/** * Marlin 3D Printer Firmware * Copyright (c) 2020 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 . * */ // // NOTE: All tests assume each axis uses matching driver chips. // #include "../../../inc/MarlinConfig.h" #if HAS_L64XX #include "../../gcode.h" #include "../../../module/stepper/indirection.h" #include "../../../module/planner.h" #include "../../../libs/L64XX/L64XX_Marlin.h" #define DEBUG_OUT ENABLED(L6470_CHITCHAT) #include "../../../core/debug_out.h" /** * M916: increase KVAL_HOLD until get thermal warning * NOTE - on L6474 it is TVAL that is used * * J - select which driver(s) to monitor on multi-driver axis * 0 - (default) monitor all drivers on the axis or E0 * 1 - monitor only X, Y, Z, E1 * 2 - monitor only X2, Y2, Z2, E2 * 3 - monitor only Z3, E3 * 4 - monitor only Z4, E4 * * Xxxx, Yxxx, Zxxx, Exxx - axis to be monitored with displacement * xxx (1-255) is distance moved on either side of current position * * F - feedrate * optional - will use default max feedrate from configuration.h if not specified * * T - current (mA) setting for TVAL (0 - 4A in 31.25mA increments, rounds down) - L6474 only * optional - will report current value from driver if not specified * * K - value for KVAL_HOLD (0 - 255) (ignored for L6474) * optional - will report current value from driver if not specified * * D - time (in seconds) to run each setting of KVAL_HOLD/TVAL * optional - defaults to zero (runs each setting once) */ /** * This routine is also useful for determining the approximate KVAL_HOLD * where the stepper stops losing steps. The sound will get noticeably quieter * as it stops losing steps. */ void GcodeSuite::M916() { DEBUG_ECHOLNPGM("M916"); L64xxManager.pause_monitor(true); // Keep monitor_driver() from stealing status // Variables used by L64xxManager.get_user_input function - some may not be used char axis_mon[3][3] = { {" "}, {" "}, {" "} }; // list of Axes to be monitored L64XX_axis_t axis_index[3]; uint16_t axis_status[3]; uint8_t driver_count = 1; float position_max; float position_min; float final_feedrate; uint8_t kval_hold; uint8_t OCD_TH_val = 0; uint8_t STALL_TH_val = 0; uint16_t over_current_threshold; constexpr uint8_t over_current_flag = false; // M916 doesn't play with the overcurrent thresholds #define DRIVER_TYPE_L6474(Q) AXIS_DRIVER_TYPE_##Q(L6474) uint8_t j; // general purpose counter if (L64xxManager.get_user_input(driver_count, axis_index, axis_mon, position_max, position_min, final_feedrate, kval_hold, over_current_flag, OCD_TH_val, STALL_TH_val, over_current_threshold)) return; // quit if invalid user input DEBUG_ECHOLNPGM("feedrate = ", final_feedrate); planner.synchronize(); // wait for all current movement commands to complete const L64XX_Marlin::L64XX_shadow_t &sh = L64xxManager.shadow; for (j = 0; j < driver_count; j++) L64xxManager.get_status(axis_index[j]); // clear out any pre-existing error flags char temp_axis_string[] = " "; temp_axis_string[0] = axis_mon[0][0]; // need to have a string for use within sprintf format section char gcode_string[80]; uint16_t status_composite = 0; uint16_t M91x_counter = kval_hold; uint16_t M91x_counter_max; if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) { M91x_counter_max = 128; // TVAL is 7 bits LIMIT(M91x_counter, 0U, 127U); } else M91x_counter_max = 256; // KVAL_HOLD is 8 bits uint8_t M91x_delay_s = parser.byteval('D'); // get delay in seconds millis_t M91x_delay_ms = SEC_TO_MS(M91x_delay_s * 60); millis_t M91x_delay_end; DEBUG_ECHOLNPGM(".\n."); do { if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) DEBUG_ECHOLNPGM("TVAL current (mA) = ", (M91x_counter + 1) * sh.AXIS_STALL_CURRENT_CONSTANT_INV); // report TVAL current for this run else DEBUG_ECHOLNPGM("kval_hold = ", M91x_counter); // report KVAL_HOLD for this run for (j = 0; j < driver_count; j++) L64xxManager.set_param(axis_index[j], L6470_KVAL_HOLD, M91x_counter); //set KVAL_HOLD or TVAL (same register address) M91x_delay_end = millis() + M91x_delay_ms; do { // turn the motor(s) both directions sprintf_P(gcode_string, PSTR("G0 %s%03d F%03d"), temp_axis_string, uint16_t(position_min), uint16_t(final_feedrate)); process_subcommands_now(gcode_string); sprintf_P(gcode_string, PSTR("G0 %s%03d F%03d"), temp_axis_string, uint16_t(position_max), uint16_t(final_feedrate)); process_subcommands_now(gcode_string); // get the status after the motors have stopped planner.synchronize(); status_composite = 0; // clear out the old bits for (j = 0; j < driver_count; j++) { axis_status[j] = (~L64xxManager.get_status(axis_index[j])) & sh.L6470_ERROR_MASK; // bits of interest are all active low status_composite |= axis_status[j] ; } if (status_composite) break; } while (millis() < M91x_delay_end); if (status_composite) break; M91x_counter++; } while (!(status_composite & (sh.STATUS_AXIS_TH_WRN | sh.STATUS_AXIS_TH_SD)) && (M91x_counter < M91x_counter_max)); DEBUG_ECHOLNPGM("."); #if ENABLED(L6470_CHITCHAT) if (status_composite) { L64xxManager.error_status_decode(status_composite, axis_index[0], sh.STATUS_AXIS_TH_SD, sh.STATUS_AXIS_TH_WRN, sh.STATUS_AXIS_STEP_LOSS_A, sh.STATUS_AXIS_STEP_LOSS_B, sh.STATUS_AXIS_OCD, sh.STATUS_AXIS_LAYOUT); DEBUG_ECHOLNPGM("."); } #endif if ((status_composite & (sh.STATUS_AXIS_TH_WRN | sh.STATUS_AXIS_TH_SD))) DEBUG_ECHOLNPGM(".\n.\nTest completed normally - Thermal warning/shutdown has occurred"); else if (status_composite) DEBUG_ECHOLNPGM(".\n.\nTest completed abnormally - non-thermal error has occurred"); else DEBUG_ECHOLNPGM(".\n.\nTest completed normally - Unable to get to thermal warning/shutdown"); L64xxManager.pause_monitor(false); } /** * M917: Find minimum current thresholds * * Decrease OCD current until overcurrent error * Increase OCD until overcurrent error goes away * Decrease stall threshold until stall (not done on L6474) * Increase stall until stall error goes away (not done on L6474) * * J - select which driver(s) to monitor on multi-driver axis * 0 - (default) monitor all drivers on the axis or E0 * 1 - monitor only X, Y, Z, E1 * 2 - monitor only X2, Y2, Z2, E2 * Xxxx, Yxxx, Zxxx, Exxx - axis to be monitored with displacement * xxx (1-255) is distance moved on either side of current position * * F - feedrate * optional - will use default max feedrate from Configuration.h if not specified * * I - starting over-current threshold * optional - will report current value from driver if not specified * if there are multiple drivers on the axis then all will be set the same * * T - current (mA) setting for TVAL (0 - 4A in 31.25mA increments, rounds down) - L6474 only * optional - will report current value from driver if not specified * * K - value for KVAL_HOLD (0 - 255) (ignored for L6474) * optional - will report current value from driver if not specified */ void GcodeSuite::M917() { DEBUG_ECHOLNPGM("M917"); L64xxManager.pause_monitor(true); // Keep monitor_driver() from stealing status char axis_mon[3][3] = { {" "}, {" "}, {" "} }; // list of Axes to be monitored L64XX_axis_t axis_index[3]; uint16_t axis_status[3]; uint8_t driver_count = 1; float position_max; float position_min; float final_feedrate; uint8_t kval_hold; uint8_t OCD_TH_val = 0; uint8_t STALL_TH_val = 0; uint16_t over_current_threshold; constexpr uint8_t over_current_flag = true; uint8_t j; // general purpose counter if (L64xxManager.get_user_input(driver_count, axis_index, axis_mon, position_max, position_min, final_feedrate, kval_hold, over_current_flag, OCD_TH_val, STALL_TH_val, over_current_threshold)) return; // quit if invalid user input DEBUG_ECHOLNPGM("feedrate = ", final_feedrate); planner.synchronize(); // wait for all current movement commands to complete const L64XX_Marlin::L64XX_shadow_t &sh = L64xxManager.shadow; for (j = 0; j < driver_count; j++) L64xxManager.get_status(axis_index[j]); // clear error flags char temp_axis_string[] = " "; temp_axis_string[0] = axis_mon[0][0]; // need a sprintf format string char gcode_string[80]; uint16_t status_composite = 0; uint8_t test_phase = 0; // 0 - decreasing OCD - exit when OCD warning occurs (ignore STALL) // 1 - increasing OCD - exit when OCD warning stops (ignore STALL) // 2 - OCD finalized - decreasing STALL - exit when STALL warning happens // 3 - OCD finalized - increasing STALL - exit when STALL warning stop // 4 - all testing completed DEBUG_ECHOPGM(".\n.\n.\nover_current threshold : ", (OCD_TH_val + 1) * 375); // first status display DEBUG_ECHOPGM(" (OCD_TH: : ", OCD_TH_val); if (sh.STATUS_AXIS_LAYOUT != L6474_STATUS_LAYOUT) { DEBUG_ECHOPGM(") Stall threshold: ", (STALL_TH_val + 1) * 31.25); DEBUG_ECHOPGM(" (STALL_TH: ", STALL_TH_val); } DEBUG_ECHOLNPGM(")"); do { if (sh.STATUS_AXIS_LAYOUT != L6474_STATUS_LAYOUT) DEBUG_ECHOPGM("STALL threshold : ", (STALL_TH_val + 1) * 31.25); DEBUG_ECHOLNPGM(" OCD threshold : ", (OCD_TH_val + 1) * 375); sprintf_P(gcode_string, PSTR("G0 %s%03d F%03d"), temp_axis_string, uint16_t(position_min), uint16_t(final_feedrate)); process_subcommands_now(gcode_string); sprintf_P(gcode_string, PSTR("G0 %s%03d F%03d"), temp_axis_string, uint16_t(position_max), uint16_t(final_feedrate)); process_subcommands_now(gcode_string); planner.synchronize(); status_composite = 0; // clear out the old bits for (j = 0; j < driver_count; j++) { axis_status[j] = (~L64xxManager.get_status(axis_index[j])) & sh.L6470_ERROR_MASK; // bits of interest are all active low status_composite |= axis_status[j]; } if (status_composite && (status_composite & sh.STATUS_AXIS_UVLO)) { DEBUG_ECHOLNPGM("Test aborted (Undervoltage lockout active)"); #if ENABLED(L6470_CHITCHAT) for (j = 0; j < driver_count; j++) { if (j) DEBUG_ECHOPGM("..."); L64xxManager.error_status_decode(axis_status[j], axis_index[j], sh.STATUS_AXIS_TH_SD, sh.STATUS_AXIS_TH_WRN, sh.STATUS_AXIS_STEP_LOSS_A, sh.STATUS_AXIS_STEP_LOSS_B, sh.STATUS_AXIS_OCD, sh.STATUS_AXIS_LAYOUT); } #endif return; } if (status_composite & (sh.STATUS_AXIS_TH_WRN | sh.STATUS_AXIS_TH_SD)) { DEBUG_ECHOLNPGM("thermal problem - waiting for chip(s) to cool down "); uint16_t status_composite_temp = 0; uint8_t k = 0; do { k++; if (!(k % 4)) { kval_hold *= 0.95; DEBUG_EOL(); DEBUG_ECHOLNPGM("Lowering KVAL_HOLD by about 5% to ", kval_hold); for (j = 0; j < driver_count; j++) L64xxManager.set_param(axis_index[j], L6470_KVAL_HOLD, kval_hold); } DEBUG_ECHOLNPGM("."); reset_stepper_timeout(); // keep steppers powered watchdog_refresh(); safe_delay(5000); status_composite_temp = 0; for (j = 0; j < driver_count; j++) { axis_status[j] = (~L64xxManager.get_status(axis_index[j])) & sh.L6470_ERROR_MASK; // bits of interest are all active low status_composite_temp |= axis_status[j]; } } while (status_composite_temp & (sh.STATUS_AXIS_TH_WRN | sh.STATUS_AXIS_TH_SD)); DEBUG_EOL(); } if (status_composite & (sh.STATUS_AXIS_STEP_LOSS_A | sh.STATUS_AXIS_STEP_LOSS_B | sh.STATUS_AXIS_OCD)) { switch (test_phase) { case 0: { if (status_composite & sh.STATUS_AXIS_OCD) { // phase 0 with OCD warning - time to go to next phase if (OCD_TH_val >= sh.AXIS_OCD_TH_MAX) { OCD_TH_val = sh.AXIS_OCD_TH_MAX; // limit to max test_phase = 2; // at highest value so skip phase 1 //DEBUG_ECHOLNPGM("LOGIC E0A OCD at highest - skip to 2"); DEBUG_ECHOLNPGM("OCD at highest - OCD finalized"); } else { OCD_TH_val++; // normal exit to next phase test_phase = 1; // setup for first pass of phase 1 //DEBUG_ECHOLNPGM("LOGIC E0B - inc OCD & go to 1"); DEBUG_ECHOLNPGM("inc OCD"); } } else { // phase 0 without OCD warning - keep on decrementing if can if (OCD_TH_val) { OCD_TH_val--; // try lower value //DEBUG_ECHOLNPGM("LOGIC E0C - dec OCD"); DEBUG_ECHOLNPGM("dec OCD"); } else { test_phase = 2; // at lowest value without warning so skip phase 1 //DEBUG_ECHOLNPGM("LOGIC E0D - OCD at latest - go to 2"); DEBUG_ECHOLNPGM("OCD finalized"); } } } break; case 1: { if (status_composite & sh.STATUS_AXIS_OCD) { // phase 1 with OCD warning - increment if can if (OCD_TH_val >= sh.AXIS_OCD_TH_MAX) { OCD_TH_val = sh.AXIS_OCD_TH_MAX; // limit to max test_phase = 2; // at highest value so go to next phase //DEBUG_ECHOLNPGM("LOGIC E1A - OCD at max - go to 2"); DEBUG_ECHOLNPGM("OCD finalized"); } else { OCD_TH_val++; // try a higher value //DEBUG_ECHOLNPGM("LOGIC E1B - inc OCD"); DEBUG_ECHOLNPGM("inc OCD"); } } else { // phase 1 without OCD warning - normal exit to phase 2 test_phase = 2; //DEBUG_ECHOLNPGM("LOGIC E1C - no OCD warning - go to 1"); DEBUG_ECHOLNPGM("OCD finalized"); } } break; case 2: { if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) { // skip all STALL_TH steps if L6474 test_phase = 4; break; } if (status_composite & (sh.STATUS_AXIS_STEP_LOSS_A | sh.STATUS_AXIS_STEP_LOSS_B)) { // phase 2 with stall warning - time to go to next phase if (STALL_TH_val >= 127) { STALL_TH_val = 127; // limit to max //DEBUG_ECHOLNPGM("LOGIC E2A - STALL warning, STALL at max, quit"); DEBUG_ECHOLNPGM("finished - STALL at maximum value but still have stall warning"); test_phase = 4; } else { test_phase = 3; // normal exit to next phase (found failing value of STALL) STALL_TH_val++; // setup for first pass of phase 3 //DEBUG_ECHOLNPGM("LOGIC E2B - INC - STALL warning, inc Stall, go to 3"); DEBUG_ECHOLNPGM("inc Stall"); } } else { // phase 2 without stall warning - decrement if can if (STALL_TH_val) { STALL_TH_val--; // try a lower value //DEBUG_ECHOLNPGM("LOGIC E2C - no STALL, dec STALL"); DEBUG_ECHOLNPGM("dec STALL"); } else { DEBUG_ECHOLNPGM("finished - STALL at lowest value but still do NOT have stall warning"); test_phase = 4; //DEBUG_ECHOLNPGM("LOGIC E2D - no STALL, at lowest so quit"); } } } break; case 3: { if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) { // skip all STALL_TH steps if L6474 test_phase = 4; break; } if (status_composite & (sh.STATUS_AXIS_STEP_LOSS_A | sh.STATUS_AXIS_STEP_LOSS_B)) { // phase 3 with stall warning - increment if can if (STALL_TH_val >= 127) { STALL_TH_val = 127; // limit to max DEBUG_ECHOLNPGM("finished - STALL at maximum value but still have stall warning"); test_phase = 4; //DEBUG_ECHOLNPGM("LOGIC E3A - STALL, at max so quit"); } else { STALL_TH_val++; // still looking for passing value //DEBUG_ECHOLNPGM("LOGIC E3B - STALL, inc stall"); DEBUG_ECHOLNPGM("inc stall"); } } else { //phase 3 without stall warning but have OCD warning DEBUG_ECHOLNPGM("Hardware problem - OCD warning without STALL warning"); test_phase = 4; //DEBUG_ECHOLNPGM("LOGIC E3C - not STALLED, hardware problem (quit)"); } } break; } } else { switch (test_phase) { case 0: { // phase 0 without OCD warning - keep on decrementing if can if (OCD_TH_val) { OCD_TH_val--; // try lower value //DEBUG_ECHOLNPGM("LOGIC N0A - DEC OCD"); DEBUG_ECHOLNPGM("DEC OCD"); } else { test_phase = 2; // at lowest value without warning so skip phase 1 //DEBUG_ECHOLNPGM("LOGIC N0B - OCD at lowest (go to phase 2)"); DEBUG_ECHOLNPGM("OCD finalized"); } } break; case 1: //DEBUG_ECHOLNPGM("LOGIC N1 (go directly to 2)"); // phase 1 without OCD warning - drop directly to phase 2 DEBUG_ECHOLNPGM("OCD finalized"); case 2: { // phase 2 without stall warning - keep on decrementing if can if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) { // skip all STALL_TH steps if L6474 test_phase = 4; break; } if (STALL_TH_val) { STALL_TH_val--; // try a lower value (stay in phase 2) //DEBUG_ECHOLNPGM("LOGIC N2B - dec STALL"); DEBUG_ECHOLNPGM("dec STALL"); } else { DEBUG_ECHOLNPGM("finished - STALL at lowest value but still no stall warning"); test_phase = 4; //DEBUG_ECHOLNPGM("LOGIC N2C - STALL at lowest (quit)"); } } break; case 3: { if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) { // skip all STALL_TH steps if L6474 test_phase = 4; break; } test_phase = 4; //DEBUG_ECHOLNPGM("LOGIC N3 - finished!"); DEBUG_ECHOLNPGM("finished!"); } break; // phase 3 without any warnings - desired exit } // } // end of status checks if (test_phase != 4) { for (j = 0; j < driver_count; j++) { // update threshold(s) L64xxManager.set_param(axis_index[j], L6470_OCD_TH, OCD_TH_val); if (sh.STATUS_AXIS_LAYOUT != L6474_STATUS_LAYOUT) L64xxManager.set_param(axis_index[j], L6470_STALL_TH, STALL_TH_val); if (L64xxManager.get_param(axis_index[j], L6470_OCD_TH) != OCD_TH_val) DEBUG_ECHOLNPGM("OCD mismatch"); if ((L64xxManager.get_param(axis_index[j], L6470_STALL_TH) != STALL_TH_val) && (sh.STATUS_AXIS_LAYOUT != L6474_STATUS_LAYOUT)) DEBUG_ECHOLNPGM("STALL mismatch"); } } } while (test_phase != 4); DEBUG_ECHOLNPGM("."); if (status_composite) { #if ENABLED(L6470_CHITCHAT) for (j = 0; j < driver_count; j++) { if (j) DEBUG_ECHOPGM("..."); L64xxManager.error_status_decode(axis_status[j], axis_index[j], sh.STATUS_AXIS_TH_SD, sh.STATUS_AXIS_TH_WRN, sh.STATUS_AXIS_STEP_LOSS_A, sh.STATUS_AXIS_STEP_LOSS_B, sh.STATUS_AXIS_OCD, sh.STATUS_AXIS_LAYOUT); } DEBUG_ECHOLNPGM("."); #endif DEBUG_ECHOLNPGM("Completed with errors"); } else DEBUG_ECHOLNPGM("Completed with no errors"); DEBUG_ECHOLNPGM("."); L64xxManager.pause_monitor(false); } /** * M918: increase speed until error or max feedrate achieved (as shown in configuration.h)) * * J - select which driver(s) to monitor on multi-driver axis * 0 - (default) monitor all drivers on the axis or E0 * 1 - monitor only X, Y, Z, E1 * 2 - monitor only X2, Y2, Z2, E2 * Xxxx, Yxxx, Zxxx, Exxx - axis to be monitored with displacement * xxx (1-255) is distance moved on either side of current position * * I - over current threshold * optional - will report current value from driver if not specified * * T - current (mA) setting for TVAL (0 - 4A in 31.25mA increments, rounds down) - L6474 only * optional - will report current value from driver if not specified * * K - value for KVAL_HOLD (0 - 255) (ignored for L6474) * optional - will report current value from driver if not specified * * M - value for microsteps (1 - 128) (optional) * optional - will report current value from driver if not specified */ void GcodeSuite::M918() { DEBUG_ECHOLNPGM("M918"); L64xxManager.pause_monitor(true); // Keep monitor_driver() from stealing status char axis_mon[3][3] = { {" "}, {" "}, {" "} }; // list of Axes to be monitored L64XX_axis_t axis_index[3]; uint16_t axis_status[3]; uint8_t driver_count = 1; float position_max, position_min; float final_feedrate; uint8_t kval_hold; uint8_t OCD_TH_val = 0; uint8_t STALL_TH_val = 0; uint16_t over_current_threshold; constexpr uint8_t over_current_flag = true; const L64XX_Marlin::L64XX_shadow_t &sh = L64xxManager.shadow; uint8_t j; // general purpose counter if (L64xxManager.get_user_input(driver_count, axis_index, axis_mon, position_max, position_min, final_feedrate, kval_hold, over_current_flag, OCD_TH_val, STALL_TH_val, over_current_threshold)) return; // quit if invalid user input L64xxManager.get_status(axis_index[0]); // populate shadow array uint8_t m_steps = parser.byteval('M'); if (m_steps != 0) { LIMIT(m_steps, 1, sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT ? 16 : 128); // L6474 uint8_t stepVal; for (stepVal = 0; stepVal < 8; stepVal++) { // convert to L64xx register value if (m_steps == 1) break; m_steps >>= 1; } if (sh.STATUS_AXIS_LAYOUT == L6474_STATUS_LAYOUT) stepVal |= 0x98; // NO SYNC else stepVal |= (!SYNC_EN) | SYNC_SEL_1 | stepVal; for (j = 0; j < driver_count; j++) { L64xxManager.set_param(axis_index[j], dSPIN_HARD_HIZ, 0); // can't write STEP register if stepper being powered // results in an extra NOOP being sent (data 00) L64xxManager.set_param(axis_index[j], L6470_STEP_MODE, stepVal); // set microsteps } } m_steps = L64xxManager.get_param(axis_index[0], L6470_STEP_MODE) & 0x07; // get microsteps DEBUG_ECHOLNPGM("Microsteps = ", _BV(m_steps)); DEBUG_ECHOLNPGM("target (maximum) feedrate = ", final_feedrate); const float feedrate_inc = final_feedrate / 10, // Start at 1/10 of max & go up by 1/10 per step fr_limit = final_feedrate * 0.99f; // Rounding-safe comparison value float current_feedrate = 0; planner.synchronize(); // Wait for moves to complete for (j = 0; j < driver_count; j++) L64xxManager.get_status(axis_index[j]); // Clear error flags char temp_axis_string[2] = " "; temp_axis_string[0] = axis_mon[0][0]; // Need a sprintf format string //temp_axis_string[1] = '\n'; char gcode_string[80]; uint16_t status_composite = 0; DEBUG_ECHOLNPGM(".\n.\n."); // Make feedrate outputs easier to read do { current_feedrate += feedrate_inc; DEBUG_ECHOLNPGM("...feedrate = ", current_feedrate); sprintf_P(gcode_string, PSTR("G0 %s%03d F%03d"), temp_axis_string, uint16_t(position_min), uint16_t(current_feedrate)); process_subcommands_now(gcode_string); sprintf_P(gcode_string, PSTR("G0 %s%03d F%03d"), temp_axis_string, uint16_t(position_max), uint16_t(current_feedrate)); process_subcommands_now(gcode_string); planner.synchronize(); for (j = 0; j < driver_count; j++) { axis_status[j] = (~L64xxManager.get_status(axis_index[j])) & 0x0800; // Bits of interest are all active LOW status_composite |= axis_status[j]; } if (status_composite) break; // Break on any error } while (current_feedrate < fr_limit); DEBUG_ECHOPGM("Completed with "); if (status_composite) { DEBUG_ECHOLNPGM("errors"); #if ENABLED(L6470_CHITCHAT) for (j = 0; j < driver_count; j++) { if (j) DEBUG_ECHOPGM("..."); L64xxManager.error_status_decode(axis_status[j], axis_index[j], sh.STATUS_AXIS_TH_SD, sh.STATUS_AXIS_TH_WRN, sh.STATUS_AXIS_STEP_LOSS_A, sh.STATUS_AXIS_STEP_LOSS_B, sh.STATUS_AXIS_OCD, sh.STATUS_AXIS_LAYOUT); } #endif } else DEBUG_ECHOLNPGM("no errors"); L64xxManager.pause_monitor(false); } #endif // HAS_L64XX