfigPotentiometerTurns
* @see ConfigEncoderCodesPerRev
* @return double precision of sensor velocity in RPM, unless config was never performed.
*/
double ScaleNativeUnitsToRpm(FeedbackDevice devToLookup, int32_t nativeVel) const;
// LiveWindow stuff.
std::shared_ptr<ITable> m_table;
bool m_isInverted;
HasBeenMoved m_hasBeenMoved;
};