marlin/Marlin/src/libs/L64XX/L64XX_Marlin.cpp

/**
 * Marlin 3D Printer Firmware
 * Copyright (c) 2019 MarlinFirmware [https://github.com/MarlinFirmware/Marlin]
 *
 * Based on Sprinter and grbl.
 * Copyright (c) 2011 Camiel Gubbels / Erik van der Zalm
 *
 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation, either version 3 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *
 */

/**
 * The monitor_driver routines are a close copy of the TMC code
 */

#include "../../inc/MarlinConfig.h"

#if HAS_L64XX

#include "L64XX_Marlin.h"

L64XX_Marlin L64xxManager;

#include "../../module/stepper/indirection.h"
#include "../../gcode/gcode.h"
#include "../../module/planner.h"
#include "../../HAL/shared/Delay.h"

void echo_yes_no(const bool yes) { serialprintPGM(yes ? PSTR(" YES") : PSTR(" NO ")); }

char L64XX_Marlin::index_to_axis[MAX_L6470][3] = { "X ", "Y ", "Z ", "X2", "Y2", "Z2", "Z3", "E0", "E1", "E2", "E3", "E4", "E5" };

#define DEBUG_OUT ENABLED(L6470_CHITCHAT)
#include "../../core/debug_out.h"

uint8_t L64XX_Marlin::dir_commands[MAX_L6470];  // array to hold direction command for each driver

uint8_t L64XX_Marlin::index_to_dir[MAX_L6470] = { (INVERT_X_DIR)                        , //  0 X
                                                  (INVERT_Y_DIR)                        , //  1 Y
                                                  (INVERT_Z_DIR)                        , //  2 Z
                                                  #if ENABLED(X_DUAL_STEPPER_DRIVERS)
                                                    (INVERT_X_DIR) ^ (INVERT_X2_VS_X_DIR) , //  3 X2
                                                  #else
                                                    (INVERT_X_DIR)                      , //  3 X2
                                                  #endif
                                                  #if ENABLED(Y_DUAL_STEPPER_DRIVERS)
                                                    (INVERT_Y_DIR) ^ (INVERT_Y2_VS_Y_DIR) , //  4 Y2
                                                  #else
                                                    (INVERT_Y_DIR)                      , //  4 Y2
                                                  #endif
                                                  (INVERT_Z_DIR)                        , //  5 Z2
                                                  (INVERT_Z_DIR)                        , //  6 Z3
                                                  (INVERT_E0_DIR)                       , //  7 E0
                                                  (INVERT_E1_DIR)                       , //  8 E1
                                                  (INVERT_E2_DIR)                       , //  9 E2
                                                  (INVERT_E3_DIR)                       , // 10 E3
                                                  (INVERT_E4_DIR)                       , // 11 E4
                                                  (INVERT_E5_DIR)                       , // 12 E5
                                                };

volatile uint8_t L64XX_Marlin::spi_abort = false;
uint8_t L64XX_Marlin::spi_active = false;

L64XX_Marlin::L64XX_shadow_t L64XX_Marlin::shadow;

//uint32_t UVLO_ADC = 0x0400; // ADC undervoltage event

void L6470_populate_chain_array() {

  #define _L6470_INIT_SPI(Q)  do{ stepper##Q.set_chain_info(Q, Q##_CHAIN_POS); }while(0)

  #if AXIS_IS_L64XX(X)
    _L6470_INIT_SPI(X);
  #endif
  #if AXIS_IS_L64XX(X2)
    _L6470_INIT_SPI(X2);
  #endif
  #if AXIS_IS_L64XX(Y)
    _L6470_INIT_SPI(Y);
  #endif
  #if AXIS_IS_L64XX(Y2)
    _L6470_INIT_SPI(Y2);
  #endif
  #if AXIS_IS_L64XX(Z)
    _L6470_INIT_SPI(Z);
  #endif
  #if AXIS_IS_L64XX(Z2)
    _L6470_INIT_SPI(Z2);
  #endif
  #if AXIS_IS_L64XX(Z3)
    _L6470_INIT_SPI(Z3);
  #endif
  #if AXIS_IS_L64XX(E0)
    _L6470_INIT_SPI(E0);
  #endif
  #if AXIS_IS_L64XX(E1)
    _L6470_INIT_SPI(E1);
  #endif
  #if AXIS_IS_L64XX(E2)
    _L6470_INIT_SPI(E2);
  #endif
  #if AXIS_IS_L64XX(E3)
    _L6470_INIT_SPI(E3);
  #endif
  #if AXIS_IS_L64XX(E4)
    _L6470_INIT_SPI(E4);
  #endif
  #if AXIS_IS_L64XX(E5)
    _L6470_INIT_SPI(E5);
  #endif
}


/**
 * Some status bit positions & definitions differ per driver.
 * Copy info to known locations to simplfy check/display logic.
 *   1. Copy stepper status
 *   2. Copy status bit definitions
 *   3. Copy status layout
 *   4. Make all error bits active low (as needed)
 */
uint16_t L64XX_Marlin::get_stepper_status(L64XX &st) {
  shadow.STATUS_AXIS_RAW           = st.getStatus();
  shadow.STATUS_AXIS               = shadow.STATUS_AXIS_RAW;
  shadow.STATUS_AXIS_LAYOUT        = st.L6470_status_layout;
  shadow.AXIS_OCD_TH_MAX           = st.OCD_TH_MAX;
  shadow.AXIS_STALL_TH_MAX         = st.STALL_TH_MAX;
  shadow.AXIS_OCD_CURRENT_CONSTANT_INV   = st.OCD_CURRENT_CONSTANT_INV;
  shadow.AXIS_STALL_CURRENT_CONSTANT_INV = st.STALL_CURRENT_CONSTANT_INV;
  shadow.L6470_AXIS_CONFIG         = st.L64XX_CONFIG;
  shadow.L6470_AXIS_STATUS         = st.L64XX_STATUS;
  shadow.STATUS_AXIS_OCD           = st.STATUS_OCD;
  shadow.STATUS_AXIS_SCK_MOD       = st.STATUS_SCK_MOD;
  shadow.STATUS_AXIS_STEP_LOSS_A   = st.STATUS_STEP_LOSS_A;
  shadow.STATUS_AXIS_STEP_LOSS_B   = st.STATUS_STEP_LOSS_B;
  shadow.STATUS_AXIS_TH_SD         = st.STATUS_TH_SD;
  shadow.STATUS_AXIS_TH_WRN        = st.STATUS_TH_WRN;
  shadow.STATUS_AXIS_UVLO          = st.STATUS_UVLO;
  shadow.STATUS_AXIS_WRONG_CMD     = st.STATUS_WRONG_CMD;
  shadow.STATUS_AXIS_CMD_ERR       = st.STATUS_CMD_ERR;
  shadow.STATUS_AXIS_NOTPERF_CMD   = st.STATUS_NOTPERF_CMD;

  switch (shadow.STATUS_AXIS_LAYOUT) {
    case L6470_STATUS_LAYOUT: {   // L6470
      shadow.L6470_ERROR_MASK      = shadow.STATUS_AXIS_UVLO | shadow.STATUS_AXIS_TH_WRN | shadow.STATUS_AXIS_TH_SD | shadow.STATUS_AXIS_OCD | shadow.STATUS_AXIS_STEP_LOSS_A | shadow.STATUS_AXIS_STEP_LOSS_B;
      shadow.STATUS_AXIS           ^= (shadow.STATUS_AXIS_WRONG_CMD | shadow.STATUS_AXIS_NOTPERF_CMD);  // invert just error bits that are active high
      break;
    }
    case L6474_STATUS_LAYOUT: {   // L6474
      shadow.L6470_ERROR_MASK      = shadow.STATUS_AXIS_UVLO | shadow.STATUS_AXIS_TH_WRN | shadow.STATUS_AXIS_TH_SD | shadow.STATUS_AXIS_OCD ;
      shadow.STATUS_AXIS           ^= (shadow.STATUS_AXIS_WRONG_CMD | shadow.STATUS_AXIS_NOTPERF_CMD);  // invert just error bits that are active high
      break;
    }
    case L6480_STATUS_LAYOUT: {   // L6480 & powerSTEP01
      shadow.L6470_ERROR_MASK      = shadow.STATUS_AXIS_UVLO | shadow.STATUS_AXIS_TH_WRN | shadow.STATUS_AXIS_TH_SD | shadow.STATUS_AXIS_OCD | shadow.STATUS_AXIS_STEP_LOSS_A | shadow.STATUS_AXIS_STEP_LOSS_B;
      shadow.STATUS_AXIS           ^= (shadow.STATUS_AXIS_CMD_ERR | shadow.STATUS_AXIS_TH_WRN | shadow.STATUS_AXIS_TH_SD);  // invert just error bits that are active high
      break;
    }
  }
  return shadow.STATUS_AXIS;
}


void L64XX_Marlin::init() {               // Set up SPI and then init chips
  ENABLE_RESET_L64XX_CHIPS(LOW);          // hardware reset of drivers
  DELAY_US(100);
  ENABLE_RESET_L64XX_CHIPS(HIGH);
  DELAY_US(1000);                         // need about 650µs for the chip(s) to fully start up
  L6470_populate_chain_array();           // Set up array to control where in the SPI transfer sequence a particular stepper's data goes

  spi_init();                             // Since L64XX SPI pins are unset we must init SPI here

  init_to_defaults();                     // init the chips
}

uint16_t L64XX_Marlin::get_status(const L64XX_axis_t axis) {

  #define STATUS_L6470(Q) get_stepper_status(stepper##Q)

  switch (axis) {
    default: break;
    #if AXIS_IS_L64XX(X)
      case X : return STATUS_L6470(X);
    #endif
    #if AXIS_IS_L64XX(Y)
      case Y : return STATUS_L6470(Y);
    #endif
    #if AXIS_IS_L64XX(Z)
      case Z : return STATUS_L6470(Z);
    #endif
    #if AXIS_IS_L64XX(X2)
      case X2: return STATUS_L6470(X2);
    #endif
    #if AXIS_IS_L64XX(Y2)
      case Y2: return STATUS_L6470(Y2);
    #endif
    #if AXIS_IS_L64XX(Z2)
      case Z2: return STATUS_L6470(Z2);
    #endif
    #if AXIS_IS_L64XX(Z3)
      case Z3: return STATUS_L6470(Z3);
    #endif
    #if AXIS_IS_L64XX(E0)
      case E0: return STATUS_L6470(E0);
    #endif
    #if AXIS_IS_L64XX(E1)
      case E1: return STATUS_L6470(E1);
    #endif
    #if AXIS_IS_L64XX(E2)
      case E2: return STATUS_L6470(E2);
    #endif
    #if AXIS_IS_L64XX(E3)
      case E3: return STATUS_L6470(E3);
    #endif
    #if AXIS_IS_L64XX(E4)
      case E4: return STATUS_L6470(E4);
    #endif
    #if AXIS_IS_L64XX(E5)
      case E5: return STATUS_L6470(E5);
    #endif
  }

  return 0; // Not needed but kills a compiler warning
}

uint32_t L64XX_Marlin::get_param(const L64XX_axis_t axis, const uint8_t param) {

  #define GET_L6470_PARAM(Q) L6470_GETPARAM(param, Q)

  switch (axis) {
    default: break;
    #if AXIS_IS_L64XX(X)
      case X : return GET_L6470_PARAM(X);
    #endif
    #if AXIS_IS_L64XX(Y)
      case Y : return GET_L6470_PARAM(Y);
    #endif
    #if AXIS_IS_L64XX(Z)
      case Z : return GET_L6470_PARAM(Z);
    #endif
    #if AXIS_IS_L64XX(X2)
      case X2: return GET_L6470_PARAM(X2);
    #endif
    #if AXIS_IS_L64XX(Y2)
      case Y2: return GET_L6470_PARAM(Y2);
    #endif
    #if AXIS_IS_L64XX(Z2)
      case Z2: return GET_L6470_PARAM(Z2);
    #endif
    #if AXIS_IS_L64XX(Z3)
      case Z3: return GET_L6470_PARAM(Z3);
    #endif
    #if AXIS_IS_L64XX(E0)
      case E0: return GET_L6470_PARAM(E0);
    #endif
    #if AXIS_IS_L64XX(E1)
      case E1: return GET_L6470_PARAM(E1);
    #endif
    #if AXIS_IS_L64XX(E2)
      case E2: return GET_L6470_PARAM(E2);
    #endif
    #if AXIS_IS_L64XX(E3)
      case E3: return GET_L6470_PARAM(E3);
    #endif
    #if AXIS_IS_L64XX(E4)
      case E4: return GET_L6470_PARAM(E4);
    #endif
    #if AXIS_IS_L64XX(E5)
      case E5: return GET_L6470_PARAM(E5);
    #endif
  }

  return 0; // not needed but kills a compiler warning
}

void L64XX_Marlin::set_param(const L64XX_axis_t axis, const uint8_t param, const uint32_t value) {

  #define SET_L6470_PARAM(Q) stepper##Q.SetParam(param, value)

  switch (axis) {
    default: break;
    #if AXIS_IS_L64XX(X)
      case X : SET_L6470_PARAM(X); break;
    #endif
    #if AXIS_IS_L64XX(Y)
      case Y : SET_L6470_PARAM(Y); break;
    #endif
    #if AXIS_IS_L64XX(Z)
      case Z : SET_L6470_PARAM(Z); break;
    #endif
    #if AXIS_IS_L64XX(X2)
      case X2: SET_L6470_PARAM(X2); break;
    #endif
    #if AXIS_IS_L64XX(Y2)
      case Y2: SET_L6470_PARAM(Y2); break;
    #endif
    #if AXIS_IS_L64XX(Z2)
      case Z2: SET_L6470_PARAM(Z2); break;
    #endif
    #if AXIS_IS_L64XX(Z3)
      case Z3: SET_L6470_PARAM(Z3); break;
    #endif
    #if AXIS_IS_L64XX(E0)
      case E0: SET_L6470_PARAM(E0); break;
    #endif
    #if AXIS_IS_L64XX(E1)
      case E1: SET_L6470_PARAM(E1); break;
    #endif
    #if AXIS_IS_L64XX(E2)
      case E2: SET_L6470_PARAM(E2); break;
    #endif
    #if AXIS_IS_L64XX(E3)
      case E3: SET_L6470_PARAM(E3); break;
    #endif
    #if AXIS_IS_L64XX(E4)
      case E4: SET_L6470_PARAM(E4); break;
    #endif
    #if AXIS_IS_L64XX(E5)
      case E5: SET_L6470_PARAM(E5); break;
    #endif
  }
}

inline void echo_min_max(const char a, const float &min, const float &max) {
  DEBUG_CHAR(' '); DEBUG_CHAR(a);
  DEBUG_ECHOPAIR(" min = ", min);
  DEBUG_ECHOLNPAIR("  max = ", max);
}
inline void echo_oct_used(const float &oct, const uint8_t stall) {
  DEBUG_ECHOPAIR("over_current_threshold used     : ", oct);
  serialprintPGM(stall ? PSTR("  (Stall") : PSTR("  (OCD"));
  DEBUG_ECHOLNPGM(" threshold)");
}
inline void err_out_of_bounds() { DEBUG_ECHOLNPGM("Test aborted - motion out of bounds"); }

uint8_t L64XX_Marlin::get_user_input(uint8_t &driver_count, L64XX_axis_t axis_index[3],  char axis_mon[3][3],
                                 float &position_max, float &position_min, float &final_feedrate, uint8_t &kval_hold,
                                 uint8_t over_current_flag, uint8_t &OCD_TH_val, uint8_t &STALL_TH_val, uint16_t &over_current_threshold
) {
  // Return TRUE if the calling routine needs to abort/kill

  uint16_t displacement = 0;  // " = 0" to eliminate compiler warning
  uint8_t j;   // general purpose counter

  if (!all_axes_homed()) {
    DEBUG_ECHOLNPGM("Test aborted - home all before running this command");
    return true;
  }

  uint8_t found_displacement = false;
  LOOP_XYZE(i) if (uint16_t _displacement = parser.intval(axis_codes[i])) {
    found_displacement = true;
    displacement = _displacement;
    uint8_t axis_offset = parser.byteval('J');
    axis_mon[0][0] = axis_codes[i];   // axis ASCII value (target character)
    uint8_t driver_count_local = 0;         // Can't use "driver_count" directly as a subscript because it's passed by reference
    if (axis_offset >= 2 || axis_mon[0][0] == 'E') {  // Single axis, E0, or E1
      axis_mon[0][1] = axis_offset + '0';
      for (j = 0; j < MAX_L6470; j++) {       // See how many drivers on this axis
        const char * const str = index_to_axis[j];
        if (axis_mon[0][0] == str[0]) {
          char * const mon = axis_mon[driver_count_local];
          mon[0] = str[0];
          mon[1] = str[1];
          mon[2] = str[2];   // append end of string
          axis_index[driver_count_local] = (L64XX_axis_t)j;        // set axis index
          driver_count_local++;
        }
      }
    }
    else if (axis_offset == 0) {              // One or more axes
      for (j = 0; j < MAX_L6470; j++) {       // See how many drivers on this axis
        const char * const str = index_to_axis[j];
        if (axis_mon[0][0] == str[0]) {
          char * const mon = axis_mon[driver_count_local];
          mon[0] = str[0];
          mon[1] = str[1];
          mon[2] = str[2];   // append end of string
          axis_index[driver_count_local] = (L64XX_axis_t)j;        // set axis index
          driver_count_local++;
        }
      }
      driver_count = driver_count_local;
    }
    break; // only take first axis found
  }

  if (!found_displacement) {
    DEBUG_ECHOLNPGM("Test aborted - AXIS with displacement is required");
    return true;
  }

  //
  // Position calcs & checks
  //

  const float X_center = LOGICAL_X_POSITION(current_position.x),
              Y_center = LOGICAL_Y_POSITION(current_position.y),
              Z_center = LOGICAL_Z_POSITION(current_position.z),
              E_center = current_position.e;

  switch (axis_mon[0][0]) {
    default: position_max = position_min = 0; break;

    case 'X': {
      position_min = X_center - displacement;
      position_max = X_center + displacement;
      echo_min_max('X', position_min, position_max);
      if (false
        #ifdef X_MIN_POS
          || position_min < (X_MIN_POS)
        #endif
        #ifdef X_MAX_POS
          || position_max > (X_MAX_POS)
        #endif
      ) {
        err_out_of_bounds();
        return true;
      }
    } break;

    case 'Y': {
      position_min = Y_center - displacement;
      position_max = Y_center + displacement;
      echo_min_max('Y', position_min, position_max);
      if (false
        #ifdef Y_MIN_POS
          || position_min < (Y_MIN_POS)
        #endif
        #ifdef Y_MAX_POS
          || position_max > (Y_MAX_POS)
        #endif
      ) {
        err_out_of_bounds();
        return true;
      }
    } break;

    case 'Z': {
      position_min = Z_center - displacement;
      position_max = Z_center + displacement;
      echo_min_max('Z', position_min, position_max);
      if (false
        #ifdef Z_MIN_POS
          || position_min < (Z_MIN_POS)
        #endif
        #ifdef Z_MAX_POS
          || position_max > (Z_MAX_POS)
        #endif
      ) {
        err_out_of_bounds();
        return true;
      }
    } break;

    case 'E': {
      position_min = E_center - displacement;
      position_max = E_center + displacement;
      echo_min_max('E', position_min, position_max);
    } break;
  }

  //
  // Work on the drivers
  //

  for (uint8_t k = 0; k < driver_count; k++) {
    uint8_t not_found = true;
    for (j = 1; j <= L64XX::chain[0]; j++) {
      const char * const ind_axis = index_to_axis[L64XX::chain[j]];
      if (ind_axis[0] == axis_mon[k][0] && ind_axis[1] == axis_mon[k][1]) { // See if a L6470 driver
        not_found = false;
        break;
      }
    }
    if (not_found) {
      driver_count = k;
      axis_mon[k][0] = ' ';  // mark this entry invalid
      break;
    }
  }

  if (driver_count == 0) {
    DEBUG_ECHOLNPGM("Test aborted - not a L6470 axis");
    return true;
  }

  DEBUG_ECHOPGM("Monitoring:");
  for (j = 0; j < driver_count; j++) DEBUG_ECHOPAIR("  ", axis_mon[j]);
  DEBUG_EOL();

  // now have a list of driver(s) to monitor

  //
  // TVAL & kVAL_HOLD checks & settings
  //
  const L64XX_shadow_t &sh = shadow;
  get_status(axis_index[0]); // populate shadow array

  if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) {  // L6474 - use TVAL
    uint16_t TVAL_current = parser.ushortval('T');
    if (TVAL_current) {
      uint8_t TVAL_count = (TVAL_current /  sh.AXIS_STALL_CURRENT_CONSTANT_INV) - 1;
      LIMIT(TVAL_count, 0, sh.AXIS_STALL_TH_MAX);
      for (j = 0; j < driver_count; j++)
        set_param(axis_index[j], L6474_TVAL, TVAL_count);
    }
    // only print the tval from one of the drivers
    kval_hold = get_param(axis_index[0], L6474_TVAL);
    DEBUG_ECHOLNPAIR("TVAL current (mA) = ", (kval_hold + 1) * sh.AXIS_STALL_CURRENT_CONSTANT_INV);
  }
  else {
    kval_hold = parser.byteval('K');
    if (kval_hold) {
      DEBUG_ECHOLNPAIR("kval_hold = ", kval_hold);
      for (j = 0; j < driver_count; j++)
        set_param(axis_index[j], L6470_KVAL_HOLD, kval_hold);
    }
    else {
      // only print the KVAL_HOLD from one of the drivers
      kval_hold = get_param(axis_index[0], L6470_KVAL_HOLD);
      DEBUG_ECHOLNPAIR("KVAL_HOLD = ", kval_hold);
    }
  }

  //
  // Overcurrent checks & settings
  //

  if (over_current_flag) {

    uint8_t OCD_TH_val_local = 0,       // compiler thinks OCD_TH_val is unused if use it directly
            STALL_TH_val_local = 0;     // just in case ...

    over_current_threshold = parser.intval('I');

    if (over_current_threshold) {

      OCD_TH_val_local = over_current_threshold/375;
      LIMIT(OCD_TH_val_local, 0, 15);
      STALL_TH_val_local = over_current_threshold/31.25;
      LIMIT(STALL_TH_val_local, 0, 127);
      uint16_t OCD_TH_actual = (OCD_TH_val_local + 1) * 375,
               STALL_TH_actual = (STALL_TH_val_local + 1) * 31.25;
      if (OCD_TH_actual < STALL_TH_actual) {
        OCD_TH_val_local++;
        OCD_TH_actual = (OCD_TH_val_local + 1) * 375;
      }

      DEBUG_ECHOLNPAIR("over_current_threshold specified: ", over_current_threshold);
      if (!(sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT)) echo_oct_used((STALL_TH_val_local + 1) * 31.25, true);
      echo_oct_used((OCD_TH_val_local + 1) * 375, false);

      #define SET_OVER_CURRENT(Q) do { stepper##Q.SetParam(L6470_STALL_TH, STALL_TH_val_local); stepper##Q.SetParam(L6470_OCD_TH, OCD_TH_val_local);} while (0)

      for (j = 0; j < driver_count; j++) {
        set_param(axis_index[j], L6470_STALL_TH, STALL_TH_val_local);
        set_param(axis_index[j], L6470_OCD_TH, OCD_TH_val_local);
      }
    }
    else {
      // only get & print the OVER_CURRENT values from one of the drivers
      STALL_TH_val_local = get_param(axis_index[0], L6470_STALL_TH);
      OCD_TH_val_local = get_param(axis_index[0], L6470_OCD_TH);

      if (!(sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT)) echo_oct_used((STALL_TH_val_local + 1) * 31.25, true);
      echo_oct_used((OCD_TH_val_local + 1) * 375, false);
    } // over_current_threshold

    for (j = 0; j < driver_count; j++) {                 // set all drivers on axis the same
      set_param(axis_index[j], L6470_STALL_TH, STALL_TH_val_local);
      set_param(axis_index[j], L6470_OCD_TH, OCD_TH_val_local);
    }

    OCD_TH_val = OCD_TH_val_local;        // force compiler to update the main routine's copy
    STALL_TH_val = STALL_TH_val_local;    // force compiler to update the main routine's copy
  } // end of overcurrent

  //
  // Feedrate
  //

  final_feedrate = parser.floatval('F');
  if (final_feedrate == 0) {
    static constexpr float default_max_feedrate[] = DEFAULT_MAX_FEEDRATE;
    const uint8_t num_feedrates = COUNT(default_max_feedrate);
    for (j = 0; j < num_feedrates; j++) {
      if (axis_codes[j] == axis_mon[0][0]) {
        final_feedrate = default_max_feedrate[j];
        break;
      }
    }
    if (j == 3 && num_feedrates > 4) {   // have more than one extruder feedrate
      uint8_t extruder_num = axis_mon[0][1] - '0';
      if (j <= num_feedrates - extruder_num)     // have a feedrate specifically for this extruder
        final_feedrate = default_max_feedrate[j + extruder_num];
      else
        final_feedrate = default_max_feedrate[3];  // use E0 feedrate for this extruder
    }
    final_feedrate *= 60;  // convert to mm/minute
  } // end of feedrate

  return false;   // FALSE indicates no user input problems
}

void L64XX_Marlin::say_axis(const L64XX_axis_t axis, const uint8_t label/*=true*/) {
  if (label) SERIAL_ECHOPGM("AXIS:");
  const char * const str = L64xxManager.index_to_axis[axis];
  SERIAL_CHAR(' ', str[0], str[1], ' ');
}

#if ENABLED(L6470_CHITCHAT)

  // Assumes status bits have been inverted
  void L64XX_Marlin::error_status_decode(const uint16_t status, const L64XX_axis_t axis,
        const uint16_t _status_axis_th_sd, const uint16_t _status_axis_th_wrn,
        const uint16_t _status_axis_step_loss_a, const uint16_t _status_axis_step_loss_b,
        const uint16_t _status_axis_ocd, const uint8_t _status_axis_layout
  ) {
    say_axis(axis);
    DEBUG_ECHOPGM("  THERMAL: ");
    serialprintPGM((status & _status_axis_th_sd) ? PSTR("SHUTDOWN") : (status & _status_axis_th_wrn) ? PSTR("WARNING ") : PSTR("OK      "));
    DEBUG_ECHOPGM("   OVERCURRENT: ");
    echo_yes_no((status & _status_axis_ocd) != 0);
    if (!(_status_axis_layout == L6474_STATUS_LAYOUT)) {  // L6474 doesn't have these bits
      DEBUG_ECHOPGM("   STALL: ");
      echo_yes_no((status & (_status_axis_step_loss_a | _status_axis_step_loss_b)) != 0);
    }
    DEBUG_EOL();
  }

#endif

//////////////////////////////////////////////////////////////////////////////////////////////////
////
////  MONITOR_L6470_DRIVER_STATUS routines
////
//////////////////////////////////////////////////////////////////////////////////////////////////

#if ENABLED(MONITOR_L6470_DRIVER_STATUS)

  bool L64XX_Marlin::monitor_paused = false; // Flag to skip monitor during M122, M906, M916, M917, M918, etc.

  struct L6470_driver_data {
    uint8_t driver_index;
    uint32_t driver_status;
    uint8_t is_otw;
    uint8_t otw_counter;
    uint8_t is_ot;
    uint8_t is_hi_Z;
    uint8_t com_counter;
  };

  L6470_driver_data driver_L6470_data[] = {
    #if AXIS_IS_L64XX(X)
      {  0, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(Y)
      {  1, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(Z)
      {  2, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(X2)
      {  3, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(Y2)
      {  4, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(Z2)
      {  5, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(Z3)
      {  6, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(E0)
      {  7, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(E1)
      {  8, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(E2)
      {  9, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(E3)
      { 10, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(E4)
      { 11, 0, 0, 0, 0, 0, 0 },
    #endif
    #if AXIS_IS_L64XX(E5)
      { 12, 0, 0, 0, 0, 0, 0 }
    #endif
  };

  void L64XX_Marlin::append_stepper_err(char* &p, const uint8_t stepper_index, const char * const err/*=nullptr*/) {
    p += sprintf_P(p, PSTR("Stepper %c%c "), index_to_axis[stepper_index][0], index_to_axis[stepper_index][1]);
    if (err) p += sprintf_P(p, err);
  }

  void L64XX_Marlin::monitor_update(L64XX_axis_t stepper_index) {
    if (spi_abort) return;  // don't do anything if set_directions() has occurred
    const L64XX_shadow_t &sh = shadow;
    get_status(stepper_index); // get stepper status and details
    uint16_t status = sh.STATUS_AXIS;
    uint8_t kval_hold, tval;
    char temp_buf[120], *p = temp_buf;
    uint8_t j;
    for (j = 0; j < L64XX::chain[0]; j++) // find the table for this stepper
      if (driver_L6470_data[j].driver_index == stepper_index) break;

    driver_L6470_data[j].driver_status = status;
    uint16_t _status = ~status;     // all error bits are active low

    if (status == 0 || status == 0xFFFF) {              // com problem
      if (driver_L6470_data[j].com_counter == 0) {      // warn user when it first happens
        driver_L6470_data[j].com_counter++;
        append_stepper_err(p, stepper_index, PSTR(" - communications lost\n"));
        DEBUG_ECHO(temp_buf);
      }
      else {
        driver_L6470_data[j].com_counter++;
        if (driver_L6470_data[j].com_counter > 240) {  // remind of com problem about every 2 minutes
          driver_L6470_data[j].com_counter = 1;
          append_stepper_err(p, stepper_index, PSTR(" - still no communications\n"));
          DEBUG_ECHO(temp_buf);
        }
      }
    }
    else {
      if (driver_L6470_data[j].com_counter) {   // comms re-established
        driver_L6470_data[j].com_counter = 0;
        append_stepper_err(p, stepper_index, PSTR(" - communications re-established\n.. setting all drivers to default values\n"));
        DEBUG_ECHO(temp_buf);
        init_to_defaults();
      }
      else {
        // no com problems - do the usual checks
        if (_status & sh.L6470_ERROR_MASK) {
          append_stepper_err(p, stepper_index);

          if (status & STATUS_HIZ) {                         // The driver has shut down. HiZ is active high
            driver_L6470_data[j].is_hi_Z = true;
            p += sprintf_P(p, PSTR("%cIS SHUT DOWN"), ' ');
            //if (_status & sh.STATUS_AXIS_TH_SD) { // strange - TH_SD never seems to go active, must be implied by the HiZ and TH_WRN
            if (_status & sh.STATUS_AXIS_TH_WRN) {                    // over current shutdown
              p += sprintf_P(p, PSTR("%cdue to over temperature"), ' ');
              driver_L6470_data[j].is_ot = true;
              if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) {  // L6474
                tval = get_param(stepper_index, L6474_TVAL) - 2 * KVAL_HOLD_STEP_DOWN;
              set_param(stepper_index, L6474_TVAL, tval);     // reduce TVAL
                p += sprintf_P(p, PSTR(" - TVAL reduced by %d to %d mA"), uint16_t (2 * KVAL_HOLD_STEP_DOWN * sh.AXIS_STALL_CURRENT_CONSTANT_INV), uint16_t ((tval + 1) * sh.AXIS_STALL_CURRENT_CONSTANT_INV));   // let user know
              }
              else {
                kval_hold = get_param(stepper_index, L6470_KVAL_HOLD) - 2 * KVAL_HOLD_STEP_DOWN;
                set_param(stepper_index, L6470_KVAL_HOLD, kval_hold);     // reduce KVAL_HOLD
                p += sprintf_P(p, PSTR(" - KVAL_HOLD reduced by %d to %d"), 2 * KVAL_HOLD_STEP_DOWN, kval_hold);   // let user know
              }
            }
            else
              driver_L6470_data[j].is_ot = false;
          }
          else {
            driver_L6470_data[j].is_hi_Z = false;

            if (_status & sh.STATUS_AXIS_TH_WRN) {     // have an over temperature warning
              driver_L6470_data[j].is_otw = true;
              driver_L6470_data[j].otw_counter++;
              kval_hold = get_param(stepper_index, L6470_KVAL_HOLD);
              if (driver_L6470_data[j].otw_counter > 4) {  // otw present for 2 - 2.5 seconds, reduce KVAL_HOLD
                driver_L6470_data[j].otw_counter = 0;
                driver_L6470_data[j].is_otw = true;
                if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) {  // L6474
                  tval = get_param(stepper_index, L6474_TVAL) - KVAL_HOLD_STEP_DOWN;
                  set_param(stepper_index, L6474_TVAL, tval);     // reduce TVAL
                  p += sprintf_P(p, PSTR(" - TVAL reduced by %d to %d mA"), uint16_t (KVAL_HOLD_STEP_DOWN * sh.AXIS_STALL_CURRENT_CONSTANT_INV), uint16_t ((tval + 1) * sh.AXIS_STALL_CURRENT_CONSTANT_INV));   // let user know
                }
                else {
                  kval_hold = get_param(stepper_index, L6470_KVAL_HOLD) - KVAL_HOLD_STEP_DOWN;
                  set_param(stepper_index, L6470_KVAL_HOLD, kval_hold);     // reduce KVAL_HOLD
                  p += sprintf_P(p, PSTR(" - KVAL_HOLD reduced by %d to %d"), KVAL_HOLD_STEP_DOWN, kval_hold);   // let user know
                }
              }
              else if (driver_L6470_data[j].otw_counter)
                p += sprintf_P(p, PSTR("%c- thermal warning"), ' ');   // warn user
            }
          }

          #if ENABLED(L6470_STOP_ON_ERROR)
            if (_status & (sh.STATUS_AXIS_UVLO | sh.STATUS_AXIS_TH_WRN | sh.STATUS_AXIS_TH_SD))
              kill(temp_buf);
          #endif

          #if ENABLED(L6470_CHITCHAT)
            if (_status & sh.STATUS_AXIS_OCD)
              p += sprintf_P(p, PSTR("%c  over current"), ' ');

            if (_status & (sh.STATUS_AXIS_STEP_LOSS_A | sh.STATUS_AXIS_STEP_LOSS_B))
              p += sprintf_P(p, PSTR("%c  stall"), ' ');

            if (_status & sh.STATUS_AXIS_UVLO)
              p += sprintf_P(p, PSTR("%c  under voltage lock out"), ' ');

            p += sprintf_P(p, PSTR("%c\n"), ' ');
          #endif

          DEBUG_ECHOLN(temp_buf);  // print the error message
        }
        else {
          driver_L6470_data[j].is_ot = false;
          driver_L6470_data[j].otw_counter = 0;   //clear out warning indicators
          driver_L6470_data[j].is_otw = false;
        } // end usual checks

      } // comms established but have errors
    } // comms re-established
  } // end monitor_update()


  void L64XX_Marlin::monitor_driver() {
    static millis_t next_cOT = 0;
    if (ELAPSED(millis(), next_cOT)) {
      next_cOT = millis() + 500;

      if (!monitor_paused) {  // Skip during M122, M906, M916, M917 or M918 (could steal status result from test)

        spi_active = true;    // Tell set_directions() a series of SPI transfers is underway

        #if AXIS_IS_L64XX(X)
          monitor_update(X);
        #endif
        #if AXIS_IS_L64XX(Y)
          monitor_update(Y);
        #endif
        #if AXIS_IS_L64XX(Z)
          monitor_update(Z);
        #endif
        #if AXIS_IS_L64XX(X2)
          monitor_update(X2);
        #endif
        #if AXIS_IS_L64XX(Y2)
          monitor_update(Y2);
        #endif
        #if AXIS_IS_L64XX(Z2)
          monitor_update(Z2);
        #endif
        #if AXIS_IS_L64XX(Z3)
          monitor_update(Z3);
        #endif
        #if AXIS_IS_L64XX(E0)
          monitor_update(E0);
        #endif
        #if AXIS_IS_L64XX(E1)
          monitor_update(E1);
        #endif
        #if AXIS_IS_L64XX(E2)
          monitor_update(E2);
        #endif
        #if AXIS_IS_L64XX(E3)
          monitor_update(E3);
        #endif
        #if AXIS_IS_L64XX(E4)
          monitor_update(E4);
        #endif
        #if AXIS_IS_L64XX(E5)
          monitor_update(E5);
        #endif

        #if ENABLED(L6470_DEBUG)
          if (report_L6470_status) DEBUG_EOL();
        #endif

        spi_active = false;   // done with all SPI transfers - clear handshake flags
        spi_abort = false;
      }
    }
  }

#endif // MONITOR_L6470_DRIVER_STATUS

#endif // HAS_L64XX