Marlin_FB4S/Marlin/src/HAL/STM32_F4_F7/STM32F7/TMC2660.h

/**
 * TMC26XStepper.h - - TMC26X Stepper library for Wiring/Arduino
 *
 * based on the stepper library by Tom Igoe, et. al.
 *
 * Copyright (c) 2011, Interactive Matter, Marcus Nowotny
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in
 * all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 * THE SOFTWARE.
 */
#pragma once

#include <stdint.h>

//! return value for TMC26XStepper.getOverTemperature() if there is a overtemperature situation in the TMC chip
/*!
 * This warning indicates that the TMC chip is too warm.
 * It is still working but some parameters may be inferior.
 * You should do something against it.
 */
#define TMC26X_OVERTEMPERATURE_PREWARING 1
//! return value for TMC26XStepper.getOverTemperature() if there is a overtemperature shutdown in the TMC chip
/*!
 * This warning indicates that the TMC chip is too warm to operate and has shut down to prevent damage.
 * It will stop working until it cools down again.
 * If you encouter this situation you must do something against it. Like reducing the current or improving the PCB layout
 * and/or heat management.
 */
#define TMC26X_OVERTEMPERATURE_SHUTDOWN 2

//which values can be read out
/*!
 * Selects to readout the microstep position from the motor.
 *\sa readStatus()
 */
#define TMC26X_READOUT_POSITION 0
/*!
 * Selects to read out the StallGuard value of the motor.
 *\sa readStatus()
 */
#define TMC26X_READOUT_STALLGUARD 1
/*!
 * Selects to read out the current current setting (acc. to CoolStep) and the upper bits of the StallGuard value from the motor.
 *\sa readStatus(), setCurrent()
 */
#define TMC26X_READOUT_CURRENT 3

/*!
 * Define to set the minimum current for CoolStep operation to 1/2 of the selected CS minium.
 *\sa setCoolStepConfiguration()
 */
#define COOL_STEP_HALF_CS_LIMIT 0
/*!
 * Define to set the minimum current for CoolStep operation to 1/4 of the selected CS minium.
 *\sa setCoolStepConfiguration()
 */
#define COOL_STEP_QUARTDER_CS_LIMIT 1

/*!
 * \class TMC26XStepper
 * \brief Class representing a TMC26X stepper driver
 *
 * To use one of these drivers in your code create an object of its class:
 * \code
 * TMC26XStepper tmc_stepper = TMC26XStepper(200,1,2,3,500);
 * \endcode
 * see TMC26XStepper(int16_t number_of_steps, int16_t cs_pin, int16_t dir_pin, int16_t step_pin, uint16_t rms_current)
 *
 * Keep in mind that you need to start the driver with start() in order to configure the TMC26X.
 *
 * The most important function is move(). It checks if the motor requires a step. It's important to call move() as
 * often as possible in loop(). I suggest using a very fast loop routine and always call move() at the beginning or end.
 *
 * To move you must set a movement speed with setSpeed(). The speed is a positive value, setting the RPM.
 *
 * To really move the motor you have to call step() to tell the driver to move the motor the given number
 * of steps in the given direction. Positive values move the motor in one direction, negative values in the other.
 *
 * You can check with isMoving() if the motor is still moving or stop it abruptly with stop().
 */
class TMC26XStepper {
  public:
    /*!
     * \brief Create a new representation of a stepper motor connected to a TMC26X stepper driver
     *
     * Main constructor. If in doubt use this. All parameters must be provided as described below.
     *
     * \param number_of_steps Number of steps the motor has per rotation.
     * \param cs_pin          Arduino pin connected to the Client Select Pin (!CS) of the TMC26X for SPI.
     * \param dir_pin         Arduino pin connected to the DIR input of the TMC26X.
     * \param step_pin        Arduino pin connected to the STEP pin of the TMC26X.
     * \param rms_current     Maximum current to provide to the motor in mA (!). A value of 200 will send up to 200mA to the motor.
     * \param resistor        Current sense resistor in milli-Ohm, defaults to 0.15 Ohm (or 150 milli-Ohm) as in the TMC260 Arduino Shield.
     *
     * You must also call TMC26XStepper.start() to configure the stepper driver for use.
     *
     * By default the Constant Off Time chopper is used. See TMC26XStepper.setConstantOffTimeChopper() for details.
     * This should work on most motors (YMMV). You may want to configure and use the Spread Cycle Chopper. See setSpreadCycleChopper().
     *
     * By default a microstepping of 1/32 is used to provide a smooth motor run while still giving a good progression per step.
     * Change stepping by sending setMicrosteps() a different value.
     * \sa start(), setMicrosteps()
     */
    TMC26XStepper(const int16_t in_steps, int16_t cs_pin, int16_t dir_pin, int16_t step_pin, uint16_t current, uint16_t resistor=100); //resistor=150

    /*!
     * \brief Configure and start the TMC26X stepper driver. Before this is called the stepper driver is nonfunctional.
     *
     * Configure the TMC26X stepper driver for the given values via SPI.
     * Most member functions are non-functional if the driver has not been started,
     * therefore it is best to call this in setup().
     */
    void start();

    /*!
     * \brief Reset the stepper in unconfigured mode.
     *
     * Allows start to be called again. It doesn't change the internal stepper
     * configuration or the desired configuration. It just marks the stepper as
     * not-yet-started. The stepper doesn't need to be reconfigured before
     * starting again, and is not reset to any factory settings.
     * It must be reset intentionally.
     * (Hint: Normally you do not need this function)
     */
    void un_start();

    /*!
     * \brief Set the rotation speed in RPM.
     * \param whatSpeed the desired speed in RPM.
     */
    void setSpeed(uint16_t whatSpeed);

    /*!
     * \brief Report the currently selected speed in RPM.
     * \sa setSpeed()
     */
    uint16_t getSpeed();

    /*!
     * \brief Set the number of microsteps in 2^i values (rounded) up to 256
     *
     * This method sets the number of microsteps per step in 2^i interval.
     * It accepts 1, 2, 4, 16, 32, 64, 128 or 256 as valid microsteps.
     * Other values will be rounded down to the next smaller value (e.g., 3 gives a microstepping of 2).
     * You can always check the current microstepping with getMicrosteps().
     */
    void setMicrosteps(const int16_t in_steps);

    /*!
     * \brief Return the effective current number of microsteps selected.
     *
     * Always returns the effective number of microsteps.
     * This may be different from the micro-steps set in setMicrosteps() since it is rounded to 2^i.
     *
     * \sa setMicrosteps()
     */
    int16_t getMicrosteps();

    /*!
     * \brief Initiate a movement with the given number of steps. Positive values move in one direction, negative in the other.
     *
     * \param number_of_steps The number of steps to move the motor.
     * \return 0 if the motor was not moving and moves now. -1 if the motor is moving and the new steps could not be set.
     *
     * If the previous movement is incomplete the function returns -1 and doesn't change the steps to move the motor.
     * If the motor does not move it returns 0.
     *
     * The movement direction is determined by the sign of the steps parameter. The motor direction in machine space
     * cannot be determined, as it depends on the construction of the motor and how it functions in the drive system.
     *
     * For safety, verify with isMoving() or even use stop() to stop the motor before giving it new step directions.
     * \sa isMoving(), getStepsLeft(), stop()
     */
    char step(int16_t number_of_steps);

    /*!
     * \brief Central movement method. Must be called as often as possible in the loop function and is very fast.
     *
     * Check if the motor still has to move and whether the wait-to-step interval has expired, and manages the
     * number of steps remaining to fulfill the current move command.
     *
     * This function is implemented to be as fast as possible, so call it as often as possible in your loop.
     * It should be invoked with as frequently and with as much regularity as possible.
     *
     * This can be called even when the motor is known not to be moving. It will simply return.
     *
     * The frequency with which this function is called determines the top stepping speed of the motor.
     * It is recommended to call this using a hardware timer to ensure regular invocation.
     * \sa step()
     */
    char move();

    /*!
     * \brief Check whether the last movement command is done.
     * \return 0 if the motor stops, -1 if the motor is moving.
     *
     * Used to determine if the motor is ready for new movements.
     *\sa step(), move()
     */
    char isMoving();

    /*!
     * \brief Get the number of steps left in the current movement.
     * \return The number of steps left in the movement. Always positive.
     */
    uint16_t getStepsLeft();

    /*!
     * \brief Stop the motor immediately.
     * \return -1 if the motor was moving and is really stoped or 0 if it was not moving at all.
     *
     * This method directly and abruptly stops the motor and may be used as an emergency stop.
     */
    char stop();

    /*!
     * \brief Set and configure the classical Constant Off Timer Chopper
     * \param constant_off_time       The off time setting controls the minimum chopper frequency. For most applications an off time within the range of 5μs to 20μs will fit. Setting this parameter to zero completely disables all driver transistors and the motor can free-wheel. 0: chopper off, 1:15: off time setting (1 will work with minimum blank time of 24 clocks)
     * \param blank_time              Comparator blank time. This duration needs to safely cover the duration of the switching event and the ringing on the sense resistor. For most low current drivers, a setting of 1 or 2 is good. For high current applications with large MOSFETs, a setting of 2 or 3 will be required. 0 (min setting) … (3) amx setting
     * \param fast_decay_time_setting Fast decay time setting. Controls the portion of fast decay for each chopper cycle. 0: slow decay only, 1…15: duration of fast decay phase
     * \param sine_wave_offset        Sine wave offset. Controls the sine wave offset. A positive offset corrects for zero crossing error. -3…-1: negative offset, 0: no offset,1…12: positive offset
     * \param use_curreent_comparator Selects usage of the current comparator for termination of the fast decay cycle. If current comparator is enabled, it terminates the fast decay cycle in case the current reaches a higher negative value than the actual positive value. (0 disable, -1 enable).
     *
     * The classic constant off time chopper uses a fixed portion of fast decay following each on phase.
     * While the duration of the on time is determined by the chopper comparator, the fast decay time needs
     * to be set by the user in a way, that the current decay is enough for the driver to be able to follow
     * the falling slope of the sine wave, and on the other hand it should not be too long, in order to minimize
     * motor current ripple and power dissipation. This best can be tuned using an oscilloscope or
     * trying out motor smoothness at different velocities. A good starting value is a fast decay time setting
     * similar to the slow decay time setting.
     * After tuning of the fast decay time, the offset should be determined, in order to have a smooth zero transition.
     * This is necessary, because the fast decay phase leads to the absolute value of the motor current being lower
     * than the target current (see figure 17). If the zero offset is too low, the motor stands still for a short
     * moment during current zero crossing, if it is set too high, it makes a larger microstep.
     * Typically, a positive offset setting is required for optimum operation.
     *
     * \sa setSpreadCycleChoper() for other alternatives.
     * \sa setRandomOffTime() for spreading the noise over a wider spectrum
     */
    void setConstantOffTimeChopper(char constant_off_time, char blank_time, char fast_decay_time_setting, char sine_wave_offset, uint8_t use_current_comparator);

    /*!
     * \brief Sets and configures with spread cycle chopper.
     * \param constant_off_time The off time setting controls the minimum chopper frequency. For most applications an off time within the range of 5μs to 20μs will fit. Setting this parameter to zero completely disables all driver transistors and the motor can free-wheel. 0: chopper off, 1:15: off time setting (1 will work with minimum blank time of 24 clocks)
     * \param blank_time Selects the comparator blank time. This time needs to safely cover the switching event and the duration of the ringing on the sense resistor. For most low current drivers, a setting of 1 or 2 is good. For high current applications with large MOSFETs, a setting of 2 or 3 will be required. 0 (min setting) … (3) amx setting
     * \param hysteresis_start Hysteresis start setting. Please remark, that this value is an offset to the hysteresis end value. 1 … 8
     * \param hysteresis_end Hysteresis end setting. Sets the hysteresis end value after a number of decrements. Decrement interval time is controlled by hysteresis_decrement. The sum hysteresis_start + hysteresis_end must be <16. At a current setting CS of max. 30 (amplitude reduced to 240), the sum is not limited.
     * \param hysteresis_decrement Hysteresis decrement setting. This setting determines the slope of the hysteresis during on time and during fast decay time. 0 (fast decrement) … 3 (slow decrement).
     *
     * The spreadCycle chopper scheme (pat.fil.) is a precise and simple to use chopper principle, which automatically determines
     * the optimum fast decay portion for the motor. Anyhow, a number of settings can be made in order to optimally fit the driver
     * to the motor.
     * Each chopper cycle is comprised of an on-phase, a slow decay phase, a fast decay phase and a second slow decay phase.
     * The slow decay phases limit the maximum chopper frequency and are important for low motor and driver power dissipation.
     * The hysteresis start setting limits the chopper frequency by forcing the driver to introduce a minimum amount of
     * current ripple into the motor coils. The motor inductivity determines the ability to follow a changing motor current.
     * The duration of the on- and fast decay phase needs to cover at least the blank time, because the current comparator is
     * disabled during this time.
     *
     * \sa setRandomOffTime() for spreading the noise over a wider spectrum
     */
    void setSpreadCycleChopper(char constant_off_time, char blank_time, char hysteresis_start, char hysteresis_end, char hysteresis_decrement);

    /*!
     * \brief Use random off time for noise reduction (0 for off, -1 for on).
     * \param value 0 for off, -1 for on
     *
     * In a constant off time chopper scheme both coil choppers run freely, i.e. are not synchronized.
     * The frequency of each chopper mainly depends on the coil current and the position dependant motor coil inductivity,
     * thus it depends on the microstep position. With some motors a slightly audible beat can occur between the chopper
     * frequencies, especially when they are near to each other. This typically occurs at a few microstep positions within
     * each quarter wave.
     * This effect normally is not audible when compared to mechanical noise generated by ball bearings,
     * etc. Further factors which can cause a similar effect are a poor layout of sense resistor GND connection.
     * In order to minimize the effect of a beat between both chopper frequencies, an internal random generator is provided.
     * It modulates the slow decay time setting when switched on. The random off time feature further spreads the chopper spectrum,
     * reducing electromagnetic emission on single frequencies.
     */
    void setRandomOffTime(char value);

    /*!
     * \brief set the maximum motor current in mA (1000 is 1 Amp)
     * Keep in mind this is the maximum peak Current. The RMS current will be 1/sqrt(2) smaller. The actual current can also be smaller
     * by employing CoolStep.
     * \param current the maximum motor current in mA
     * \sa getCurrent(), getCurrentCurrent()
     */
    void setCurrent(uint16_t current);

    /*!
     * \brief readout the motor maximum current in mA (1000 is an Amp)
     * This is the maximum current. to get the current current - which may be affected by CoolStep us getCurrentCurrent()
     * \return the maximum motor current in milli amps
     * \sa getCurrentCurrent()
     */
    uint16_t getCurrent();

    /*!
     * \brief set the StallGuard threshold in order to get sensible StallGuard readings.
     * \param stallguard_threshold -64 … 63 the StallGuard threshold
     * \param stallguard_filter_enabled 0 if the filter is disabled, -1 if it is enabled
     *
     * The StallGuard threshold is used to optimize the StallGuard reading to sensible values. It should be at 0 at
     * the maximum allowable load on the otor (but not before). = is a good starting point (and the default)
     * If you get Stall Gaurd readings of 0 without any load or with too little laod increase the value.
     * If you get readings of 1023 even with load decrease the setting.
     *
     * If you switch on the filter the StallGuard reading is only updated each 4th full step to reduce the noise in the
     * reading.
     *
     * \sa getCurrentStallGuardReading() to read out the current value.
     */
    void setStallGuardThreshold(char stallguard_threshold, char stallguard_filter_enabled);

    /*!
     * \brief reads out the StallGuard threshold
     * \return a number between -64 and 63.
     */
    char getStallGuardThreshold();

    /*!
     * \brief returns the current setting of the StallGuard filter
     * \return 0 if not set, -1 if set
     */
    char getStallGuardFilter();

    /*!
     * \brief This method configures the CoolStep smart energy operation. You must have a proper StallGuard configuration for the motor situation (current, voltage, speed) in rder to use this feature.
     * \param lower_SG_threshold Sets the lower threshold for stallGuard2TM reading. Below this value, the motor current becomes increased. Allowed values are 0...480
     * \param SG_hysteresis Sets the distance between the lower and the upper threshold for stallGuard2TM reading. Above the upper threshold (which is lower_SG_threshold+SG_hysteresis+1) the motor current becomes decreased. Allowed values are 0...480
     * \param current_decrement_step_size Sets the current decrement steps. If the StallGuard value is above the threshold the current gets decremented by this step size. 0...32
     * \param current_increment_step_size Sets the current increment step. The current becomes incremented for each measured stallGuard2TM value below the lower threshold. 0...8
     * \param lower_current_limit Sets the lower motor current limit for coolStepTM operation by scaling the CS value. Values can be COOL_STEP_HALF_CS_LIMIT, COOL_STEP_QUARTER_CS_LIMIT
     * The CoolStep smart energy operation automatically adjust the current sent into the motor according to the current load,
     * read out by the StallGuard in order to provide the optimum torque with the minimal current consumption.
     * You configure the CoolStep current regulator by defining upper and lower bounds of StallGuard readouts. If the readout is above the
     * limit the current gets increased, below the limit the current gets decreased.
     * You can specify the upper an lower threshold of the StallGuard readout in order to adjust the current. You can also set the number of
     * StallGuard readings neccessary above or below the limit to get a more stable current adjustement.
     * The current adjustement itself is configured by the number of steps the current gests in- or decreased and the absolut minimum current
     * (1/2 or 1/4th otf the configured current).
     * \sa COOL_STEP_HALF_CS_LIMIT, COOL_STEP_QUARTER_CS_LIMIT
     */
    void setCoolStepConfiguration(uint16_t lower_SG_threshold, uint16_t SG_hysteresis, uint8_t current_decrement_step_size,
                                  uint8_t current_increment_step_size, uint8_t lower_current_limit);

    /*!
     * \brief enables or disables the CoolStep smart energy operation feature. It must be configured before enabling it.
     * \param enabled true if CoolStep should be enabled, false if not.
     * \sa setCoolStepConfiguration()
     */
    void setCoolStepEnabled(boolean enabled);


    /*!
     * \brief check if the CoolStep feature is enabled
     * \sa setCoolStepEnabled()
     */
    boolean isCoolStepEnabled();

    /*!
     * \brief returns the lower StallGuard threshold for the CoolStep operation
     * \sa setCoolStepConfiguration()
     */
    uint16_t getCoolStepLowerSgThreshold();

    /*!
     * \brief returns the upper StallGuard threshold for the CoolStep operation
     * \sa setCoolStepConfiguration()
     */
    uint16_t getCoolStepUpperSgThreshold();

    /*!
     * \brief returns the number of StallGuard readings befor CoolStep adjusts the motor current.
     * \sa setCoolStepConfiguration()
     */
    uint8_t getCoolStepNumberOfSGReadings();

    /*!
     * \brief returns the increment steps for the current for the CoolStep operation
     * \sa setCoolStepConfiguration()
     */
    uint8_t getCoolStepCurrentIncrementSize();

    /*!
     * \brief returns the absolut minium current for the CoolStep operation
     * \sa setCoolStepConfiguration()
     * \sa COOL_STEP_HALF_CS_LIMIT, COOL_STEP_QUARTER_CS_LIMIT
     */
    uint8_t getCoolStepLowerCurrentLimit();

    /*!
     * \brief Get the current microstep position for phase A
     * \return The current microstep position for phase A 0…255
     *
     * Keep in mind that this routine reads and writes a value via SPI - so this may take a bit time.
     */
    int16_t getMotorPosition();

    /*!
     * \brief Reads the current StallGuard value.
     * \return The current StallGuard value, lesser values indicate higher load, 0 means stall detected.
     * Keep in mind that this routine reads and writes a value via SPI - so this may take a bit time.
     * \sa setStallGuardThreshold() for tuning the readout to sensible ranges.
     */
    int16_t getCurrentStallGuardReading();

    /*!
     * \brief Reads the current current setting value as fraction of the maximum current
     * Returns values between 0 and 31, representing 1/32 to 32/32 (=1)
     * \sa setCoolStepConfiguration()
     */
    uint8_t getCurrentCSReading();


    /*!
     *\brief a convenience method to determine if the current scaling uses 0.31V or 0.165V as reference.
     *\return false if 0.13V is the reference voltage, true if 0.165V is used.
     */
    boolean isCurrentScalingHalfed();

    /*!
     * \brief Reads the current current setting value and recalculates the absolute current in mA (1A would be 1000).
     * This method calculates the currently used current setting (either by setting or by CoolStep) and reconstructs
     * the current in mA by usinge the VSENSE and resistor value. This method uses floating point math - so it
     * may not be the fastest.
     * \sa getCurrentCSReading(), getResistor(), isCurrentScalingHalfed(), getCurrent()
     */
    uint16_t getCurrentCurrent();

    /*!
     * \brief checks if there is a StallGuard warning in the last status
     * \return 0 if there was no warning, -1 if there was some warning.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     *
     * \sa setStallGuardThreshold() for tuning the readout to sensible ranges.
     */
    boolean isStallGuardOverThreshold();

    /*!
     * \brief Return over temperature status of the last status readout
     * return 0 is everything is OK, TMC26X_OVERTEMPERATURE_PREWARING if status is reached, TMC26X_OVERTEMPERATURE_SHUTDOWN is the chip is shutdown, -1 if the status is unknown.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     */
    char getOverTemperature();

    /*!
     * \brief Is motor channel A shorted to ground detected in the last status readout.
     * \return true is yes, false if not.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     */

    boolean isShortToGroundA();

    /*!
     * \brief Is motor channel B shorted to ground detected in the last status readout.
     * \return true is yes, false if not.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     */
    boolean isShortToGroundB();
    /*!
     * \brief iIs motor channel A connected according to the last statu readout.
     * \return true is yes, false if not.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     */
    boolean isOpenLoadA();

    /*!
     * \brief iIs motor channel A connected according to the last statu readout.
     * \return true is yes, false if not.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     */
    boolean isOpenLoadB();

    /*!
     * \brief Is chopper inactive since 2^20 clock cycles - defaults to ~0,08s
     * \return true is yes, false if not.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     */
    boolean isStandStill();

    /*!
     * \brief checks if there is a StallGuard warning in the last status
     * \return 0 if there was no warning, -1 if there was some warning.
     * Keep in mind that this method does not enforce a readout but uses the value of the last status readout.
     * You may want to use getMotorPosition() or getCurrentStallGuardReading() to enforce an updated status readout.
     *
     * \sa isStallGuardOverThreshold()
     * TODO why?
     *
     * \sa setStallGuardThreshold() for tuning the readout to sensible ranges.
     */
    boolean isStallGuardReached();

    /*!
     *\brief enables or disables the motor driver bridges. If disabled the motor can run freely. If enabled not.
     *\param enabled a boolean value true if the motor should be enabled, false otherwise.
     */
    void setEnabled(boolean enabled);

    /*!
     *\brief checks if the output bridges are enabled. If the bridges are not enabled the motor can run freely
     *\return true if the bridges and by that the motor driver are enabled, false if not.
     *\sa setEnabled()
     */
    boolean isEnabled();

    /*!
     * \brief Manually read out the status register
     * This function sends a byte to the motor driver in order to get the current readout. The parameter read_value
     * seletcs which value will get returned. If the read_vlaue changes in respect to the previous readout this method
     * automatically send two bytes to the motor: one to set the redout and one to get the actual readout. So this method
     * may take time to send and read one or two bits - depending on the previous readout.
     * \param read_value selects which value to read out (0..3). You can use the defines TMC26X_READOUT_POSITION, TMC_262_READOUT_STALLGUARD, or TMC_262_READOUT_CURRENT
     * \sa TMC26X_READOUT_POSITION, TMC_262_READOUT_STALLGUARD, TMC_262_READOUT_CURRENT
     */
    void readStatus(char read_value);

    /*!
     * \brief Returns the current sense resistor value in milliohm.
     * The default value of ,15 Ohm will return 150.
     */
    int16_t getResistor();

    /*!
     * \brief Prints out all the information that can be found in the last status read out - it does not force a status readout.
     * The result is printed via Serial
     */
    void debugLastStatus();

    /*!
     * \brief library version
     * \return the version number as int.
     */
    int16_t version();

  private:
    uint16_t steps_left;      // The steps the motor has to do to complete the movement
    int16_t direction;        // Direction of rotation
    uint32_t step_delay;      // Delay between steps, in ms, based on speed
    int16_t number_of_steps;  // Total number of steps this motor can take
    uint16_t speed;           // Store the current speed in order to change the speed after changing microstepping
    uint16_t resistor;        // Current sense resitor value in milliohm

    uint32_t last_step_time,  // Timestamp (ms) of the last step
             next_step_time;  // Timestamp (ms) of the next step

    // Driver control register copies to easily set & modify the registers
    uint32_t driver_control_register_value,
             chopper_config_register,
             cool_step_register_value,
             stallguard2_current_register_value,
             driver_configuration_register_value,
             driver_status_result; // The driver status result

    // Helper routione to get the top 10 bit of the readout
    inline int16_t getReadoutValue();

    // The pins for the stepper driver
    uint8_t cs_pin, step_pin, dir_pin;

    // Status values
    boolean started; // If the stepper has been started yet
    int16_t microsteps; // The current number of micro steps
    char constant_off_time; // We need to remember this value in order to enable and disable the motor
    uint8_t cool_step_lower_threshold; //  we need to remember the threshold to enable and disable the CoolStep feature
    boolean cool_step_enabled; // We need to remember this to configure the coolstep if it si enabled

    // SPI sender
    inline void send262(uint32_t datagram);
};