/**
 * 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/>.
 *
 */

/**
 * stepper/trinamic.cpp
 * Stepper driver indirection for Trinamic
 */

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

#if HAS_TRINAMIC

#include "trinamic.h"
#include "../stepper.h"

#include <HardwareSerial.h>
#include <SPI.h>

enum StealthIndex : uint8_t { STEALTH_AXIS_XY, STEALTH_AXIS_Z, STEALTH_AXIS_E };
#define _TMC_INIT(ST, STEALTH_INDEX) tmc_init(stepper##ST, ST##_CURRENT, ST##_MICROSTEPS, ST##_HYBRID_THRESHOLD, stealthchop_by_axis[STEALTH_INDEX])

//   IC = TMC model number
//   ST = Stepper object letter
//   L  = Label characters
//   AI = Axis Enum Index
// SWHW = SW/SH UART selection
#if ENABLED(TMC_USE_SW_SPI)
  #define __TMC_SPI_DEFINE(IC, ST, L, AI) TMCMarlin<IC##Stepper, L, AI> stepper##ST(ST##_CS_PIN, ST##_RSENSE, TMC_SW_MOSI, TMC_SW_MISO, TMC_SW_SCK, ST##_CHAIN_POS)
#else
  #define __TMC_SPI_DEFINE(IC, ST, L, AI) TMCMarlin<IC##Stepper, L, AI> stepper##ST(ST##_CS_PIN, ST##_RSENSE, ST##_CHAIN_POS)
#endif

#define TMC_UART_HW_DEFINE(IC, ST, L, AI) TMCMarlin<IC##Stepper, L, AI> stepper##ST(&ST##_HARDWARE_SERIAL, ST##_RSENSE, ST##_SLAVE_ADDRESS)
#define TMC_UART_SW_DEFINE(IC, ST, L, AI) TMCMarlin<IC##Stepper, L, AI> stepper##ST(ST##_SERIAL_RX_PIN, ST##_SERIAL_TX_PIN, ST##_RSENSE, ST##_SLAVE_ADDRESS, ST##_SERIAL_RX_PIN > -1)

#define _TMC_SPI_DEFINE(IC, ST, AI) __TMC_SPI_DEFINE(IC, ST, TMC_##ST##_LABEL, AI)
#define TMC_SPI_DEFINE(ST, AI) _TMC_SPI_DEFINE(ST##_DRIVER_TYPE, ST, AI##_AXIS)

#define _TMC_UART_DEFINE(SWHW, IC, ST, AI) TMC_UART_##SWHW##_DEFINE(IC, ST, TMC_##ST##_LABEL, AI)
#define TMC_UART_DEFINE(SWHW, ST, AI) _TMC_UART_DEFINE(SWHW, ST##_DRIVER_TYPE, ST, AI##_AXIS)

#if ENABLED(DISTINCT_E_FACTORS) && E_STEPPERS > 1
  #define TMC_SPI_DEFINE_E(AI) TMC_SPI_DEFINE(E##AI, E##AI)
  #define TMC_UART_DEFINE_E(SWHW, AI) TMC_UART_DEFINE(SWHW, E##AI, E##AI)
#else
  #define TMC_SPI_DEFINE_E(AI) TMC_SPI_DEFINE(E##AI, E)
  #define TMC_UART_DEFINE_E(SWHW, AI) TMC_UART_DEFINE(SWHW, E##AI, E)
#endif

// Stepper objects of TMC2130/TMC2160/TMC2660/TMC5130/TMC5160 steppers used
#if AXIS_HAS_SPI(X)
  TMC_SPI_DEFINE(X, X);
#endif
#if AXIS_HAS_SPI(X2)
  TMC_SPI_DEFINE(X2, X);
#endif
#if AXIS_HAS_SPI(Y)
  TMC_SPI_DEFINE(Y, Y);
#endif
#if AXIS_HAS_SPI(Y2)
  TMC_SPI_DEFINE(Y2, Y);
#endif
#if AXIS_HAS_SPI(Z)
  TMC_SPI_DEFINE(Z, Z);
#endif
#if AXIS_HAS_SPI(Z2)
  TMC_SPI_DEFINE(Z2, Z);
#endif
#if AXIS_HAS_SPI(Z3)
  TMC_SPI_DEFINE(Z3, Z);
#endif
#if AXIS_HAS_SPI(Z4)
  TMC_SPI_DEFINE(Z4, Z);
#endif
#if AXIS_HAS_SPI(E0)
  TMC_SPI_DEFINE_E(0);
#endif
#if AXIS_HAS_SPI(E1)
  TMC_SPI_DEFINE_E(1);
#endif
#if AXIS_HAS_SPI(E2)
  TMC_SPI_DEFINE_E(2);
#endif
#if AXIS_HAS_SPI(E3)
  TMC_SPI_DEFINE_E(3);
#endif
#if AXIS_HAS_SPI(E4)
  TMC_SPI_DEFINE_E(4);
#endif
#if AXIS_HAS_SPI(E5)
  TMC_SPI_DEFINE_E(5);
#endif

#ifndef TMC_BAUD_RATE
  #define TMC_BAUD_RATE 115200
#endif

#if HAS_DRIVER(TMC2130)
  template<char AXIS_LETTER, char DRIVER_ID, AxisEnum AXIS_ID>
  void tmc_init(TMCMarlin<TMC2130Stepper, AXIS_LETTER, DRIVER_ID, AXIS_ID> &st, const uint16_t mA, const uint16_t microsteps, const uint32_t thrs, const bool stealth) {
    st.begin();

    CHOPCONF_t chopconf{0};
    chopconf.tbl = 1;
    chopconf.toff = chopper_timing.toff;
    chopconf.intpol = INTERPOLATE;
    chopconf.hend = chopper_timing.hend + 3;
    chopconf.hstrt = chopper_timing.hstrt - 1;
    #if ENABLED(SQUARE_WAVE_STEPPING)
      chopconf.dedge = true;
    #endif
    st.CHOPCONF(chopconf.sr);

    st.rms_current(mA, HOLD_MULTIPLIER);
    st.microsteps(microsteps);
    st.iholddelay(10);
    st.TPOWERDOWN(128); // ~2s until driver lowers to hold current

    st.en_pwm_mode(stealth);
    st.stored.stealthChop_enabled = stealth;

    PWMCONF_t pwmconf{0};
    pwmconf.pwm_freq = 0b01; // f_pwm = 2/683 f_clk
    pwmconf.pwm_autoscale = true;
    pwmconf.pwm_grad = 5;
    pwmconf.pwm_ampl = 180;
    st.PWMCONF(pwmconf.sr);

    #if ENABLED(HYBRID_THRESHOLD)
      st.set_pwm_thrs(thrs);
    #else
      UNUSED(thrs);
    #endif

    st.GSTAT(); // Clear GSTAT
  }
#endif // TMC2130

#if HAS_DRIVER(TMC2160)
  template<char AXIS_LETTER, char DRIVER_ID, AxisEnum AXIS_ID>
  void tmc_init(TMCMarlin<TMC2160Stepper, AXIS_LETTER, DRIVER_ID, AXIS_ID> &st, const uint16_t mA, const uint16_t microsteps, const uint32_t thrs, const bool stealth) {
    st.begin();

    CHOPCONF_t chopconf{0};
    chopconf.tbl = 1;
    chopconf.toff = chopper_timing.toff;
    chopconf.intpol = INTERPOLATE;
    chopconf.hend = chopper_timing.hend + 3;
    chopconf.hstrt = chopper_timing.hstrt - 1;
    #if ENABLED(SQUARE_WAVE_STEPPING)
      chopconf.dedge = true;
    #endif
    st.CHOPCONF(chopconf.sr);

    st.rms_current(mA, HOLD_MULTIPLIER);
    st.microsteps(microsteps);
    st.iholddelay(10);
    st.TPOWERDOWN(128); // ~2s until driver lowers to hold current

    st.en_pwm_mode(stealth);
    st.stored.stealthChop_enabled = stealth;

    TMC2160_n::PWMCONF_t pwmconf{0};
    pwmconf.pwm_lim = 12;
    pwmconf.pwm_reg = 8;
    pwmconf.pwm_autograd = true;
    pwmconf.pwm_autoscale = true;
    pwmconf.pwm_freq = 0b01;
    pwmconf.pwm_grad = 14;
    pwmconf.pwm_ofs = 36;
    st.PWMCONF(pwmconf.sr);

    #if ENABLED(HYBRID_THRESHOLD)
      st.set_pwm_thrs(thrs);
    #else
      UNUSED(thrs);
    #endif

    st.GSTAT(); // Clear GSTAT
  }
#endif // TMC2160

//
// TMC2208/2209 Driver objects and inits
//
#if HAS_TMC220x
  #if AXIS_HAS_UART(X)
    #ifdef X_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, X, X);
    #else
      TMC_UART_DEFINE(SW, X, X);
    #endif
  #endif
  #if AXIS_HAS_UART(X2)
    #ifdef X2_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, X2, X);
    #else
      TMC_UART_DEFINE(SW, X2, X);
    #endif
  #endif
  #if AXIS_HAS_UART(Y)
    #ifdef Y_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, Y, Y);
    #else
      TMC_UART_DEFINE(SW, Y, Y);
    #endif
  #endif
  #if AXIS_HAS_UART(Y2)
    #ifdef Y2_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, Y2, Y);
    #else
      TMC_UART_DEFINE(SW, Y2, Y);
    #endif
  #endif
  #if AXIS_HAS_UART(Z)
    #ifdef Z_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, Z, Z);
    #else
      TMC_UART_DEFINE(SW, Z, Z);
    #endif
  #endif
  #if AXIS_HAS_UART(Z2)
    #ifdef Z2_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, Z2, Z);
    #else
      TMC_UART_DEFINE(SW, Z2, Z);
    #endif
  #endif
  #if AXIS_HAS_UART(Z3)
    #ifdef Z3_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, Z3, Z);
    #else
      TMC_UART_DEFINE(SW, Z3, Z);
    #endif
  #endif
  #if AXIS_HAS_UART(Z4)
    #ifdef Z4_HARDWARE_SERIAL
      TMC_UART_DEFINE(HW, Z4, Z);
    #else
      TMC_UART_DEFINE(SW, Z4, Z);
    #endif
  #endif
  #if AXIS_HAS_UART(E0)
    #ifdef E0_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 0);
    #else
      TMC_UART_DEFINE_E(SW, 0);
    #endif
  #endif
  #if AXIS_HAS_UART(E1)
    #ifdef E1_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 1);
    #else
      TMC_UART_DEFINE_E(SW, 1);
    #endif
  #endif
  #if AXIS_HAS_UART(E2)
    #ifdef E2_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 2);
    #else
      TMC_UART_DEFINE_E(SW, 2);
    #endif
  #endif
  #if AXIS_HAS_UART(E3)
    #ifdef E3_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 3);
    #else
      TMC_UART_DEFINE_E(SW, 3);
    #endif
  #endif
  #if AXIS_HAS_UART(E4)
    #ifdef E4_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 4);
    #else
      TMC_UART_DEFINE_E(SW, 4);
    #endif
  #endif
  #if AXIS_HAS_UART(E5)
    #ifdef E5_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 5);
    #else
      TMC_UART_DEFINE_E(SW, 5);
    #endif
  #endif
  #if AXIS_HAS_UART(E6)
    #ifdef E6_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 6);
    #else
      TMC_UART_DEFINE_E(SW, 6);
    #endif
  #endif
  #if AXIS_HAS_UART(E7)
    #ifdef E7_HARDWARE_SERIAL
      TMC_UART_DEFINE_E(HW, 7);
    #else
      TMC_UART_DEFINE_E(SW, 7);
    #endif
  #endif

  void tmc_serial_begin() {
    #if AXIS_HAS_UART(X)
      #ifdef X_HARDWARE_SERIAL
        X_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperX.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(X2)
      #ifdef X2_HARDWARE_SERIAL
        X2_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperX2.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(Y)
      #ifdef Y_HARDWARE_SERIAL
        Y_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperY.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(Y2)
      #ifdef Y2_HARDWARE_SERIAL
        Y2_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperY2.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(Z)
      #ifdef Z_HARDWARE_SERIAL
        Z_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperZ.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(Z2)
      #ifdef Z2_HARDWARE_SERIAL
        Z2_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperZ2.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(Z3)
      #ifdef Z3_HARDWARE_SERIAL
        Z3_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperZ3.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(Z4)
      #ifdef Z4_HARDWARE_SERIAL
        Z4_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperZ4.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E0)
      #ifdef E0_HARDWARE_SERIAL
        E0_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE0.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E1)
      #ifdef E1_HARDWARE_SERIAL
        E1_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE1.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E2)
      #ifdef E2_HARDWARE_SERIAL
        E2_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE2.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E3)
      #ifdef E3_HARDWARE_SERIAL
        E3_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE3.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E4)
      #ifdef E4_HARDWARE_SERIAL
        E4_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE4.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E5)
      #ifdef E5_HARDWARE_SERIAL
        E5_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE5.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E6)
      #ifdef E6_HARDWARE_SERIAL
        E6_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE6.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
    #if AXIS_HAS_UART(E7)
      #ifdef E7_HARDWARE_SERIAL
        E7_HARDWARE_SERIAL.begin(TMC_BAUD_RATE);
      #else
        stepperE7.beginSerial(TMC_BAUD_RATE);
      #endif
    #endif
  }
#endif

#if HAS_DRIVER(TMC2208)
  template<char AXIS_LETTER, char DRIVER_ID, AxisEnum AXIS_ID>
  void tmc_init(TMCMarlin<TMC2208Stepper, AXIS_LETTER, DRIVER_ID, AXIS_ID> &st, const uint16_t mA, const uint16_t microsteps, const uint32_t thrs, const bool stealth) {
    TMC2208_n::GCONF_t gconf{0};
    gconf.pdn_disable = true; // Use UART
    gconf.mstep_reg_select = true; // Select microsteps with UART
    gconf.i_scale_analog = false;
    gconf.en_spreadcycle = !stealth;
    st.GCONF(gconf.sr);
    st.stored.stealthChop_enabled = stealth;

    TMC2208_n::CHOPCONF_t chopconf{0};
    chopconf.tbl = 0b01; // blank_time = 24
    chopconf.toff = chopper_timing.toff;
    chopconf.intpol = INTERPOLATE;
    chopconf.hend = chopper_timing.hend + 3;
    chopconf.hstrt = chopper_timing.hstrt - 1;
    #if ENABLED(SQUARE_WAVE_STEPPING)
      chopconf.dedge = true;
    #endif
    st.CHOPCONF(chopconf.sr);

    st.rms_current(mA, HOLD_MULTIPLIER);
    st.microsteps(microsteps);
    st.iholddelay(10);
    st.TPOWERDOWN(128); // ~2s until driver lowers to hold current

    TMC2208_n::PWMCONF_t pwmconf{0};
    pwmconf.pwm_lim = 12;
    pwmconf.pwm_reg = 8;
    pwmconf.pwm_autograd = true;
    pwmconf.pwm_autoscale = true;
    pwmconf.pwm_freq = 0b01;
    pwmconf.pwm_grad = 14;
    pwmconf.pwm_ofs = 36;
    st.PWMCONF(pwmconf.sr);

    #if ENABLED(HYBRID_THRESHOLD)
      st.set_pwm_thrs(thrs);
    #else
      UNUSED(thrs);
    #endif

    st.GSTAT(0b111); // Clear
    delay(200);
  }
#endif // TMC2208

#if HAS_DRIVER(TMC2209)
  template<char AXIS_LETTER, char DRIVER_ID, AxisEnum AXIS_ID>
  void tmc_init(TMCMarlin<TMC2209Stepper, AXIS_LETTER, DRIVER_ID, AXIS_ID> &st, const uint16_t mA, const uint16_t microsteps, const uint32_t thrs, const bool stealth) {
    TMC2208_n::GCONF_t gconf{0};
    gconf.pdn_disable = true; // Use UART
    gconf.mstep_reg_select = true; // Select microsteps with UART
    gconf.i_scale_analog = false;
    gconf.en_spreadcycle = !stealth;
    st.GCONF(gconf.sr);
    st.stored.stealthChop_enabled = stealth;

    TMC2208_n::CHOPCONF_t chopconf{0};
    chopconf.tbl = 0b01; // blank_time = 24
    chopconf.toff = chopper_timing.toff;
    chopconf.intpol = INTERPOLATE;
    chopconf.hend = chopper_timing.hend + 3;
    chopconf.hstrt = chopper_timing.hstrt - 1;
    #if ENABLED(SQUARE_WAVE_STEPPING)
      chopconf.dedge = true;
    #endif
    st.CHOPCONF(chopconf.sr);

    st.rms_current(mA, HOLD_MULTIPLIER);
    st.microsteps(microsteps);
    st.iholddelay(10);
    st.TPOWERDOWN(128); // ~2s until driver lowers to hold current

    TMC2208_n::PWMCONF_t pwmconf{0};
    pwmconf.pwm_lim = 12;
    pwmconf.pwm_reg = 8;
    pwmconf.pwm_autograd = true;
    pwmconf.pwm_autoscale = true;
    pwmconf.pwm_freq = 0b01;
    pwmconf.pwm_grad = 14;
    pwmconf.pwm_ofs = 36;
    st.PWMCONF(pwmconf.sr);

    #if ENABLED(HYBRID_THRESHOLD)
      st.set_pwm_thrs(thrs);
    #else
      UNUSED(thrs);
    #endif

    st.GSTAT(0b111); // Clear
    delay(200);
  }
#endif // TMC2209

#if HAS_DRIVER(TMC2660)
  template<char AXIS_LETTER, char DRIVER_ID, AxisEnum AXIS_ID>
  void tmc_init(TMCMarlin<TMC2660Stepper, AXIS_LETTER, DRIVER_ID, AXIS_ID> &st, const uint16_t mA, const uint16_t microsteps, const uint32_t, const bool) {
    st.begin();

    TMC2660_n::CHOPCONF_t chopconf{0};
    chopconf.tbl = 1;
    chopconf.toff = chopper_timing.toff;
    chopconf.hend = chopper_timing.hend + 3;
    chopconf.hstrt = chopper_timing.hstrt - 1;
    st.CHOPCONF(chopconf.sr);

    st.sdoff(0);
    st.rms_current(mA);
    st.microsteps(microsteps);
    #if ENABLED(SQUARE_WAVE_STEPPING)
      st.dedge(true);
    #endif
    st.intpol(INTERPOLATE);
    st.diss2g(true); // Disable short to ground protection. Too many false readings?

    #if ENABLED(TMC_DEBUG)
      st.rdsel(0b01);
    #endif
  }
#endif // TMC2660

#if HAS_DRIVER(TMC5130)
  template<char AXIS_LETTER, char DRIVER_ID, AxisEnum AXIS_ID>
  void tmc_init(TMCMarlin<TMC5130Stepper, AXIS_LETTER, DRIVER_ID, AXIS_ID> &st, const uint16_t mA, const uint16_t microsteps, const uint32_t thrs, const bool stealth) {
    st.begin();

    CHOPCONF_t chopconf{0};
    chopconf.tbl = 1;
    chopconf.toff = chopper_timing.toff;
    chopconf.intpol = INTERPOLATE;
    chopconf.hend = chopper_timing.hend + 3;
    chopconf.hstrt = chopper_timing.hstrt - 1;
    #if ENABLED(SQUARE_WAVE_STEPPING)
      chopconf.dedge = true;
    #endif
    st.CHOPCONF(chopconf.sr);

    st.rms_current(mA, HOLD_MULTIPLIER);
    st.microsteps(microsteps);
    st.iholddelay(10);
    st.TPOWERDOWN(128); // ~2s until driver lowers to hold current

    st.en_pwm_mode(stealth);
    st.stored.stealthChop_enabled = stealth;

    PWMCONF_t pwmconf{0};
    pwmconf.pwm_freq = 0b01; // f_pwm = 2/683 f_clk
    pwmconf.pwm_autoscale = true;
    pwmconf.pwm_grad = 5;
    pwmconf.pwm_ampl = 180;
    st.PWMCONF(pwmconf.sr);

    #if ENABLED(HYBRID_THRESHOLD)
      st.set_pwm_thrs(thrs);
    #else
      UNUSED(thrs);
    #endif

    st.GSTAT(); // Clear GSTAT
  }
#endif // TMC5130

#if HAS_DRIVER(TMC5160)
  template<char AXIS_LETTER, char DRIVER_ID, AxisEnum AXIS_ID>
  void tmc_init(TMCMarlin<TMC5160Stepper, AXIS_LETTER, DRIVER_ID, AXIS_ID> &st, const uint16_t mA, const uint16_t microsteps, const uint32_t thrs, const bool stealth) {
    st.begin();

    CHOPCONF_t chopconf{0};
    chopconf.tbl = 1;
    chopconf.toff = chopper_timing.toff;
    chopconf.intpol = INTERPOLATE;
    chopconf.hend = chopper_timing.hend + 3;
    chopconf.hstrt = chopper_timing.hstrt - 1;
    #if ENABLED(SQUARE_WAVE_STEPPING)
      chopconf.dedge = true;
    #endif
    st.CHOPCONF(chopconf.sr);

    st.rms_current(mA, HOLD_MULTIPLIER);
    st.microsteps(microsteps);
    st.iholddelay(10);
    st.TPOWERDOWN(128); // ~2s until driver lowers to hold current

    st.en_pwm_mode(stealth);
    st.stored.stealthChop_enabled = stealth;

    TMC2160_n::PWMCONF_t pwmconf{0};
    pwmconf.pwm_lim = 12;
    pwmconf.pwm_reg = 8;
    pwmconf.pwm_autograd = true;
    pwmconf.pwm_autoscale = true;
    pwmconf.pwm_freq = 0b01;
    pwmconf.pwm_grad = 14;
    pwmconf.pwm_ofs = 36;
    st.PWMCONF(pwmconf.sr);

    #if ENABLED(HYBRID_THRESHOLD)
      st.set_pwm_thrs(thrs);
    #else
      UNUSED(thrs);
    #endif
    st.GSTAT(); // Clear GSTAT
  }
#endif // TMC5160

void restore_trinamic_drivers() {
  #if AXIS_IS_TMC(X)
    stepperX.push();
  #endif
  #if AXIS_IS_TMC(X2)
    stepperX2.push();
  #endif
  #if AXIS_IS_TMC(Y)
    stepperY.push();
  #endif
  #if AXIS_IS_TMC(Y2)
    stepperY2.push();
  #endif
  #if AXIS_IS_TMC(Z)
    stepperZ.push();
  #endif
  #if AXIS_IS_TMC(Z2)
    stepperZ2.push();
  #endif
  #if AXIS_IS_TMC(Z3)
    stepperZ3.push();
  #endif
  #if AXIS_IS_TMC(Z4)
    stepperZ4.push();
  #endif
  #if AXIS_IS_TMC(E0)
    stepperE0.push();
  #endif
  #if AXIS_IS_TMC(E1)
    stepperE1.push();
  #endif
  #if AXIS_IS_TMC(E2)
    stepperE2.push();
  #endif
  #if AXIS_IS_TMC(E3)
    stepperE3.push();
  #endif
  #if AXIS_IS_TMC(E4)
    stepperE4.push();
  #endif
  #if AXIS_IS_TMC(E5)
    stepperE5.push();
  #endif
  #if AXIS_IS_TMC(E6)
    stepperE6.push();
  #endif
  #if AXIS_IS_TMC(E7)
    stepperE7.push();
  #endif
}

void reset_trinamic_drivers() {
  static constexpr bool stealthchop_by_axis[] = {
    #if ENABLED(STEALTHCHOP_XY)
      true
    #else
      false
    #endif
    ,
    #if ENABLED(STEALTHCHOP_Z)
      true
    #else
      false
    #endif
    ,
    #if ENABLED(STEALTHCHOP_E)
      true
    #else
      false
    #endif
  };

  #if AXIS_IS_TMC(X)
    _TMC_INIT(X, STEALTH_AXIS_XY);
  #endif
  #if AXIS_IS_TMC(X2)
    _TMC_INIT(X2, STEALTH_AXIS_XY);
  #endif
  #if AXIS_IS_TMC(Y)
    _TMC_INIT(Y, STEALTH_AXIS_XY);
  #endif
  #if AXIS_IS_TMC(Y2)
    _TMC_INIT(Y2, STEALTH_AXIS_XY);
  #endif
  #if AXIS_IS_TMC(Z)
    _TMC_INIT(Z, STEALTH_AXIS_Z);
  #endif
  #if AXIS_IS_TMC(Z2)
    _TMC_INIT(Z2, STEALTH_AXIS_Z);
  #endif
  #if AXIS_IS_TMC(Z3)
    _TMC_INIT(Z3, STEALTH_AXIS_Z);
  #endif
  #if AXIS_IS_TMC(Z4)
    _TMC_INIT(Z4, STEALTH_AXIS_Z);
  #endif
  #if AXIS_IS_TMC(E0)
    _TMC_INIT(E0, STEALTH_AXIS_E);
  #endif
  #if AXIS_IS_TMC(E1)
    _TMC_INIT(E1, STEALTH_AXIS_E);
  #endif
  #if AXIS_IS_TMC(E2)
    _TMC_INIT(E2, STEALTH_AXIS_E);
  #endif
  #if AXIS_IS_TMC(E3)
    _TMC_INIT(E3, STEALTH_AXIS_E);
  #endif
  #if AXIS_IS_TMC(E4)
    _TMC_INIT(E4, STEALTH_AXIS_E);
  #endif
  #if AXIS_IS_TMC(E5)
    _TMC_INIT(E5, STEALTH_AXIS_E);
  #endif
  #if AXIS_IS_TMC(E6)
    _TMC_INIT(E6, STEALTH_AXIS_E);
  #endif
  #if AXIS_IS_TMC(E7)
    _TMC_INIT(E7, STEALTH_AXIS_E);
  #endif

  #if USE_SENSORLESS
    #if X_SENSORLESS
      #if AXIS_HAS_STALLGUARD(X)
        stepperX.homing_threshold(X_STALL_SENSITIVITY);
      #endif
      #if AXIS_HAS_STALLGUARD(X2) && !X2_SENSORLESS
        stepperX2.homing_threshold(X_STALL_SENSITIVITY);
      #endif
    #endif
    #if X2_SENSORLESS
      stepperX2.homing_threshold(X2_STALL_SENSITIVITY);
    #endif
    #if Y_SENSORLESS
      #if AXIS_HAS_STALLGUARD(Y)
        stepperY.homing_threshold(Y_STALL_SENSITIVITY);
      #endif
      #if AXIS_HAS_STALLGUARD(Y2)
        stepperY2.homing_threshold(Y_STALL_SENSITIVITY);
      #endif
    #endif
    #if Z_SENSORLESS
      #if AXIS_HAS_STALLGUARD(Z)
        stepperZ.homing_threshold(Z_STALL_SENSITIVITY);
      #endif
      #if AXIS_HAS_STALLGUARD(Z2)
        stepperZ2.homing_threshold(Z_STALL_SENSITIVITY);
      #endif
      #if AXIS_HAS_STALLGUARD(Z3)
        stepperZ3.homing_threshold(Z_STALL_SENSITIVITY);
      #endif
      #if AXIS_HAS_STALLGUARD(Z4)
        stepperZ4.homing_threshold(Z_STALL_SENSITIVITY);
      #endif
    #endif
  #endif

  #ifdef TMC_ADV
    TMC_ADV()
  #endif

  stepper.set_directions();
}

#endif // HAS_TRINAMIC