#include "mmu2.h" #include "mmu2_config.h" #include "mmu2_error_converter.h" #include "mmu2_fsensor.h" #include "mmu2_log.h" #include "mmu2_power.h" #include "mmu2_progress_converter.h" #include "mmu2_reporting.h" #include "Marlin.h" #include "language.h" #include "messages.h" #include "sound.h" #include "stepper.h" #include "strlen_cx.h" #include "temperature.h" #include "ultralcd.h" #include "SpoolJoin.h" // As of FW 3.12 we only support building the FW with only one extruder, all the multi-extruder infrastructure will be removed. // Saves at least 800B of code size static_assert(EXTRUDERS==1); namespace MMU2 { void execute_extruder_sequence(const E_Step *sequence, int steps); template void waitForHotendTargetTemp(uint16_t delay, F f){ while (((degTargetHotend(active_extruder) - degHotend(active_extruder)) > 5)) { f(); delay_keep_alive(delay); } } void WaitForHotendTargetTempBeep(){ waitForHotendTargetTemp(3000, []{ Sound_MakeSound(e_SOUND_TYPE_StandardPrompt); } ); } MMU2 mmu2; MMU2::MMU2() : is_mmu_error_monitor_active(false) , logic(&mmu2Serial, MMU2_TOOL_CHANGE_LOAD_LENGTH) , extruder(MMU2_NO_TOOL) , tool_change_extruder(MMU2_NO_TOOL) , resume_position() , resume_hotend_temp(0) , logicStepLastStatus(StepStatus::Finished) , state(xState::Stopped) , mmu_print_saved(SavedState::None) , loadFilamentStarted(false) , unloadFilamentStarted(false) , loadingToNozzle(false) , inAutoRetry(false) , retryAttempts(MAX_RETRIES) , toolchange_counter(0) , tmcFailures(0) { } void MMU2::Start() { #ifdef MMU_HWRESET WRITE(MMU_RST_PIN, 1); SET_OUTPUT(MMU_RST_PIN); // setup reset pin #endif //MMU_HWRESET mmu2Serial.begin(MMU_BAUD); PowerOn(); // I repurposed this to serve as our EEPROM disable toggle. Reset(ResetForm::ResetPin); mmu2Serial.flush(); // make sure the UART buffer is clear before starting communication extruder = MMU2_NO_TOOL; state = xState::Connecting; // start the communication logic.Start(); ResetRetryAttempts(); } void MMU2::Stop() { StopKeepPowered(); PowerOff(); // This also disables the MMU in the EEPROM. } void MMU2::StopKeepPowered(){ state = xState::Stopped; logic.Stop(); mmu2Serial.close(); } void MMU2::Reset(ResetForm level){ switch (level) { case Software: ResetX0(); break; case ResetPin: TriggerResetPin(); break; case CutThePower: PowerCycle(); break; default: break; } } void MMU2::ResetX0() { logic.ResetMMU(); // Send soft reset } void MMU2::TriggerResetPin(){ reset(); } void MMU2::PowerCycle(){ // cut the power to the MMU and after a while restore it // Sadly, MK3/S/+ cannot do this // NOTE: the below will toggle the EEPROM var. Should we // assert this function is never called in the MK3 FW? Do we even care? PowerOff(); delay_keep_alive(1000); PowerOn(); } void MMU2::PowerOff(){ power_off(); } void MMU2::PowerOn(){ power_on(); } bool MMU2::ReadRegister(uint8_t address){ if( ! WaitForMMUReady()) return false; do { logic.ReadRegister(address); // we may signal the accepted/rejected status of the response as return value of this function } while( ! manage_response(false, false) ); return true; } bool MMU2::WriteRegister(uint8_t address, uint16_t data){ if( ! WaitForMMUReady()) return false; // special case - intercept requests of extra loading distance and perform the change even on the printer's side if( address == 0x0b ){ logic.PlanExtraLoadDistance(data); } do { logic.WriteRegister(address, data); // we may signal the accepted/rejected status of the response as return value of this function } while( ! manage_response(false, false) ); return true; } void MMU2::mmu_loop() { // We only leave this method if the current command was successfully completed - that's the Marlin's way of blocking operation // Atomic compare_exchange would have been the most appropriate solution here, but this gets called only in Marlin's task, // so thread safety should be kept static bool avoidRecursion = false; if (avoidRecursion) return; avoidRecursion = true; mmu_loop_inner(true); avoidRecursion = false; } void __attribute__((noinline)) MMU2::mmu_loop_inner(bool reportErrors) { logicStepLastStatus = LogicStep(reportErrors); // it looks like the mmu_loop doesn't need to be a blocking call if (is_mmu_error_monitor_active) { // Call this every iteration to keep the knob rotation responsive // This includes when mmu_loop is called within manage_response ReportErrorHook((uint16_t)lastErrorCode); } } void MMU2::CheckFINDARunout() { // Check for FINDA filament runout if (!FindaDetectsFilament() && check_fsensor()) { SERIAL_ECHOLNPGM("FINDA filament runout!"); stop_and_save_print_to_ram(0, 0); restore_print_from_ram_and_continue(0); if (SpoolJoin::spooljoin.isSpoolJoinEnabled() && get_current_tool() != (uint8_t)FILAMENT_UNKNOWN){ // Can't auto if F=? enquecommand_front_P(PSTR("M600 AUTO")); // save print and run M600 command } else { enquecommand_front_P(PSTR("M600")); // save print and run M600 command } } } struct ReportingRAII { CommandInProgress cip; inline ReportingRAII(CommandInProgress cip):cip(cip){ BeginReport(cip, (uint16_t)ProgressCode::EngagingIdler); } inline ~ReportingRAII(){ EndReport(cip, (uint16_t)ProgressCode::OK); } }; bool MMU2::WaitForMMUReady(){ switch(State()){ case xState::Stopped: return false; case xState::Connecting: // shall we wait until the MMU reconnects? // fire-up a fsm_dlg and show "MMU not responding"? default: return true; } } bool MMU2::RetryIfPossible(uint16_t ec){ if( retryAttempts ){ SERIAL_ECHOPGM("retryAttempts=");SERIAL_ECHOLN((uint16_t)retryAttempts); SetButtonResponse(ButtonOperations::Retry); // check, that Retry is actually allowed on that operation if( ButtonAvailable(ec) != NoButton ){ inAutoRetry = true; SERIAL_ECHOLNPGM("RetryButtonPressed"); // We don't decrement until the button is acknowledged by the MMU. //--retryAttempts; // "used" one retry attempt return true; } } inAutoRetry = false; return false; } void MMU2::ResetRetryAttempts(){ SERIAL_ECHOLNPGM("ResetRetryAttempts"); retryAttempts = MAX_RETRIES; } void MMU2::DecrementRetryAttempts() { if (inAutoRetry && retryAttempts) { SERIAL_ECHOLNPGM("DecrementRetryAttempts"); retryAttempts--; } } bool MMU2::VerifyFilamentEnteredPTFE() { st_synchronize(); if (!fsensor.getFilamentPresent()) return false; uint8_t fsensorState = 0; // MMU has finished its load, push the filament further by some defined constant length // If the filament sensor reads 0 at any moment, then report FAILURE current_position[E_AXIS] += MMU2_EXTRUDER_PTFE_LENGTH + MMU2_EXTRUDER_HEATBREAK_LENGTH - logic.ExtraLoadDistance(); plan_buffer_line_curposXYZE(MMU2_LOAD_TO_NOZZLE_FEED_RATE); current_position[E_AXIS] -= (MMU2_EXTRUDER_PTFE_LENGTH + MMU2_EXTRUDER_HEATBREAK_LENGTH - logic.ExtraLoadDistance()); plan_buffer_line_curposXYZE(MMU2_LOAD_TO_NOZZLE_FEED_RATE); while(blocks_queued()) { // Wait for move to finish and monitor the fsensor the entire time // A single 0 reading will set the bit. fsensorState |= !fsensor.getFilamentPresent(); manage_heater(); manage_inactivity(true); } if (fsensorState) { IncrementLoadFails(); return false; } else { // else, happy printing! :) return true; } } void MMU2::ToolChangeCommon(uint8_t slot){ for(;;) { // while not successfully fed into extruder's PTFE tube for(;;) { tool_change_extruder = slot; logic.ToolChange(slot); // let the MMU pull the filament out and push a new one in if( manage_response(true, true) ) break; // otherwise: failed to perform the command - unload first and then let it run again IncrementMMUFails(); // just in case we stood in an error screen for too long and the hotend got cold ResumeHotendTemp(); // if the extruder has been parked, it will get unparked once the ToolChange command finishes OK // - so no ResumeUnpark() at this spot unload(); // if we run out of retries, we must do something ... may be raise an error screen and allow the user to do something // but honestly - if the MMU restarts during every toolchange, // something else is seriously broken and stopping a print is probably our best option. } // reset current position to whatever the planner thinks it is plan_set_e_position(current_position[E_AXIS]); if (VerifyFilamentEnteredPTFE()) break; else { // Prepare a retry attempt unload(); // TODO cut filament } } extruder = slot; //filament change is finished SpoolJoin::spooljoin.setSlot(slot); // @@TODO really report onto the serial? May be for the Octoprint? Not important now // SERIAL_ECHO_START(); // SERIAL_ECHOLNPAIR(MSG_ACTIVE_EXTRUDER, int(extruder)); ++toolchange_counter; } bool MMU2::tool_change(uint8_t slot) { if( ! WaitForMMUReady()) return false; if (slot != extruder) { if (FindaDetectsFilament()) { // If Tcodes are used manually through the serial // we need to unload manually as well -- but only if FINDA detects filament unload(); } ReportingRAII rep(CommandInProgress::ToolChange); FSensorBlockRunout blockRunout; st_synchronize(); ToolChangeCommon(slot); } return true; } /// Handle special T?/Tx/Tc commands /// ///- T? Gcode to extrude shouldn't have to follow, load to extruder wheels is done automatically ///- Tx Same as T?, except nozzle doesn't have to be preheated. Tc must be placed after extruder nozzle is preheated to finish filament load. ///- Tc Load to nozzle after filament was prepared by Tx and extruder nozzle is already heated. bool MMU2::tool_change(char code, uint8_t slot) { if( ! WaitForMMUReady()) return false; FSensorBlockRunout blockRunout; switch (code) { case '?': { waitForHotendTargetTemp(100, []{}); load_filament_to_nozzle(slot); } break; case 'x': { set_extrude_min_temp(0); // Allow cold extrusion since Tx only loads to the gears not nozzle st_synchronize(); ToolChangeCommon(slot); // the only difference was manage_response(false, false), but probably good enough set_extrude_min_temp(EXTRUDE_MINTEMP); } break; case 'c': { waitForHotendTargetTemp(100, []{}); execute_extruder_sequence((const E_Step *)load_to_nozzle_sequence, sizeof(load_to_nozzle_sequence) / sizeof (load_to_nozzle_sequence[0])); } break; } return true; } void MMU2::get_statistics() { logic.Statistics(); } uint8_t MMU2::get_current_tool() const { return extruder == MMU2_NO_TOOL ? (uint8_t)FILAMENT_UNKNOWN : extruder; } uint8_t MMU2::get_tool_change_tool() const { return tool_change_extruder == MMU2_NO_TOOL ? (uint8_t)FILAMENT_UNKNOWN : tool_change_extruder; } bool MMU2::set_filament_type(uint8_t slot, uint8_t type) { if( ! WaitForMMUReady()) return false; // @@TODO - this is not supported in the new MMU yet slot = slot; // @@TODO type = type; // @@TODO // cmd_arg = filamentType; // command(MMU_CMD_F0 + index); if( ! manage_response(false, false) ){ // @@TODO failed to perform the command - retry ; } // true, true); -- Comment: how is it possible for a filament type set to fail? return true; } bool MMU2::unload() { if( ! WaitForMMUReady()) return false; WaitForHotendTargetTempBeep(); { FSensorBlockRunout blockRunout; ReportingRAII rep(CommandInProgress::UnloadFilament); filament_ramming(); // we assume the printer managed to relieve filament tip from the gears, // so repeating that part in case of an MMU restart is not necessary for(;;) { logic.UnloadFilament(); if( manage_response(false, true) ) break; IncrementMMUFails(); } Sound_MakeSound(e_SOUND_TYPE_StandardConfirm); // no active tool extruder = MMU2_NO_TOOL; tool_change_extruder = MMU2_NO_TOOL; } return true; } bool MMU2::cut_filament(uint8_t slot){ if( ! WaitForMMUReady()) return false; ReportingRAII rep(CommandInProgress::CutFilament); for(;;){ logic.CutFilament(slot); if( manage_response(false, true) ) break; IncrementMMUFails(); } return true; } void FullScreenMsg(const char *pgmS, uint8_t slot){ lcd_update_enable(false); lcd_clear(); lcd_puts_at_P(0, 1, pgmS); lcd_print(' '); lcd_print(slot + 1); } bool MMU2::loading_test(uint8_t slot){ FullScreenMsg(_T(MSG_TESTING_FILAMENT), slot); tool_change(slot); st_synchronize(); unload(); lcd_update_enable(true); return true; } bool MMU2::load_filament(uint8_t slot) { if( ! WaitForMMUReady()) return false; FullScreenMsg(_T(MSG_LOADING_FILAMENT), slot); ReportingRAII rep(CommandInProgress::LoadFilament); for(;;) { logic.LoadFilament(slot); if( manage_response(false, false) ) break; IncrementMMUFails(); } Sound_MakeSound(e_SOUND_TYPE_StandardConfirm); lcd_update_enable(true); return true; } struct LoadingToNozzleRAII { MMU2 &mmu2; explicit inline LoadingToNozzleRAII(MMU2 &mmu2):mmu2(mmu2){ mmu2.loadingToNozzle = true; } inline ~LoadingToNozzleRAII(){ mmu2.loadingToNozzle = false; } }; bool MMU2::load_filament_to_nozzle(uint8_t slot) { if( ! WaitForMMUReady()) return false; LoadingToNozzleRAII ln(*this); WaitForHotendTargetTempBeep(); FullScreenMsg(_T(MSG_LOADING_FILAMENT), slot); { // used for MMU-menu operation "Load to Nozzle" ReportingRAII rep(CommandInProgress::ToolChange); FSensorBlockRunout blockRunout; if( extruder != MMU2_NO_TOOL ){ // we already have some filament loaded - free it + shape its tip properly filament_ramming(); } ToolChangeCommon(slot); // Finish loading to the nozzle with finely tuned steps. execute_extruder_sequence((const E_Step *)load_to_nozzle_sequence, sizeof(load_to_nozzle_sequence) / sizeof (load_to_nozzle_sequence[0])); Sound_MakeSound(e_SOUND_TYPE_StandardConfirm); } lcd_update_enable(true); return true; } bool MMU2::eject_filament(uint8_t slot, bool recover) { if( ! WaitForMMUReady()) return false; ReportingRAII rep(CommandInProgress::EjectFilament); current_position[E_AXIS] -= MMU2_FILAMENTCHANGE_EJECT_FEED; plan_buffer_line_curposXYZE(2500.F / 60.F); st_synchronize(); logic.EjectFilament(slot); if( ! manage_response(false, false) ){ // @@TODO failed to perform the command - retry ; } if (recover) { // LCD_MESSAGEPGM(MSG_MMU2_EJECT_RECOVER); Sound_MakeSound(e_SOUND_TYPE_StandardPrompt); //@@TODO wait_for_user = true; //#if ENABLED(HOST_PROMPT_SUPPORT) // host_prompt_do(PROMPT_USER_CONTINUE, PSTR("MMU2 Eject Recover"), PSTR("Continue")); //#endif //#if ENABLED(EXTENSIBLE_UI) // ExtUI::onUserConfirmRequired_P(PSTR("MMU2 Eject Recover")); //#endif //@@TODO while (wait_for_user) idle(true); Sound_MakeSound(e_SOUND_TYPE_StandardConfirm); // logic.Command(); //@@TODO command(MMU_CMD_R0); if( ! manage_response(false, false) ){ // @@TODO failed to perform the command - retry ; } } // no active tool extruder = MMU2_NO_TOOL; tool_change_extruder = MMU2_NO_TOOL; Sound_MakeSound(e_SOUND_TYPE_StandardConfirm); // disable_E0(); return true; } void MMU2::Button(uint8_t index){ LogEchoEvent_P(PSTR("Button")); logic.Button(index); } void MMU2::Home(uint8_t mode){ logic.Home(mode); } void MMU2::SaveHotendTemp(bool turn_off_nozzle) { if (mmu_print_saved & SavedState::Cooldown) return; if (turn_off_nozzle && !(mmu_print_saved & SavedState::CooldownPending)){ resume_hotend_temp = degTargetHotend(active_extruder); mmu_print_saved |= SavedState::CooldownPending; LogEchoEvent_P(PSTR("Heater cooldown pending")); } } void MMU2::SaveAndPark(bool move_axes) { if (mmu_print_saved == SavedState::None) { // First occurrence. Save current position, park print head, disable nozzle heater. LogEchoEvent_P(PSTR("Saving and parking")); st_synchronize(); if (move_axes){ mmu_print_saved |= SavedState::ParkExtruder; // save current pos for(uint8_t i = 0; i < 3; ++i){ resume_position.xyz[i] = current_position[i]; } // lift Z raise_z(MMU_ERR_Z_PAUSE_LIFT); // move XY aside if (axis_known_position[X_AXIS] && axis_known_position[Y_AXIS]) { current_position[X_AXIS] = MMU_ERR_X_PAUSE_POS; current_position[Y_AXIS] = MMU_ERR_Y_PAUSE_POS; plan_buffer_line_curposXYZE(NOZZLE_PARK_XY_FEEDRATE); st_synchronize(); } } } // keep the motors powered forever (until some other strategy is chosen) // @@TODO do we need that in 8bit? // gcode.reset_stepper_timeout(); } void MMU2::ResumeHotendTemp() { if ((mmu_print_saved & SavedState::CooldownPending)) { // Clear the "pending" flag if we haven't cooled yet. mmu_print_saved &= ~(SavedState::CooldownPending); LogEchoEvent_P(PSTR("Cooldown flag cleared")); } if ((mmu_print_saved & SavedState::Cooldown) && resume_hotend_temp) { LogEchoEvent_P(PSTR("Resuming Temp")); MMU2_ECHO_MSGRPGM(PSTR("Restoring hotend temperature ")); SERIAL_ECHOLN(resume_hotend_temp); mmu_print_saved &= ~(SavedState::Cooldown); setTargetHotend(resume_hotend_temp, active_extruder); lcd_display_message_fullscreen_P(_i("MMU Retry: Restoring temperature...")); ////MSG_MMU_RESTORE_TEMP c=20 r=4 //@todo better report the event and let the GUI do its work somewhere else ReportErrorHookSensorLineRender(); waitForHotendTargetTemp(100, []{ manage_inactivity(true); mmu2.mmu_loop_inner(false); ReportErrorHookDynamicRender(); }); lcd_update_enable(true); // temporary hack to stop this locking the printer... LogEchoEvent_P(PSTR("Hotend temperature reached")); lcd_clear(); } } void MMU2::ResumeUnpark(){ if (mmu_print_saved & SavedState::ParkExtruder) { LogEchoEvent_P(PSTR("Resuming XYZ")); current_position[X_AXIS] = resume_position.xyz[X_AXIS]; current_position[Y_AXIS] = resume_position.xyz[Y_AXIS]; plan_buffer_line_curposXYZE(NOZZLE_PARK_XY_FEEDRATE); st_synchronize(); current_position[Z_AXIS] = resume_position.xyz[Z_AXIS]; plan_buffer_line_curposXYZE(NOZZLE_PARK_Z_FEEDRATE); st_synchronize(); mmu_print_saved &= ~(SavedState::ParkExtruder); } } void MMU2::CheckUserInput(){ auto btn = ButtonPressed((uint16_t)lastErrorCode); // Was a button pressed on the MMU itself instead of the LCD? if (btn == Buttons::NoButton && lastButton != Buttons::NoButton){ btn = lastButton; lastButton = Buttons::NoButton; // Clear it. } switch (btn) { case Left: case Middle: case Right: SERIAL_ECHOPGM("CheckUserInput-btnLMR "); SERIAL_ECHOLN(btn); ResumeHotendTemp(); // Recover the hotend temp before we attempt to do anything else... Button(btn); // A quick hack: for specific error codes move the E-motor every time. // Not sure if we can rely on the fsensor. // Just plan the move, let the MMU take over when it is ready switch(lastErrorCode){ case ErrorCode::FSENSOR_DIDNT_SWITCH_OFF: case ErrorCode::FSENSOR_TOO_EARLY: HelpUnloadToFinda(); break; default: break; } break; case RestartMMU: Reset(ResetPin); // we cannot do power cycle on the MK3 // ... but mmu2_power.cpp knows this and triggers a soft-reset instead. break; case DisableMMU: Stop(); // Poweroff handles updating the EEPROM shutoff. break; case StopPrint: // @@TODO not sure if we shall handle this high level operation at this spot break; default: break; } } /// Originally, this was used to wait for response and deal with timeout if necessary. /// The new protocol implementation enables much nicer and intense reporting, so this method will boil down /// just to verify the result of an issued command (which was basically the original idea) /// /// It is closely related to mmu_loop() (which corresponds to our ProtocolLogic::Step()), which does NOT perform any blocking wait for a command to finish. /// But - in case of an error, the command is not yet finished, but we must react accordingly - move the printhead elsewhere, stop heating, eat a cat or so. /// That's what's being done here... bool MMU2::manage_response(const bool move_axes, const bool turn_off_nozzle) { mmu_print_saved = SavedState::None; KEEPALIVE_STATE(IN_PROCESS); LongTimer nozzleTimeout; for (;;) { // in our new implementation, we know the exact state of the MMU at any moment, we do not have to wait for a timeout // So in this case we shall decide if the operation is: // - still running -> wait normally in idle() // - failed -> then do the safety moves on the printer like before // - finished ok -> proceed with reading other commands manage_heater(); manage_inactivity(true); // calls LogicStep() and remembers its return status lcd_update(0); if (mmu_print_saved & SavedState::CooldownPending){ if (!nozzleTimeout.running()){ nozzleTimeout.start(); LogEchoEvent_P(PSTR("Cooling Timeout started")); } else if (nozzleTimeout.expired(DEFAULT_SAFETYTIMER_TIME_MINS*60*1000ul)){ // mins->msec. mmu_print_saved &= ~(SavedState::CooldownPending); mmu_print_saved |= SavedState::Cooldown; setAllTargetHotends(0); LogEchoEvent_P(PSTR("Heater cooldown")); } } else if (nozzleTimeout.running()) { nozzleTimeout.stop(); LogEchoEvent_P(PSTR("Cooling timer stopped")); } switch (logicStepLastStatus) { case Finished: // command/operation completed, let Marlin continue its work // the E may have some more moves to finish - wait for them ResumeHotendTemp(); ResumeUnpark(); // We can now travel back to the tower or wherever we were when we saved. ResetRetryAttempts(); // Reset the retry counter. st_synchronize(); return true; case Interrupted: // now what :D ... big bad ... ramming, unload, retry the whole command originally issued return false; case VersionMismatch: // this basically means the MMU will be disabled until reconnected CheckUserInput(); return true; case CommandError: case CommunicationTimeout: case ProtocolError: case ButtonPushed: if (!inAutoRetry){ // Don't proceed to the park/save if we are doing an autoretry. SaveAndPark(move_axes); SaveHotendTemp(turn_off_nozzle); CheckUserInput(); } break; case CommunicationRecovered: // @@TODO communication recovered and may be an error recovered as well // may be the logic layer can detect the change of state a respond with one "Recovered" to be handled here ResumeHotendTemp(); ResumeUnpark(); break; case Processing: // wait for the MMU to respond default: break; } } } StepStatus MMU2::LogicStep(bool reportErrors) { CheckUserInput(); // Process any buttons before proceeding with another MMU Query StepStatus ss = logic.Step(); switch (ss) { case Finished: // At this point it is safe to trigger a runout and not interrupt the MMU protocol CheckFINDARunout(); break; case Processing: OnMMUProgressMsg(logic.Progress()); break; case ButtonPushed: lastButton = logic.Button(); LogEchoEvent_P(PSTR("MMU Button pushed")); CheckUserInput(); // Process the button immediately break; case Interrupted: // can be silently handed over to a higher layer, no processing necessary at this spot break; default: if(reportErrors) { switch (ss) { case CommandError: ReportError(logic.Error(), ErrorSourceMMU); break; case CommunicationTimeout: state = xState::Connecting; ReportError(ErrorCode::MMU_NOT_RESPONDING, ErrorSourcePrinter); break; case ProtocolError: state = xState::Connecting; ReportError(ErrorCode::PROTOCOL_ERROR, ErrorSourcePrinter); break; case VersionMismatch: StopKeepPowered(); ReportError(ErrorCode::VERSION_MISMATCH, ErrorSourcePrinter); break; default: break; } } } if( logic.Running() ){ state = xState::Active; } return ss; } void MMU2::filament_ramming() { execute_extruder_sequence((const E_Step *)ramming_sequence, sizeof(ramming_sequence) / sizeof(E_Step)); } void MMU2::execute_extruder_sequence(const E_Step *sequence, uint8_t steps) { st_synchronize(); const E_Step *step = sequence; for (uint8_t i = 0; i < steps; i++) { current_position[E_AXIS] += pgm_read_float(&(step->extrude)); plan_buffer_line_curposXYZE(pgm_read_float(&(step->feedRate))); st_synchronize(); step++; } } void MMU2::ReportError(ErrorCode ec, ErrorSource res) { // Due to a potential lossy error reporting layers linked to this hook // we'd better report everything to make sure especially the error states // do not get lost. // - The good news here is the fact, that the MMU reports the errors repeatedly until resolved. // - The bad news is, that MMU not responding may repeatedly occur on printers not having the MMU at all. // // Not sure how to properly handle this situation, options: // - skip reporting "MMU not responding" (at least for now) // - report only changes of states (we can miss an error message) // - may be some combination of MMUAvailable + UseMMU flags and decide based on their state // Right now the filtering of MMU_NOT_RESPONDING is done in ReportErrorHook() as it is not a problem if mmu2.cpp // Depending on the Progress code, we may want to do some action when an error occurs switch (logic.Progress()){ case ProgressCode::UnloadingToFinda: unloadFilamentStarted = false; break; case ProgressCode::FeedingToFSensor: // FSENSOR error during load. Make sure E-motor stops moving. loadFilamentStarted = false; break; default: break; } if( ec != lastErrorCode ){ // deduplicate: only report changes in error codes into the log lastErrorCode = ec; lastErrorSource = res; LogErrorEvent_P( _O(PrusaErrorTitle(PrusaErrorCodeIndex((uint16_t)ec))) ); if( ec != ErrorCode::OK ){ IncrementMMUFails(); // check if it is a "power" failure - we consider TMC-related errors as power failures static constexpr uint16_t tmcMask = ( (uint16_t)ErrorCode::TMC_IOIN_MISMATCH | (uint16_t)ErrorCode::TMC_RESET | (uint16_t)ErrorCode::TMC_UNDERVOLTAGE_ON_CHARGE_PUMP | (uint16_t)ErrorCode::TMC_SHORT_TO_GROUND | (uint16_t)ErrorCode::TMC_OVER_TEMPERATURE_WARN | (uint16_t)ErrorCode::TMC_OVER_TEMPERATURE_ERROR | (uint16_t)ErrorCode::MMU_SOLDERING_NEEDS_ATTENTION ) & 0x7fffU; // skip the top bit static_assert(tmcMask == 0x7e00); // just make sure we fail compilation if any of the TMC error codes change if ((uint16_t)ec & tmcMask) { // @@TODO can be optimized to uint8_t operation // TMC-related errors are from 0x8200 higher IncrementTMCFailures(); } } } if( !mmu2.RetryIfPossible((uint16_t)ec) ) { // If retry attempts are all used up // or if 'Retry' operation is not available // raise the MMU error sceen and wait for user input ReportErrorHook((uint16_t)ec); } static_assert(mmu2Magic[0] == 'M' && mmu2Magic[1] == 'M' && mmu2Magic[2] == 'U' && mmu2Magic[3] == '2' && mmu2Magic[4] == ':' && strlen_constexpr(mmu2Magic) == 5, "MMU2 logging prefix mismatch, must be updated at various spots" ); } void MMU2::ReportProgress(ProgressCode pc) { ReportProgressHook((CommandInProgress)logic.CommandInProgress(), (uint16_t)pc); LogEchoEvent_P( _O(ProgressCodeToText((uint16_t)pc)) ); } void MMU2::OnMMUProgressMsg(ProgressCode pc){ if (pc != lastProgressCode) { OnMMUProgressMsgChanged(pc); } else { OnMMUProgressMsgSame(pc); } } void MMU2::OnMMUProgressMsgChanged(ProgressCode pc){ ReportProgress(pc); lastProgressCode = pc; switch (pc) { case ProgressCode::UnloadingToFinda: if ((CommandInProgress)logic.CommandInProgress() == CommandInProgress::UnloadFilament || ((CommandInProgress)logic.CommandInProgress() == CommandInProgress::ToolChange)) { // If MK3S sent U0 command, ramming sequence takes care of releasing the filament. // If Toolchange is done while printing, PrusaSlicer takes care of releasing the filament // If printing is not in progress, ToolChange will issue a U0 command. break; } else { // We're likely recovering from an MMU error st_synchronize(); unloadFilamentStarted = true; HelpUnloadToFinda(); } break; case ProgressCode::FeedingToFSensor: // prepare for the movement of the E-motor st_synchronize(); loadFilamentStarted = true; break; default: // do nothing yet break; } } void __attribute__((noinline)) MMU2::HelpUnloadToFinda(){ current_position[E_AXIS] -= MMU2_RETRY_UNLOAD_TO_FINDA_LENGTH; plan_buffer_line_curposXYZE(MMU2_RETRY_UNLOAD_TO_FINDA_FEED_RATE); } void MMU2::OnMMUProgressMsgSame(ProgressCode pc){ switch (pc) { case ProgressCode::UnloadingToFinda: if (unloadFilamentStarted && !blocks_queued()) { // Only plan a move if there is no move ongoing if (fsensor.getFilamentPresent()) { HelpUnloadToFinda(); } else { unloadFilamentStarted = false; } } break; case ProgressCode::FeedingToFSensor: if (loadFilamentStarted) { switch (WhereIsFilament()) { case FilamentState::AT_FSENSOR: // fsensor triggered, finish FeedingToExtruder state loadFilamentStarted = false; // After the MMU knows the FSENSOR is triggered it will: // 1. Push the filament by additional 30mm (see fsensorToNozzle) // 2. Disengage the idler and push another 2mm. current_position[E_AXIS] += logic.ExtraLoadDistance() + 2; plan_buffer_line_curposXYZE(MMU2_LOAD_TO_NOZZLE_FEED_RATE); break; case FilamentState::NOT_PRESENT: // fsensor not triggered, continue moving extruder if (!blocks_queued()) { // Only plan a move if there is no move ongoing current_position[E_AXIS] += 2.0f; plan_buffer_line_curposXYZE(MMU2_LOAD_TO_NOZZLE_FEED_RATE); } break; default: // Abort here? break; } } break; default: // do nothing yet break; } } } // namespace MMU2