wpilibc/simulation/include/RobotDrive.h - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* Copyright (c) FIRST 2008. 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 $(WIND_BASE)/WPILib.  */
 /*----------------------------------------------------------------------------*/
 #pragma once

 #include "ErrorBase.h"
 #include <stdlib.h>
 #include "MotorSafety.h"
 #include "MotorSafetyHelper.h"

 class SpeedController;
 class GenericHID;

 /**
  * Utility class for handling Robot drive based on a definition of the motor configuration.
  * The robot drive class handles basic driving for a robot. Currently, 2 and 4 motor standard
  * drive trains are supported. In the future other drive types like swerve and meccanum might
  * be implemented. Motor channel numbers are passed supplied on creation of the class. Those are
  * used for either the Drive function (intended for hand created drive code, such as autonomous)
  * or with the Tank/Arcade functions intended to be used for Operator Control driving.
  */
 class RobotDrive : public MotorSafety, public ErrorBase
 {
 public:
 	enum MotorType
 	{
 		kFrontLeftMotor = 0,
 		kFrontRightMotor = 1,
 		kRearLeftMotor = 2,
 		kRearRightMotor = 3
 	};

 	RobotDrive(uint32_t leftMotorChannel, uint32_t rightMotorChannel);
 	RobotDrive(uint32_t frontLeftMotorChannel, uint32_t rearLeftMotorChannel,
 			uint32_t frontRightMotorChannel, uint32_t rearRightMotorChannel);
 	RobotDrive(SpeedController *leftMotor, SpeedController *rightMotor);
 	RobotDrive(SpeedController &leftMotor, SpeedController &rightMotor);
 	RobotDrive(SpeedController *frontLeftMotor, SpeedController *rearLeftMotor,
 			SpeedController *frontRightMotor, SpeedController *rearRightMotor);
 	RobotDrive(SpeedController &frontLeftMotor, SpeedController &rearLeftMotor,
 			SpeedController &frontRightMotor, SpeedController &rearRightMotor);
 	virtual ~RobotDrive();

     RobotDrive(const RobotDrive&) = delete;
     RobotDrive& operator=(const RobotDrive&) = delete;

 	void Drive(float outputMagnitude, float curve);
 	void TankDrive(GenericHID *leftStick, GenericHID *rightStick, bool squaredInputs = true);
 	void TankDrive(GenericHID &leftStick, GenericHID &rightStick, bool squaredInputs = true);
 	void TankDrive(GenericHID *leftStick, uint32_t leftAxis, GenericHID *rightStick,
 			uint32_t rightAxis, bool squaredInputs = true);
 	void TankDrive(GenericHID &leftStick, uint32_t leftAxis, GenericHID &rightStick,
 			uint32_t rightAxis, bool squaredInputs = true);
 	void TankDrive(float leftValue, float rightValue, bool squaredInputs = true);
 	void ArcadeDrive(GenericHID *stick, bool squaredInputs = true);
 	void ArcadeDrive(GenericHID &stick, bool squaredInputs = true);
 	void ArcadeDrive(GenericHID *moveStick, uint32_t moveChannel, GenericHID *rotateStick,
 			uint32_t rotateChannel, bool squaredInputs = true);
 	void ArcadeDrive(GenericHID &moveStick, uint32_t moveChannel, GenericHID &rotateStick,
 			uint32_t rotateChannel, bool squaredInputs = true);
 	void ArcadeDrive(float moveValue, float rotateValue, bool squaredInputs = true);
 	void MecanumDrive_Cartesian(float x, float y, float rotation, float gyroAngle = 0.0);
 	void MecanumDrive_Polar(float magnitude, float direction, float rotation);
 	void HolonomicDrive(float magnitude, float direction, float rotation);
 	virtual void SetLeftRightMotorOutputs(float leftOutput, float rightOutput);
 	void SetInvertedMotor(MotorType motor, bool isInverted);
 	void SetSensitivity(float sensitivity);
 	void SetMaxOutput(double maxOutput);

 	void SetExpiration(float timeout) override;
 	float GetExpiration() const override;
 	bool IsAlive() const override;
 	void StopMotor() override;
 	bool IsSafetyEnabled() const override;
 	void SetSafetyEnabled(bool enabled) override;
 	void GetDescription(std::ostringstream& desc) const override;

 protected:
 	void InitRobotDrive();
 	float Limit(float num);
 	void Normalize(double *wheelSpeeds);
 	void RotateVector(double &x, double &y, double angle);

 	static const int32_t kMaxNumberOfMotors = 4;

 	int32_t m_invertedMotors[kMaxNumberOfMotors];
 	float m_sensitivity = 0.5;
 	double m_maxOutput = 1.0;
 	bool m_deleteSpeedControllers;
 	SpeedController *m_frontLeftMotor = nullptr;
 	SpeedController *m_frontRightMotor = nullptr;
 	SpeedController *m_rearLeftMotor = nullptr;
 	SpeedController *m_rearRightMotor = nullptr;
 	// FIXME: MotorSafetyHelper *m_safetyHelper;

 private:
 	int32_t GetNumMotors()
 	{
 		int motors = 0;
 		if (m_frontLeftMotor)
 			motors++;
 		if (m_frontRightMotor)
 			motors++;
 		if (m_rearLeftMotor)
 			motors++;
 		if (m_rearRightMotor)
 			motors++;
 		return motors;
 	}
 };
	/----------------------------------------------------------------------------/
	/* Copyright (c) FIRST 2008. 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 $(WIND_BASE)/WPILib. */
	/----------------------------------------------------------------------------/
	#pragma once

	#include "ErrorBase.h"
	#include <stdlib.h>
	#include "MotorSafety.h"
	#include "MotorSafetyHelper.h"

	class SpeedController;
	class GenericHID;

	/**
	* Utility class for handling Robot drive based on a definition of the motor configuration.
	* The robot drive class handles basic driving for a robot. Currently, 2 and 4 motor standard
	* drive trains are supported. In the future other drive types like swerve and meccanum might
	* be implemented. Motor channel numbers are passed supplied on creation of the class. Those are
	* used for either the Drive function (intended for hand created drive code, such as autonomous)
	* or with the Tank/Arcade functions intended to be used for Operator Control driving.
	*/
	class RobotDrive : public MotorSafety, public ErrorBase
	{
	public:
	enum MotorType
	{
	kFrontLeftMotor = 0,
	kFrontRightMotor = 1,
	kRearLeftMotor = 2,
	kRearRightMotor = 3
	};

	RobotDrive(uint32_t leftMotorChannel, uint32_t rightMotorChannel);
	RobotDrive(uint32_t frontLeftMotorChannel, uint32_t rearLeftMotorChannel,
	uint32_t frontRightMotorChannel, uint32_t rearRightMotorChannel);
	RobotDrive(SpeedController leftMotor, SpeedController rightMotor);
	RobotDrive(SpeedController &leftMotor, SpeedController &rightMotor);
	RobotDrive(SpeedController frontLeftMotor, SpeedController rearLeftMotor,
	SpeedController frontRightMotor, SpeedController rearRightMotor);
	RobotDrive(SpeedController &frontLeftMotor, SpeedController &rearLeftMotor,
	SpeedController &frontRightMotor, SpeedController &rearRightMotor);
	virtual ~RobotDrive();

	RobotDrive(const RobotDrive&) = delete;
	RobotDrive& operator=(const RobotDrive&) = delete;

	void Drive(float outputMagnitude, float curve);
	void TankDrive(GenericHID leftStick, GenericHID rightStick, bool squaredInputs = true);
	void TankDrive(GenericHID &leftStick, GenericHID &rightStick, bool squaredInputs = true);
	void TankDrive(GenericHID leftStick, uint32_t leftAxis, GenericHID rightStick,
	uint32_t rightAxis, bool squaredInputs = true);
	void TankDrive(GenericHID &leftStick, uint32_t leftAxis, GenericHID &rightStick,
	uint32_t rightAxis, bool squaredInputs = true);
	void TankDrive(float leftValue, float rightValue, bool squaredInputs = true);
	void ArcadeDrive(GenericHID *stick, bool squaredInputs = true);
	void ArcadeDrive(GenericHID &stick, bool squaredInputs = true);
	void ArcadeDrive(GenericHID moveStick, uint32_t moveChannel, GenericHID rotateStick,
	uint32_t rotateChannel, bool squaredInputs = true);
	void ArcadeDrive(GenericHID &moveStick, uint32_t moveChannel, GenericHID &rotateStick,
	uint32_t rotateChannel, bool squaredInputs = true);
	void ArcadeDrive(float moveValue, float rotateValue, bool squaredInputs = true);
	void MecanumDrive_Cartesian(float x, float y, float rotation, float gyroAngle = 0.0);
	void MecanumDrive_Polar(float magnitude, float direction, float rotation);
	void HolonomicDrive(float magnitude, float direction, float rotation);
	virtual void SetLeftRightMotorOutputs(float leftOutput, float rightOutput);
	void SetInvertedMotor(MotorType motor, bool isInverted);
	void SetSensitivity(float sensitivity);
	void SetMaxOutput(double maxOutput);

	void SetExpiration(float timeout) override;
	float GetExpiration() const override;
	bool IsAlive() const override;
	void StopMotor() override;
	bool IsSafetyEnabled() const override;
	void SetSafetyEnabled(bool enabled) override;
	void GetDescription(std::ostringstream& desc) const override;

	protected:
	void InitRobotDrive();
	float Limit(float num);
	void Normalize(double *wheelSpeeds);
	void RotateVector(double &x, double &y, double angle);

	static const int32_t kMaxNumberOfMotors = 4;

	int32_t m_invertedMotors[kMaxNumberOfMotors];
	float m_sensitivity = 0.5;
	double m_maxOutput = 1.0;
	bool m_deleteSpeedControllers;
	SpeedController *m_frontLeftMotor = nullptr;
	SpeedController *m_frontRightMotor = nullptr;
	SpeedController *m_rearLeftMotor = nullptr;
	SpeedController *m_rearRightMotor = nullptr;
	// FIXME: MotorSafetyHelper *m_safetyHelper;

	private:
	int32_t GetNumMotors()
	{
	int motors = 0;
	if (m_frontLeftMotor)
	motors++;
	if (m_frontRightMotor)
	motors++;
	if (m_rearLeftMotor)
	motors++;
	if (m_rearRightMotor)
	motors++;
	return motors;
	}
	};