#include "libslic3r/libslic3r.h" #include "DeviceManager.hpp" #include "libslic3r/Time.hpp" #include "libslic3r/Thread.hpp" #include "slic3r/Utils/NetworkAgent.hpp" #include "GuiColor.hpp" #include "GUI_App.hpp" #include "MsgDialog.hpp" #include "DeviceErrorDialog.hpp" #include "Plater.hpp" #include "GUI_App.hpp" #include "ReleaseNote.hpp" #include #include #include #include #include #include #include #include #include #include "fast_float/fast_float.h" #include "DeviceCore/DevFilaSystem.h" #include "DeviceCore/DevExtruderSystem.h" #include "DeviceCore/DevNozzleSystem.h" #include "DeviceCore/DevBed.h" #include "DeviceCore/DevLamp.h" #include "DeviceCore/DevFan.h" #include "DeviceCore/DevStorage.h" #include "DeviceCore/DevConfig.h" #include "DeviceCore/DevCtrl.h" #include "DeviceCore/DevInfo.h" #include "DeviceCore/DevPrintOptions.h" #include "DeviceCore/DevPrintTaskInfo.h" #include "DeviceCore/DevHMS.h" #include "DeviceCore/DevMapping.h" #include "DeviceCore/DevManager.h" #include "DeviceCore/DevUtil.h" #define CALI_DEBUG #define MINUTE_30 1800000 //ms #define TIME_OUT 5000 //ms #define ORCA_NETWORK_DEBUG namespace pt = boost::property_tree; float string_to_float(const std::string& str_value) { float value = 0.0; fast_float::from_chars(str_value.c_str(), str_value.c_str() + str_value.size(), value); return value; } int get_tray_id_by_ams_id_and_slot_id(int ams_id, int slot_id) { if (ams_id == VIRTUAL_TRAY_MAIN_ID || ams_id == VIRTUAL_TRAY_DEPUTY_ID) { return ams_id; } else { return ams_id * 4 + slot_id; } } wxString Slic3r::get_stage_string(int stage) { switch(stage) { case 0: return _L("Printing"); case 1: return _L("Auto bed leveling"); case 2: return _L("Heatbed preheating"); case 3: return _L("Vibration compensation"); case 4: return _L("Changing filament"); case 5: return _L("M400 pause"); case 6: return _L("Paused (filament ran out)"); case 7: return _L("Heating nozzle"); case 8: return _L("Calibrating dynamic flow"); case 9: return _L("Scanning bed surface"); case 10: return _L("Inspecting first layer"); case 11: return _L("Identifying build plate type"); case 12: return _L("Calibrating Micro Lidar"); case 13: return _L("Homing toolhead"); case 14: return _L("Cleaning nozzle tip"); case 15: return _L("Checking extruder temperature"); case 16: return _L("Paused by the user"); case 17: return _L("Pause (front cover fall off)"); case 18: return _L("Calibrating the micro lidar"); case 19: return _L("Calibrating flow ratio"); case 20: return _L("Pause (nozzle temperature malfunction)"); case 21: return _L("Pause (heatbed temperature malfunction)"); case 22: return _L("Filament unloading"); case 23: return _L("Pause (step loss)"); case 24: return _L("Filament loading"); case 25: return _L("Motor noise cancellation"); case 26: return _L("Pause (AMS offline)"); case 27: return _L("Pause (low speed of the heatbreak fan)"); case 28: return _L("Pause (chamber temperature control problem)"); case 29: return _L("Cooling chamber"); case 30: return _L("Pause (G-code inserted by user)"); case 31: return _L("Motor noise showoff"); case 32: return _L("Pause (nozzle clumping)"); case 33: return _L("Pause (cutter error)"); case 34: return _L("Pause (first layer error)"); case 35: return _L("Pause (nozzle clog)"); case 36: return _L("Measuring motion percision"); case 37: return _L("Enhancing motion percision"); case 38: return _L("Measure motion accuracy"); case 39: return _L("Nozzle offset calibration"); case 40: return _L("high temperature auto bed levelling"); case 41: return _L("Auto Check: Quick Release Lever"); case 42: return _L("Auto Check: Door and Upper Cover"); case 43: return _L("Laser Calibration"); case 44: return _L("Auto Check: Platform"); case 45: return _L("Confirming BirdsEye Camera location"); case 46: return _L("Calibrating BirdsEye Camera"); case 47: return _L("Auto bed leveling -phase 1"); case 48: return _L("Auto bed leveling -phase 2"); case 49: return _L("Heating chamber"); case 50: return _L("Cooling heatbed"); case 51: return _L("Printing calibration lines"); case 52: return _L("Auto Check: Material"); case 53: return _L("Live View Camera Calibration"); case 54: return _L("Waiting for heatbed to reach target temperature"); case 55: return _L("Auto Check: Material Position"); case 56: return _L("Cutting Module Offset Calibration"); default: BOOST_LOG_TRIVIAL(info) << "stage = " << stage; } return ""; } std::string to_string_nozzle_diameter(float nozzle_diameter) { float eps = 1e-3; if (abs(nozzle_diameter - 0.2) < eps) { return "0.2"; } else if (abs(nozzle_diameter - 0.4) < eps) { return "0.4"; } else if (abs(nozzle_diameter - 0.6) < eps) { return "0.6"; } else if (abs(nozzle_diameter - 0.8) < eps) { return "0.8"; } return "0"; } void sanitizeToUtf8(std::string& str) { std::string result; size_t i = 0; while (i < str.size()) { unsigned char c = str[i]; size_t remainingBytes = 0; bool valid = true; if ((c & 0x80) == 0x00) { // 1-byte character (ASCII) remainingBytes = 0; } else if ((c & 0xE0) == 0xC0) { // 2-byte character remainingBytes = 1; } else if ((c & 0xF0) == 0xE0) { // 3-byte character remainingBytes = 2; } else if ((c & 0xF8) == 0xF0) { // 4-byte character remainingBytes = 3; } else { valid = false; // Invalid first byte } if (valid && i + remainingBytes < str.size()) { for (size_t j = 1; j <= remainingBytes; ++j) { if ((str[i + j] & 0xC0) != 0x80) { valid = false; // Invalid continuation byte break; } } } else { valid = false; // Truncated character } if (valid) { // Append valid UTF-8 character result.append(str, i, remainingBytes + 1); i += remainingBytes + 1; } else { // Replace invalid character with space result += ' '; ++i; // Skip the invalid byte } } str = std::move(result); } namespace Slic3r { /* Common Functions */ void split_string(std::string s, std::vector& v) { std::string t = ""; for (int i = 0; i < s.length(); ++i) { if (s[i] == ',') { v.push_back(t); t = ""; } else { t.push_back(s[i]); } } v.push_back(t); } static wxString _generate_nozzle_id(NozzleVolumeType nozzle_type, const std::string& diameter) { // HS00-0.4 std::string nozzle_id = "H"; switch (nozzle_type) { case NozzleVolumeType::nvtStandard: { nozzle_id += "S"; break; } case NozzleVolumeType::nvtHighFlow: { nozzle_id += "H"; break; } default: nozzle_id += "H"; break; } nozzle_id += "00"; nozzle_id += "-"; nozzle_id += diameter; return nozzle_id; } NozzleVolumeType convert_to_nozzle_type(const std::string &str) { if (str.size() < 8) { assert(false); return NozzleVolumeType::nvtStandard; } NozzleVolumeType res = NozzleVolumeType::nvtStandard; if (str[1] == 'S') res = NozzleVolumeType::nvtStandard; else if (str[1] == 'H') res = NozzleVolumeType::nvtHighFlow; return res; } wxString MachineObject::get_printer_type_display_str() const { std::string display_name = DevPrinterConfigUtil::get_printer_display_name(printer_type); if (!display_name.empty()) return display_name; else return _L("Unknown"); } std::string MachineObject::get_printer_thumbnail_img_str() const { std::string img_str = DevPrinterConfigUtil::get_printer_thumbnail_img(printer_type); std::string img_url; if (!img_str.empty()) { img_url = Slic3r::resources_dir() + "\\printers\\image\\" + img_str; if (fs::exists(img_url + ".svg")) { return img_url; } else { img_url = img_str; } } else { img_url = "printer_thumbnail"; } return img_url; } std::string MachineObject::get_auto_pa_cali_thumbnail_img_str() const { return DevPrinterConfigUtil::get_printer_auto_pa_cali_image(printer_type); } std::string MachineObject::get_ftp_folder() { return DevPrinterConfigUtil::get_ftp_folder(printer_type); } std::string MachineObject::get_access_code() const { if (get_user_access_code().empty()) return access_code; return get_user_access_code(); } void MachineObject::set_access_code(std::string code, bool only_refresh) { this->access_code = code; if (only_refresh) { AppConfig* config = GUI::wxGetApp().app_config; if (config) { if (!code.empty()) { GUI::wxGetApp().app_config->set_str("access_code", get_dev_id(), code); DeviceManager::update_local_machine(*this); } else { GUI::wxGetApp().app_config->erase("access_code", get_dev_id()); } } } } void MachineObject::erase_user_access_code() { this->user_access_code = ""; AppConfig* config = GUI::wxGetApp().app_config; if (config) { GUI::wxGetApp().app_config->erase("user_access_code", get_dev_id()); //GUI::wxGetApp().app_config->save(); } } void MachineObject::set_user_access_code(std::string code, bool only_refresh) { this->user_access_code = code; if (only_refresh && !code.empty()) { AppConfig* config = GUI::wxGetApp().app_config; if (config && !code.empty()) { GUI::wxGetApp().app_config->set_str("user_access_code", get_dev_id(), code); DeviceManager::update_local_machine(*this); } } } std::string MachineObject::get_user_access_code() const { AppConfig* config = GUI::wxGetApp().app_config; if (config) { return GUI::wxGetApp().app_config->get("user_access_code", get_dev_id()); } return ""; } std::string MachineObject::get_show_printer_type() const { std::string printer_type = this->printer_type; if (this->is_support_upgrade_kit && this->installed_upgrade_kit) printer_type = "C12"; return printer_type; } PrinterSeries MachineObject::get_printer_series() const { std::string series = DevPrinterConfigUtil::get_printer_series_str(printer_type); if (series == "series_x1" || series == "series_o") return PrinterSeries::SERIES_X1; else if (series == "series_p1p") return PrinterSeries::SERIES_P1P; else return PrinterSeries::SERIES_P1P; } PrinterArch MachineObject::get_printer_arch() const { return DevPrinterConfigUtil::get_printer_arch(printer_type); } std::string MachineObject::get_printer_ams_type() const { return DevPrinterConfigUtil::get_printer_use_ams_type(printer_type); } bool MachineObject::is_series_n(const std::string& series_str) { return series_str == "series_n"; } bool MachineObject::is_series_p(const std::string& series_str) { return series_str == "series_p1p";} bool MachineObject::is_series_x(const std::string& series_str) { return series_str == "series_x1"; } bool MachineObject::is_series_o(const std::string& series_str) { return series_str == "series_o"; } bool MachineObject::is_series_n() const { return is_series_n(DevPrinterConfigUtil::get_printer_series_str(printer_type)); } bool MachineObject::is_series_p() const { return is_series_p(DevPrinterConfigUtil::get_printer_series_str(printer_type)); } bool MachineObject::is_series_x() const { return is_series_x(DevPrinterConfigUtil::get_printer_series_str(printer_type)); } bool MachineObject::is_series_o() const { return is_series_o(DevPrinterConfigUtil::get_printer_series_str(printer_type)); } std::string MachineObject::get_printer_series_str() const{ return DevPrinterConfigUtil::get_printer_series_str(printer_type);}; void MachineObject::reload_printer_settings() { print_json.load_compatible_settings("", ""); parse_json("cloud", "{}"); } MachineObject::MachineObject(DeviceManager* manager, NetworkAgent* agent, std::string name, std::string id, std::string ip) :dev_name(name), dev_id(id), dev_ip(ip), subtask_(nullptr), model_task(nullptr), slice_info(nullptr), m_is_online(false) { m_manager = manager; m_agent = agent; reset(); /* temprature fields */ chamber_temp = 0.0f; chamber_temp_target = 0.0f; frame_temp = 0.0f; /* ams fileds */ ams_exist_bits = 0; tray_exist_bits = 0; tray_is_bbl_bits = 0; /* signals */ wifi_signal = ""; /* upgrade */ upgrade_force_upgrade = false; upgrade_new_version = false; upgrade_consistency_request = false; /* printing */ mc_print_stage = 0; mc_print_error_code = 0; print_error = 0; mc_print_line_number = 0; mc_print_percent = 0; mc_print_sub_stage = 0; mc_left_time = 0; home_flag = -1; hw_switch_state = 0; has_ipcam = true; // default true auto vslot = DevAmsTray(std::to_string(VIRTUAL_TRAY_MAIN_ID)); vt_slot.push_back(vslot); { m_lamp = new DevLamp(this); m_fan = new DevFan(this); m_bed = new DevBed(this); m_storage = new DevStorage(this); m_extder_system = new DevExtderSystem(this); m_nozzle_system = new DevNozzleSystem(this); m_fila_system = new DevFilaSystem(this); m_hms_system = new DevHMS(this); m_config = new DevConfig(this); m_ctrl = new DevCtrl(this); m_print_options = new DevPrintOptions(this); } } MachineObject::~MachineObject() { if (subtask_) { delete subtask_; subtask_ = nullptr; } if (model_task) { delete model_task; model_task = nullptr; } free_slice_info(); while (!m_command_error_code_dlgs.empty()) { delete *m_command_error_code_dlgs.begin();/*element will auto remove from m_command_error_code_dlgs on deleted*/ } { delete m_lamp; m_lamp = nullptr; delete m_fan; m_fan = nullptr; delete m_bed; m_bed = nullptr; delete m_extder_system; m_extder_system = nullptr; delete m_nozzle_system; m_nozzle_system = nullptr; delete m_ctrl; m_ctrl = nullptr; delete m_fila_system; m_fila_system = nullptr; delete m_hms_system; m_hms_system = nullptr; delete m_config; m_config = nullptr; delete m_print_options; m_print_options = nullptr; } } bool MachineObject::is_in_extrusion_cali() { auto curr_time = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(curr_time - last_extrusion_cali_start_time); if (diff.count() < EXTRUSION_OMIT_TIME) { mc_print_percent = 0; return true; } if (is_in_printing_status(print_status) && print_type == "system" && boost::contains(m_gcode_file, "extrusion_cali") ) { return true; } return false; } bool MachineObject::is_extrusion_cali_finished() { auto curr_time = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(curr_time - last_extrusion_cali_start_time); if (diff.count() < EXTRUSION_OMIT_TIME) { return false; } if (boost::contains(m_gcode_file, "extrusion_cali") && this->mc_print_percent == 100) return true; else return false; } DevAmsTray *MachineObject::get_curr_tray() { const std::string& cur_ams_id = m_extder_system->GetCurrentAmsId(); if (cur_ams_id.compare(std::to_string(VIRTUAL_TRAY_MAIN_ID)) == 0) { return &vt_slot[0]; } DevAms* curr_ams = get_curr_Ams(); if (!curr_ams) return nullptr; auto it = curr_ams->GetTrays().find(m_extder_system->GetCurrentSlotId()); if (it != curr_ams->GetTrays().end()) { return it->second; } return nullptr; } std::string MachineObject::get_filament_id(std::string ams_id, std::string tray_id) const { return this->get_tray(ams_id, tray_id).setting_id; } std::string MachineObject::get_filament_type(const std::string& ams_id, const std::string& tray_id) const { return this->get_tray(ams_id, tray_id).type; } void MachineObject::_parse_ams_status(int ams_status) { ams_status_sub = ams_status & 0xFF; int ams_status_main_int = (ams_status & 0xFF00) >> 8; if (ams_status_main_int == (int)AmsStatusMain::AMS_STATUS_MAIN_IDLE) { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_IDLE; } else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_FILAMENT_CHANGE) { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_FILAMENT_CHANGE; } else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_RFID_IDENTIFYING) { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_RFID_IDENTIFYING; } else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_ASSIST) { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_ASSIST; } else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_CALIBRATION) { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_CALIBRATION; } else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_SELF_CHECK) { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_SELF_CHECK; } else if (ams_status_main_int == (int) AmsStatusMain::AMS_STATUS_MAIN_DEBUG) { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_DEBUG; } else { ams_status_main = AmsStatusMain::AMS_STATUS_MAIN_UNKNOWN; } BOOST_LOG_TRIVIAL(trace) << "ams_debug: main = " << ams_status_main_int << ", sub = " << ams_status_sub; } bool MachineObject::can_unload_filament() { bool result = false; if (!HasAms()) return true; if (ams_status_main == AMS_STATUS_MAIN_IDLE && hw_switch_state == 1 && m_extder_system->GetCurrentAmsId() == "255") { return true; } return result; } void MachineObject::get_ams_colors(std::vector &ams_colors) { m_fila_system->CollectAmsColors(ams_colors); } std::string MachineObject::get_firmware_type_str() { /*if (firmware_type == PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER) return "engineer"; else if (firmware_type == PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION) return "product";*/ // return product by default; // always return product, printer do not push this field return "product"; } std::string MachineObject::get_lifecycle_type_str() { /*if (lifecycle == PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER) return "engineer"; else if (lifecycle == PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION) return "product";*/ // return product by default; // always return product, printer do not push this field return "product"; } bool MachineObject::is_in_upgrading() { return upgrade_display_state == DevFirmwareUpgradingState::UpgradingInProgress; } bool MachineObject::is_upgrading_avalable() { return upgrade_display_state == DevFirmwareUpgradingState::UpgradingAvaliable; } int MachineObject::get_upgrade_percent() { if (upgrade_progress.empty()) return 0; try { int result = atoi(upgrade_progress.c_str()); return result; } catch(...) { ; } return 0; } std::string MachineObject::get_ota_version() { auto it = module_vers.find("ota"); if (it != module_vers.end()) { //double check name if (it->second.name == "ota") { return it->second.sw_ver; } } return ""; } bool MachineObject::check_version_valid() { bool valid = true; for (auto module : module_vers) { if (module.second.sn.empty() && module.first != "ota" && module.first != "xm") return false; if (module.second.sw_ver.empty()) return false; } get_version_retry = 0; return valid; } wxString MachineObject::get_upgrade_result_str(int err_code) { switch(err_code) { case UpgradeNoError: return _L("Update successful."); case UpgradeDownloadFailed: return _L("Downloading failed."); case UpgradeVerfifyFailed: return _L("Verification failed."); case UpgradeFlashFailed: return _L("Update failed."); case UpgradePrinting: return _L("Update failed."); default: return _L("Update failed."); } return ""; } std::map MachineObject::get_ams_version() { std::vector multi_tray_ams_type = {"ams", "n3f"}; std::map result; for (int i = 0; i < 8; i++) { std::string ams_id; for (auto type : multi_tray_ams_type) { ams_id = type + "/" + std::to_string(i); auto it = module_vers.find(ams_id); if (it != module_vers.end()) { result.emplace(std::pair(i, it->second)); } } } std::string single_tray_ams_type = "n3s"; int n3s_start_id = 128; for (int i = n3s_start_id; i < n3s_start_id + 8; i++) { std::string ams_id; ams_id = single_tray_ams_type + "/" + std::to_string(i); auto it = module_vers.find(ams_id); if (it != module_vers.end()) { result.emplace(std::pair(i, it->second)); } } return result; } void MachineObject::clear_version_info() { air_pump_version_info = DevFirmwareVersionInfo(); laser_version_info = DevFirmwareVersionInfo(); cutting_module_version_info = DevFirmwareVersionInfo(); module_vers.clear(); } void MachineObject::store_version_info(const DevFirmwareVersionInfo& info) { if (info.isAirPump()) { air_pump_version_info = info; } else if (info.isLaszer()) { laser_version_info = info; } else if (info.isCuttingModule()) { cutting_module_version_info = info; } module_vers.emplace(info.name, info); } bool MachineObject::is_system_printing() { if (is_in_calibration() && is_in_printing_status(print_status)) return true; //FIXME //if (print_type == "system" && is_in_printing_status(print_status)) //return true; return false; } bool MachineObject::check_pa_result_validation(PACalibResult& result) { if (result.k_value < 0 || result.k_value > 10) return false; return true; } bool MachineObject::is_axis_at_home(std::string axis) { if (home_flag < 0) return true; if (axis == "X") { return (home_flag & 1) == 1; } else if (axis == "Y") { return ((home_flag >> 1) & 1) == 1; } else if (axis == "Z") { return ((home_flag >> 2) & 1) == 1; } else { return true; } } bool MachineObject::is_filament_at_extruder() { if (hw_switch_state == 1) return true; else if (hw_switch_state == 0) return false; else { //default return true; } } wxString MachineObject::get_curr_stage() { if (stage_list_info.empty()) { return ""; } return get_stage_string(stage_curr); } int MachineObject::get_curr_stage_idx() { int result = -1; for (int i = 0; i < stage_list_info.size(); i++) { if (stage_list_info[i] == stage_curr) { return i; } } return -1; } bool MachineObject::is_in_calibration() { // gcode file: auto_cali_for_user.gcode or auto_cali_for_user_param if (boost::contains(m_gcode_file, "auto_cali_for_user") && stage_curr != 0) { return true; } else { // reset if (stage_curr != 0) { calibration_done = false; } } return false; } bool MachineObject::is_calibration_done() { return calibration_done; } bool MachineObject::is_calibration_running() { if (is_in_calibration() && is_in_printing_status(print_status)) return true; return false; } void MachineObject::parse_state_changed_event() { // parse calibration done if (last_mc_print_stage != mc_print_stage) { if (mc_print_stage == 1 && boost::contains(m_gcode_file, "auto_cali_for_user")) { calibration_done = true; } else { calibration_done = false; } } last_mc_print_stage = mc_print_stage; } void MachineObject::parse_status(int flag) { is_220V_voltage = ((flag >> 3) & 0x1) != 0; if (time(nullptr) - xcam_auto_recovery_hold_start > HOLD_TIME_3SEC) { xcam_auto_recovery_step_loss = ((flag >> 4) & 0x1) != 0; } camera_recording = ((flag >> 5) & 0x1) != 0; if (time(nullptr) - ams_user_setting_start > HOLD_COUNT_MAX) { m_fila_system->GetAmsSystemSetting().SetDetectRemainEnabled(((flag >> 7) & 0x1) != 0); } // sdcard_state = MachineObject::SdcardState(get_flag_bits(flag, 8, 2)); m_storage->set_sdcard_state(get_flag_bits(flag, 8, 2)); if (time(nullptr) - ams_switch_filament_start > HOLD_TIME_3SEC) { m_fila_system->GetAmsSystemSetting().SetAutoRefillEnabled(((flag >> 10) & 0x1) != 0); } is_support_flow_calibration = ((flag >> 15) & 0x1) != 0; if (this->is_series_o()) { is_support_flow_calibration = false; } // todo: Temp modification due to incorrect machine push message for H2D is_support_pa_calibration = ((flag >> 16) & 0x1) != 0; if (this->is_series_p()) { is_support_pa_calibration = false; } // todo: Temp modification due to incorrect machine push message for P if (time(nullptr) - xcam_prompt_sound_hold_start > HOLD_TIME_3SEC) { xcam_allow_prompt_sound = ((flag >> 17) & 0x1) != 0; } is_support_prompt_sound = ((flag >> 18) & 0x1) != 0; is_support_filament_tangle_detect = ((flag >> 19) & 0x1) != 0; if (time(nullptr) - xcam_filament_tangle_detect_hold_start > HOLD_TIME_3SEC) { xcam_filament_tangle_detect = ((flag >> 20) & 0x1) != 0; } /*if(!is_support_motor_noise_cali){ is_support_motor_noise_cali = ((flag >> 21) & 0x1) != 0; }*/ is_support_motor_noise_cali = ((flag >> 21) & 0x1) != 0; is_support_user_preset = ((flag >> 22) & 0x1) != 0; is_support_nozzle_blob_detection = ((flag >> 25) & 0x1) != 0; if (time(nullptr) - nozzle_blob_detection_hold_start > HOLD_TIME_3SEC) { nozzle_blob_detection_enabled = ((flag >> 24) & 0x1) != 0; } is_support_air_print_detection = ((flag >> 29) & 0x1) != 0; ams_air_print_status = ((flag >> 28) & 0x1) != 0; /*if (!is_support_p1s_plus) { auto supported_plus = ((flag >> 27) & 0x1) != 0; auto installed_plus = ((flag >> 26) & 0x1) != 0; if (installed_plus && supported_plus) { is_support_p1s_plus = true; } else { is_support_p1s_plus = false; } }*/ is_support_upgrade_kit = ((flag >> 27) & 0x1) != 0; installed_upgrade_kit = ((flag >> 26) & 0x1) != 0; is_support_agora = ((flag >> 30) & 0x1) != 0; if (is_support_agora) is_support_tunnel_mqtt = false; } int MachineObject::get_bed_temperature_limit() { if (get_printer_series() == PrinterSeries::SERIES_X1) { if (is_220V_voltage) return 110; else { return 120; } } else { int limit = bed_temperature_limit < 0?BED_TEMP_LIMIT:bed_temperature_limit; return limit; } return BED_TEMP_LIMIT; } bool MachineObject::is_filament_installed() { if (m_extder_system->GetTotalExtderCount() > 0) { // right//or single auto ext = m_extder_system->m_extders[MAIN_EXTRUDER_ID]; if (ext.m_ext_has_filament) { return true; } } /*left*/ if (m_extder_system->GetTotalExtderCount() > 1) { auto ext = m_extder_system->m_extders[DEPUTY_EXTRUDER_ID]; if (ext.m_ext_has_filament) { return true; } } return false; } bool MachineObject::is_makeworld_subtask() { if (model_task && model_task->design_id > 0) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " model task id: " << model_task->task_id << " is makeworld model"; return true; } return false; } bool MachineObject::is_sdcard_printing() { if (can_abort() && (obj_subtask_id.compare("0") == 0 || obj_subtask_id.empty()) && (profile_id_ == "0" || profile_id_.empty()) && (project_id_ == "0" || project_id_.empty())) return true; else return false; } bool MachineObject::is_timelapse() { return camera_timelapse; } bool MachineObject::is_recording_enable() { return camera_recording_when_printing; } bool MachineObject::is_recording() { return camera_recording; } int MachineObject::get_liveview_remote() { if (is_support_agora) { return liveview_remote == LVR_None ? LVR_Agora : liveview_remote == LVR_Tutk ? LVR_TutkAgora : liveview_remote; } return liveview_remote; } int MachineObject::get_file_remote() { if (is_support_agora) file_remote = file_remote == FR_None ? FR_Agora : file_remote == FR_Tutk ? FR_TutkAgora : file_remote; return file_remote; } std::string MachineObject::parse_version() { auto ota_version = module_vers.find("ota"); if (ota_version != module_vers.end()) return ota_version->second.sw_ver; auto series = get_printer_series(); if (series == PrinterSeries::SERIES_X1) { auto rv1126_version = module_vers.find("rv1126"); if (rv1126_version != module_vers.end()) return rv1126_version->second.sw_ver; } else if (series == PrinterSeries::SERIES_P1P) { auto esp32_version = module_vers.find("esp32"); if (esp32_version != module_vers.end()) return esp32_version->second.sw_ver; } return ""; } void MachineObject::parse_version_func() { } bool MachineObject::is_studio_cmd(int sequence_id) { if (sequence_id >= START_SEQ_ID && sequence_id < END_SEQ_ID) { return true; } return false; } bool MachineObject::canEnableTimelapse(wxString &error_message) const { if (!is_support_timelapse) { error_message = _L("Timelapse is not supported on this printer."); return false; } if (is_support_internal_timelapse) { return true; } if (m_storage->get_sdcard_state() != DevStorage::SdcardState::HAS_SDCARD_NORMAL) { if (m_storage->get_sdcard_state() == DevStorage::SdcardState::NO_SDCARD) { error_message = _L("Timelapse is not supported while the storage does not exist."); } else if (m_storage->get_sdcard_state() == DevStorage::SdcardState::HAS_SDCARD_ABNORMAL) { error_message = _L("Timelapse is not supported while the storage is unavailable."); } else if (m_storage->get_sdcard_state() == DevStorage::SdcardState::HAS_SDCARD_READONLY) { error_message = _L("Timelapse is not supported while the storage is readonly."); } return false; } return true; } int MachineObject::command_get_version(bool with_retry) { BOOST_LOG_TRIVIAL(info) << "command_get_version"; json j; j["info"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["info"]["command"] = "get_version"; if (with_retry) get_version_retry = GET_VERSION_RETRYS; return this->publish_json(j, 1); } int MachineObject::command_get_access_code() { BOOST_LOG_TRIVIAL(info) << "command_get_access_code"; json j; j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["system"]["command"] = "get_access_code"; return this->publish_json(j); } int MachineObject::command_request_push_all(bool request_now) { auto curr_time = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(curr_time - last_request_push); if (diff.count() < REQUEST_PUSH_MIN_TIME) { if (request_now) { BOOST_LOG_TRIVIAL(trace) << "static: command_request_push_all, dev_id=" << dev_id; last_request_push = std::chrono::system_clock::now(); } else { BOOST_LOG_TRIVIAL(trace) << "static: command_request_push_all: send request too fast, dev_id=" << dev_id; return -1; } } else { BOOST_LOG_TRIVIAL(trace) << "static: command_request_push_all, dev_id=" << dev_id; last_request_push = std::chrono::system_clock::now(); } json j; j["pushing"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["pushing"]["command"] = "pushall"; j["pushing"]["version"] = 1; j["pushing"]["push_target"] = 1; return this->publish_json(j); } int MachineObject::command_pushing(std::string cmd) { auto curr_time = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(curr_time - last_request_start); if (diff.count() < REQUEST_START_MIN_TIME) { BOOST_LOG_TRIVIAL(trace) << "static: command_request_start: send request too fast, dev_id=" << dev_id; return -1; } else { BOOST_LOG_TRIVIAL(trace) << "static: command_request_start, dev_id=" << dev_id; last_request_start = std::chrono::system_clock::now(); } if (cmd == "start" || cmd == "stop") { json j; j["pushing"]["command"] = cmd; j["pushing"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j); } return -1; } int MachineObject::command_clean_print_error(std::string subtask_id, int print_error) { BOOST_LOG_TRIVIAL(info) << "command_clean_print_error, id = " << subtask_id; json j; j["print"]["command"] = "clean_print_error"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["subtask_id"] = subtask_id; j["print"]["print_error"] = print_error; return this->publish_json(j); } int MachineObject::command_clean_print_error_uiop(int print_error) { json j; j["system"]["command"] = "uiop"; j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["system"]["name"] = "print_error"; j["system"]["action"] = "close"; j["system"]["source"] = 1;// 0-Mushu 1-Studio j["system"]["type"] = "dialog"; // the error to be cleaned char buf[32]; ::sprintf(buf, "%08X", print_error); j["system"]["err"] = std::string(buf); return this->publish_json(j); } int MachineObject::command_upgrade_confirm() { BOOST_LOG_TRIVIAL(info) << "command_upgrade_confirm"; json j; j["upgrade"]["command"] = "upgrade_confirm"; j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["upgrade"]["src_id"] = 1; // 1 for slicer return this->publish_json(j); } int MachineObject::command_consistency_upgrade_confirm() { BOOST_LOG_TRIVIAL(info) << "command_consistency_upgrade_confirm"; json j; j["upgrade"]["command"] = "consistency_confirm"; j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["upgrade"]["src_id"] = 1; // 1 for slicer return this->publish_json(j); } int MachineObject::command_upgrade_firmware(FirmwareInfo info) { std::string version = info.version; std::string dst_url = info.url; std::string module_name = info.module_type; json j; j["upgrade"]["command"] = "start"; j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["upgrade"]["url"] = info.url; j["upgrade"]["module"] = info.module_type; j["upgrade"]["version"] = info.version; j["upgrade"]["src_id"] = 1; return this->publish_json(j); } int MachineObject::command_upgrade_module(std::string url, std::string module_type, std::string version) { json j; j["upgrade"]["command"] = "start"; j["upgrade"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["upgrade"]["url"] = url; j["upgrade"]["module"] = module_type; j["upgrade"]["version"] = version; j["upgrade"]["src_id"] = 1; return this->publish_json(j); } int MachineObject::command_xyz_abs() { return this->publish_gcode("G90 \n"); } int MachineObject::command_auto_leveling() { return this->publish_gcode("G29 \n"); } int MachineObject::command_go_home() { return this->publish_gcode("G28 \n"); } int MachineObject::command_go_home2() { BOOST_LOG_TRIVIAL(info) << "New protocol of command_go_home2"; json j; j["print"]["command"] = "back_to_center"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j); } int MachineObject::command_task_abort() { BOOST_LOG_TRIVIAL(trace) << "command_task_abort: "; json j; j["print"]["command"] = "stop"; j["print"]["param"] = ""; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_task_cancel(std::string job_id) { BOOST_LOG_TRIVIAL(trace) << "command_task_cancel: " << job_id; json j; j["print"]["command"] = "stop"; j["print"]["param"] = ""; j["print"]["job_id"] = job_id; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_task_pause() { json j; j["print"]["command"] = "pause"; j["print"]["param"] = ""; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_task_resume() { if(check_resume_condition()) return 0; json j; j["print"]["command"] = "resume"; j["print"]["param"] = ""; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_hms_idle_ignore(const std::string &error_str, int type) { if(check_resume_condition()) return 0; json j; j["print"]["command"] = "idle_ignore"; j["print"]["err"] = error_str; j["print"]["type"] = type; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_hms_resume(const std::string& error_str, const std::string& job_id) { if(check_resume_condition()) return 0; json j; j["print"]["command"] = "resume"; j["print"]["err"] = error_str; j["print"]["param"] = "reserve"; j["print"]["job_id"] = job_id; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_hms_ignore(const std::string& error_str, const std::string& job_id) { if(check_resume_condition()) return 0; json j; j["print"]["command"] = "ignore"; j["print"]["err"] = error_str; j["print"]["param"] = "reserve"; j["print"]["job_id"] = job_id; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_hms_stop(const std::string &error_str, const std::string &job_id) { json j; j["print"]["command"] = "stop"; j["print"]["err"] = error_str; j["print"]["param"] = "reserve"; j["print"]["job_id"] = job_id; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_stop_buzzer() { json j; j["print"]["command"] = "buzzer_ctrl"; j["print"]["mode"] = 0; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j, 1); } int MachineObject::command_set_bed(int temp) { if (m_support_mqtt_bet_ctrl) { json j; j["print"]["command"] = "set_bed_temp"; j["print"]["temp"] = temp; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j); } std::string gcode_str = (boost::format("M140 S%1%\n") % temp).str(); return this->publish_gcode(gcode_str); } int MachineObject::command_set_nozzle(int temp) { std::string gcode_str = (boost::format("M104 S%1%\n") % temp).str(); return this->publish_gcode(gcode_str); } int MachineObject::command_set_nozzle_new(int nozzle_id, int temp) { BOOST_LOG_TRIVIAL(info) << "set_nozzle_temp"; json j; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["command"] = "set_nozzle_temp"; j["print"]["extruder_index"] = nozzle_id; j["print"]["target_temp"] = temp; return this->publish_json(j, 1); } int MachineObject::command_set_chamber(int temp) { json j; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["command"] = "set_ctt"; j["print"]["ctt_val"] = temp; return this->publish_json(j, 1); } int MachineObject::check_resume_condition() { if (jobState_ > 1) { GUI::wxGetApp().show_dialog(_L("To ensure your safety, certain processing tasks (such as laser) can only be resumed on printer.")); return 1; } return 0; } int MachineObject::command_ams_change_filament(bool load, std::string ams_id, std::string slot_id, int old_temp, int new_temp) { json j; try { auto tray_id = 0; if (atoi(ams_id.c_str()) < 16) { tray_id = atoi(ams_id.c_str()) * 4 + atoi(slot_id.c_str()); } // TODO: Orca hack if (ams_id == "254") ams_id = "255"; j["print"]["command"] = "ams_change_filament"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["curr_temp"] = old_temp; j["print"]["tar_temp"] = new_temp; j["print"]["ams_id"] = atoi(ams_id.c_str()); if (!load) { j["print"]["target"] = 255; j["print"]["slot_id"] = 255; // the new protocol to mark unload } else { if (tray_id == 0) { j["print"]["target"] = atoi(ams_id.c_str()); } else { j["print"]["target"] = tray_id; } j["print"]["slot_id"] = atoi(slot_id.c_str()); } } catch (const std::exception &) {} return this->publish_json(j); } int MachineObject::command_ams_user_settings(int ams_id, bool start_read_opt, bool tray_read_opt, bool remain_flag) { json j; j["print"]["command"] = "ams_user_setting"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["ams_id"] = ams_id; j["print"]["startup_read_option"] = start_read_opt; j["print"]["tray_read_option"] = tray_read_opt; j["print"]["calibrate_remain_flag"] = remain_flag; m_fila_system->GetAmsSystemSetting().SetDetectOnInsertEnabled(tray_read_opt); m_fila_system->GetAmsSystemSetting().SetDetectOnPowerupEnabled(start_read_opt); m_fila_system->GetAmsSystemSetting().SetDetectRemainEnabled(remain_flag); ams_user_setting_start = time(nullptr); return this->publish_json(j); } int MachineObject::command_ams_calibrate(int ams_id) { std::string gcode_cmd = (boost::format("M620 C%1% \n") % ams_id).str(); BOOST_LOG_TRIVIAL(trace) << "ams_debug: gcode_cmd" << gcode_cmd; return this->publish_gcode(gcode_cmd); } int MachineObject::command_ams_filament_settings(int ams_id, int slot_id, std::string filament_id, std::string setting_id, std::string tray_color, std::string tray_type, int nozzle_temp_min, int nozzle_temp_max) { int tag_tray_id = 0; int tag_ams_id = ams_id; int tag_slot_id = slot_id; if (tag_ams_id == VIRTUAL_TRAY_MAIN_ID || tag_ams_id == VIRTUAL_TRAY_DEPUTY_ID) { tag_tray_id = VIRTUAL_TRAY_DEPUTY_ID; } else { tag_tray_id = tag_slot_id; } BOOST_LOG_TRIVIAL(info) << "command_ams_filament_settings, ams_id = " << tag_ams_id << ", slot_id = " << tag_slot_id << ", tray_id = " << tag_tray_id << ", tray_color = " << tray_color << ", tray_type = " << tray_type << ", filament_id = " << filament_id << ", setting_id = " << setting_id << ", temp_min: = " << nozzle_temp_min << ", temp_max: = " << nozzle_temp_max; json j; j["print"]["command"] = "ams_filament_setting"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["ams_id"] = tag_ams_id; j["print"]["slot_id"] = tag_slot_id; j["print"]["tray_id"] = tag_tray_id; j["print"]["tray_info_idx"] = filament_id; j["print"]["setting_id"] = setting_id; // format "FFFFFFFF" RGBA j["print"]["tray_color"] = tray_color; j["print"]["nozzle_temp_min"] = nozzle_temp_min; j["print"]["nozzle_temp_max"] = nozzle_temp_max; j["print"]["tray_type"] = tray_type; return this->publish_json(j); } int MachineObject::command_ams_refresh_rfid(std::string tray_id) { std::string gcode_cmd = (boost::format("M620 R%1% \n") % tray_id).str(); BOOST_LOG_TRIVIAL(trace) << "ams_debug: gcode_cmd" << gcode_cmd; return this->publish_gcode(gcode_cmd); } int MachineObject::command_ams_refresh_rfid2(int ams_id, int slot_id) { json j; j["print"]["command"] = "ams_get_rfid"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["ams_id"] = ams_id; j["print"]["slot_id"] = slot_id; return this->publish_json(j); } int MachineObject::command_ams_select_tray(std::string tray_id) { std::string gcode_cmd = (boost::format("M620 P%1% \n") % tray_id).str(); BOOST_LOG_TRIVIAL(trace) << "ams_debug: gcode_cmd" << gcode_cmd; return this->publish_gcode(gcode_cmd); } int MachineObject::command_ams_control(std::string action) { if (action == "resume" && check_resume_condition()) return 0; //valid actions if (action == "resume" || action == "reset" || action == "pause" || action == "done" || action == "abort") { json j; j["print"]["command"] = "ams_control"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["param"] = action; return this->publish_json(j); } return -1; } int MachineObject::command_ams_drying_stop() { json j; j["print"]["command"] = "auto_stop_ams_dry"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j); } int MachineObject::command_start_extrusion_cali(int tray_index, int nozzle_temp, int bed_temp, float max_volumetric_speed, std::string setting_id) { BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: tray_id = " << tray_index << ", nozzle_temp = " << nozzle_temp << ", bed_temp = " << bed_temp << ", max_volumetric_speed = " << max_volumetric_speed; json j; j["print"]["command"] = "extrusion_cali"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["tray_id"] = tray_index; //j["print"]["setting_id"] = setting_id; //j["print"]["name"] = ""; j["print"]["nozzle_temp"] = nozzle_temp; j["print"]["bed_temp"] = bed_temp; j["print"]["max_volumetric_speed"] = max_volumetric_speed; // enter extusion cali last_extrusion_cali_start_time = std::chrono::system_clock::now(); BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: " << j.dump(); return this->publish_json(j); } int MachineObject::command_stop_extrusion_cali() { BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: stop"; if (is_in_extrusion_cali()) { return command_task_abort(); } return 0; } int MachineObject::command_extrusion_cali_set(int tray_index, std::string setting_id, std::string name, float k, float n, int bed_temp, int nozzle_temp, float max_volumetric_speed) { BOOST_LOG_TRIVIAL(trace) << "extrusion_cali: tray_id = " << tray_index << ", setting_id = " << setting_id << ", k = " << k << ", n = " << n; json j; j["print"]["command"] = "extrusion_cali_set"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["tray_id"] = tray_index; //j["print"]["setting_id"] = setting_id; //j["print"]["name"] = name; j["print"]["k_value"] = k; j["print"]["n_coef"] = 1.4f; // fixed n //j["print"]["n_coef"] = n; if (bed_temp >= 0 && nozzle_temp >= 0 && max_volumetric_speed >= 0) { j["print"]["bed_temp"] = bed_temp; j["print"]["nozzle_temp"] = nozzle_temp; j["print"]["max_volumetric_speed"] = max_volumetric_speed; } return this->publish_json(j); } int MachineObject::command_set_printing_speed(DevPrintingSpeedLevel lvl) { json j; j["print"]["command"] = "print_speed"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["param"] = std::to_string((int)lvl); return this->publish_json(j); } int MachineObject::command_set_printing_option(bool auto_recovery) { int print_option = (int)auto_recovery << (int)PRINT_OP_AUTO_RECOVERY; json j; j["print"]["command"] = "print_option"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["option"] = print_option; j["print"]["auto_recovery"] = auto_recovery; return this->publish_json(j); } int MachineObject::command_nozzle_blob_detect(bool nozzle_blob_detect) { json j; j["print"]["command"] = "print_option"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["nozzle_blob_detect"] = nozzle_blob_detect; nozzle_blob_detection_enabled = nozzle_blob_detect; nozzle_blob_detection_hold_start = time(nullptr); return this->publish_json(j); } int MachineObject::command_set_prompt_sound(bool prompt_sound){ json j; j["print"]["command"] = "print_option"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["sound_enable"] = prompt_sound; return this->publish_json(j); } int MachineObject::command_set_filament_tangle_detect(bool filament_tangle_detect) { json j; j["print"]["command"] = "print_option"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["filament_tangle_detect"] = filament_tangle_detect; return this->publish_json(j); } int MachineObject::command_ams_switch_filament(bool switch_filament) { json j; j["print"]["command"] = "print_option"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["auto_switch_filament"] = switch_filament; m_fila_system->GetAmsSystemSetting().SetAutoRefillEnabled(switch_filament); BOOST_LOG_TRIVIAL(trace) << "command_ams_filament_settings:" << switch_filament; ams_switch_filament_start = time(nullptr); return this->publish_json(j); } int MachineObject::command_ams_air_print_detect(bool air_print_detect) { json j; j["print"]["command"] = "print_option"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["air_print_detect"] = air_print_detect; ams_air_print_status = air_print_detect; BOOST_LOG_TRIVIAL(trace) << "command_ams_air_print_detect:" << air_print_detect; return this->publish_json(j); } int MachineObject::command_axis_control(std::string axis, double unit, double input_val, int speed) { if (m_support_mqtt_axis_control) { json j; j["print"]["command"] = "xyz_ctrl"; j["print"]["axis"] = axis; j["print"]["dir"] = input_val > 0 ? 1 : -1; j["print"]["mode"] = (std::abs(input_val) >= 10) ? 1 : 0; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j); } double value = input_val; if (!is_core_xy()) { if ( axis.compare("Y") == 0 || axis.compare("Z") == 0) { value = -1.0 * input_val; } } char cmd[256]; if (axis.compare("X") == 0 || axis.compare("Y") == 0 || axis.compare("Z") == 0) { sprintf(cmd, "M211 S \nM211 X1 Y1 Z1\nM1002 push_ref_mode\nG91 \nG1 %s%0.1f F%d\nM1002 pop_ref_mode\nM211 R\n", axis.c_str(), value * unit, speed); } else if (axis.compare("E") == 0) { sprintf(cmd, "M83 \nG0 %s%0.1f F%d\n", axis.c_str(), value * unit, speed); } else { return -1; } return this->publish_gcode(cmd); } int MachineObject::command_extruder_control(int nozzle_id, double val) { json j; j["print"]["command"] = "set_extrusion_length"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["extruder_index"] = nozzle_id; j["print"]["length"] = (int)val; return this->publish_json(j); } bool MachineObject::is_support_command_calibration() { if (get_printer_series() == PrinterSeries::SERIES_X1) { auto ap_ver_it = module_vers.find("rv1126"); if (ap_ver_it != module_vers.end()) { if (ap_ver_it->second.sw_ver.compare("00.00.15.79") < 0) return false; } } return true; } int MachineObject::command_start_calibration(bool vibration, bool bed_leveling, bool xcam_cali, bool motor_noise, bool nozzle_cali, bool bed_cali) { if (!is_support_command_calibration()) { // fixed gcode file json j; j["print"]["command"] = "gcode_file"; j["print"]["param"] = "/usr/etc/print/auto_cali_for_user.gcode"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return this->publish_json(j); } else { json j; j["print"]["command"] = "calibration"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["option"]= (bed_cali ? 1 << 5 : 0) + (nozzle_cali ? 1 << 4 : 0) + (motor_noise ? 1 << 3 : 0) + (vibration ? 1 << 2 : 0) + (bed_leveling ? 1 << 1 : 0) + (xcam_cali ? 1 << 0 : 0); return this->publish_json(j); } } int MachineObject::command_start_pa_calibration(const X1CCalibInfos &pa_data, int mode) { CNumericLocalesSetter locales_setter; pa_calib_results.clear(); json j; j["print"]["command"] = "extrusion_cali"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_data.calib_datas[0].nozzle_diameter); j["print"]["mode"] = mode; std::string filament_ids; for (int i = 0; i < pa_data.calib_datas.size(); ++i) { j["print"]["filaments"][i]["tray_id"] = pa_data.calib_datas[i].tray_id; j["print"]["filaments"][i]["extruder_id"] = pa_data.calib_datas[i].extruder_id; j["print"]["filaments"][i]["bed_temp"] = pa_data.calib_datas[i].bed_temp; j["print"]["filaments"][i]["filament_id"] = pa_data.calib_datas[i].filament_id; j["print"]["filaments"][i]["setting_id"] = pa_data.calib_datas[i].setting_id; j["print"]["filaments"][i]["nozzle_temp"] = pa_data.calib_datas[i].nozzle_temp; j["print"]["filaments"][i]["ams_id"] = pa_data.calib_datas[i].ams_id; j["print"]["filaments"][i]["slot_id"] = pa_data.calib_datas[i].slot_id; j["print"]["filaments"][i]["nozzle_id"] = _generate_nozzle_id(pa_data.calib_datas[i].nozzle_volume_type,to_string_nozzle_diameter(pa_data.calib_datas[i].nozzle_diameter)).ToStdString(); j["print"]["filaments"][i]["nozzle_diameter"] = to_string_nozzle_diameter(pa_data.calib_datas[i].nozzle_diameter); j["print"]["filaments"][i]["max_volumetric_speed"] = std::to_string(pa_data.calib_datas[i].max_volumetric_speed); if (i > 0) filament_ids += ","; filament_ids += pa_data.calib_datas[i].filament_id; } BOOST_LOG_TRIVIAL(info) << "extrusion_cali: " << j.dump(); return this->publish_json(j); } int MachineObject::command_set_pa_calibration(const std::vector &pa_calib_values, bool is_auto_cali) { CNumericLocalesSetter locales_setter; if (pa_calib_values.size() > 0) { json j; j["print"]["command"] = "extrusion_cali_set"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_calib_values[0].nozzle_diameter); for (int i = 0; i < pa_calib_values.size(); ++i) { if (pa_calib_values[i].tray_id >= 0) j["print"]["filaments"][i]["tray_id"] = pa_calib_values[i].tray_id; if (pa_calib_values[i].cali_idx >= 0) j["print"]["filaments"][i]["cali_idx"] = pa_calib_values[i].cali_idx; j["print"]["filaments"][i]["tray_id"] = pa_calib_values[i].tray_id; j["print"]["filaments"][i]["extruder_id"] = pa_calib_values[i].extruder_id; j["print"]["filaments"][i]["nozzle_id"] = _generate_nozzle_id(pa_calib_values[i].nozzle_volume_type, to_string_nozzle_diameter(pa_calib_values[i].nozzle_diameter)).ToStdString(); j["print"]["filaments"][i]["nozzle_diameter"] = to_string_nozzle_diameter(pa_calib_values[i].nozzle_diameter); j["print"]["filaments"][i]["ams_id"] = pa_calib_values[i].ams_id; j["print"]["filaments"][i]["slot_id"] = pa_calib_values[i].slot_id; j["print"]["filaments"][i]["filament_id"] = pa_calib_values[i].filament_id; j["print"]["filaments"][i]["setting_id"] = pa_calib_values[i].setting_id; j["print"]["filaments"][i]["name"] = pa_calib_values[i].name; j["print"]["filaments"][i]["k_value"] = std::to_string(pa_calib_values[i].k_value); if (is_auto_cali) j["print"]["filaments"][i]["n_coef"] = std::to_string(pa_calib_values[i].n_coef); else j["print"]["filaments"][i]["n_coef"] = "0.0"; } BOOST_LOG_TRIVIAL(info) << "extrusion_cali_set: " << j.dump(); return this->publish_json(j); } return -1; } int MachineObject::command_delete_pa_calibration(const PACalibIndexInfo& pa_calib) { json j; j["print"]["command"] = "extrusion_cali_del"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["extruder_id"] = pa_calib.extruder_id; j["print"]["nozzle_id"] = _generate_nozzle_id(pa_calib.nozzle_volume_type, to_string_nozzle_diameter(pa_calib.nozzle_diameter)).ToStdString(); j["print"]["filament_id"] = pa_calib.filament_id; j["print"]["cali_idx"] = pa_calib.cali_idx; j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_calib.nozzle_diameter); BOOST_LOG_TRIVIAL(info) << "extrusion_cali_del: " << j.dump(); return this->publish_json(j); } int MachineObject::command_get_pa_calibration_tab(const PACalibExtruderInfo &calib_info) { reset_pa_cali_history_result(); json j; j["print"]["command"] = "extrusion_cali_get"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["filament_id"] = calib_info.filament_id; if (calib_info.use_extruder_id) j["print"]["extruder_id"] = calib_info.extruder_id; if (calib_info.use_nozzle_volume_type) j["print"]["nozzle_id"] = _generate_nozzle_id(calib_info.nozzle_volume_type, to_string_nozzle_diameter(calib_info.nozzle_diameter)).ToStdString(); j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(calib_info.nozzle_diameter); BOOST_LOG_TRIVIAL(info) << "extrusion_cali_get: " << j.dump(); request_tab_from_bbs = true; return this->publish_json(j); } int MachineObject::command_get_pa_calibration_result(float nozzle_diameter) { json j; j["print"]["command"] = "extrusion_cali_get_result"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(nozzle_diameter); BOOST_LOG_TRIVIAL(info) << "extrusion_cali_get_result: " << j.dump(); return this->publish_json(j); } int MachineObject::commnad_select_pa_calibration(const PACalibIndexInfo& pa_calib_info) { json j; j["print"]["command"] = "extrusion_cali_sel"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["tray_id"] = pa_calib_info.tray_id; j["print"]["ams_id"] = pa_calib_info.ams_id; j["print"]["slot_id"] = pa_calib_info.slot_id; j["print"]["cali_idx"] = pa_calib_info.cali_idx; j["print"]["filament_id"] = pa_calib_info.filament_id; j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(pa_calib_info.nozzle_diameter); BOOST_LOG_TRIVIAL(info) << "extrusion_cali_sel: " << j.dump(); return this->publish_json(j); } int MachineObject::command_start_flow_ratio_calibration(const X1CCalibInfos& calib_data) { CNumericLocalesSetter locales_setter; if (calib_data.calib_datas.size() > 0) { json j; j["print"]["command"] = "flowrate_cali"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["tray_id"] = calib_data.calib_datas[0].tray_id; j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(calib_data.calib_datas[0].nozzle_diameter); std::string filament_ids; for (int i = 0; i < calib_data.calib_datas.size(); ++i) { j["print"]["filaments"][i]["tray_id"] = calib_data.calib_datas[i].tray_id; j["print"]["filaments"][i]["bed_temp"] = calib_data.calib_datas[i].bed_temp; j["print"]["filaments"][i]["filament_id"] = calib_data.calib_datas[i].filament_id; j["print"]["filaments"][i]["setting_id"] = calib_data.calib_datas[i].setting_id; j["print"]["filaments"][i]["nozzle_temp"] = calib_data.calib_datas[i].nozzle_temp; j["print"]["filaments"][i]["def_flow_ratio"] = std::to_string(calib_data.calib_datas[i].flow_rate); j["print"]["filaments"][i]["max_volumetric_speed"] = std::to_string(calib_data.calib_datas[i].max_volumetric_speed); j["print"]["filaments"][i]["extruder_id"] = calib_data.calib_datas[i].extruder_id; j["print"]["filaments"][i]["ams_id"] = calib_data.calib_datas[i].ams_id; j["print"]["filaments"][i]["slot_id"] = calib_data.calib_datas[i].slot_id; if (i > 0) filament_ids += ","; filament_ids += calib_data.calib_datas[i].filament_id; } BOOST_LOG_TRIVIAL(info) << "flowrate_cali: " << j.dump(); return this->publish_json(j); } return -1; } int MachineObject::command_get_flow_ratio_calibration_result(float nozzle_diameter) { json j; j["print"]["command"] = "flowrate_get_result"; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["print"]["nozzle_diameter"] = to_string_nozzle_diameter(nozzle_diameter); BOOST_LOG_TRIVIAL(info) << "flowrate_get_result: " << j.dump(); return this->publish_json(j); } int MachineObject::command_ipcam_record(bool on_off) { BOOST_LOG_TRIVIAL(info) << "command_ipcam_record = " << on_off; json j; j["camera"]["command"] = "ipcam_record_set"; j["camera"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["camera"]["control"] = on_off ? "enable" : "disable"; camera_recording_ctl_start = time(nullptr); this->camera_recording_when_printing = on_off; return this->publish_json(j); } int MachineObject::command_ipcam_timelapse(bool on_off) { BOOST_LOG_TRIVIAL(info) << "command_ipcam_timelapse " << on_off; json j; j["camera"]["command"] = "ipcam_timelapse"; j["camera"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["camera"]["control"] = on_off ? "enable" : "disable"; camera_timelapse_hold_count = HOLD_COUNT_CAMERA; this->camera_timelapse = on_off; return this->publish_json(j); } int MachineObject::command_ipcam_resolution_set(std::string resolution) { BOOST_LOG_TRIVIAL(info) << "command:ipcam_resolution_set" << ", resolution:" << resolution; json j; j["camera"]["command"] = "ipcam_resolution_set"; j["camera"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["camera"]["resolution"] = resolution; camera_resolution_hold_count = HOLD_COUNT_CAMERA; camera_recording_ctl_start = time(nullptr); this->camera_resolution = resolution; return this->publish_json(j); } int MachineObject::command_xcam_control(std::string module_name, bool on_off, std::string lvl) { json j; j["xcam"]["command"] = "xcam_control_set"; j["xcam"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["xcam"]["module_name"] = module_name; j["xcam"]["control"] = on_off; j["xcam"]["enable"] = on_off; //old protocol j["xcam"]["print_halt"] = true; //old protocol if (!lvl.empty()) { j["xcam"]["halt_print_sensitivity"] = lvl; } // int cfg = 123; // get_flag_bits(cfg, 11, 2); BOOST_LOG_TRIVIAL(info) << "command:xcam_control_set" << ", module_name:" << module_name << ", control:" << on_off << ", halt_print_sensitivity:" << lvl; return this->publish_json(j); } int MachineObject::command_xcam_control_ai_monitoring(bool on_off, std::string lvl) { bool print_halt = (lvl == "never_halt") ? false:true; xcam_ai_monitoring = on_off; xcam_ai_monitoring_hold_start = time(nullptr); xcam_ai_monitoring_sensitivity = lvl; return command_xcam_control("printing_monitor", on_off, lvl); } // refine printer function options int MachineObject::command_xcam_control_spaghetti_detection(bool on_off, std::string lvl) { bool print_halt = (lvl == "never_halt") ? false : true; xcam_spaghetti_detection = on_off; xcam_ai_monitoring_hold_start = time(nullptr); xcam_spaghetti_detection_sensitivity = lvl; return command_xcam_control("spaghetti_detector", on_off, lvl); } int MachineObject::command_xcam_control_purgechutepileup_detection(bool on_off, std::string lvl) { bool print_halt = (lvl == "never_halt") ? false : true; xcam_purgechutepileup_detection = on_off; xcam_ai_monitoring_hold_start = time(nullptr); xcam_purgechutepileup_detection_sensitivity = lvl; return command_xcam_control("pileup_detector", on_off, lvl); } int MachineObject::command_xcam_control_nozzleclumping_detection(bool on_off, std::string lvl) { bool print_halt = (lvl == "never_halt") ? false : true; xcam_nozzleclumping_detection = on_off; xcam_ai_monitoring_hold_start = time(nullptr); xcam_nozzleclumping_detection_sensitivity = lvl; return command_xcam_control("clump_detector", on_off, lvl); } int MachineObject::command_xcam_control_airprinting_detection(bool on_off, std::string lvl) { bool print_halt = (lvl == "never_halt") ? false : true; xcam_airprinting_detection = on_off; xcam_ai_monitoring_hold_start = time(nullptr); xcam_airprinting_detection_sensitivity = lvl; return command_xcam_control("airprint_detector", on_off, lvl); } int MachineObject::command_xcam_control_buildplate_marker_detector(bool on_off) { xcam_buildplate_marker_detector = on_off; xcam_buildplate_marker_hold_start = time(nullptr); return command_xcam_control("buildplate_marker_detector", on_off); } int MachineObject::command_xcam_control_first_layer_inspector(bool on_off, bool print_halt) { xcam_first_layer_inspector = on_off; xcam_first_layer_hold_start = time(nullptr); return command_xcam_control("first_layer_inspector", on_off); } int MachineObject::command_xcam_control_auto_recovery_step_loss(bool on_off) { xcam_auto_recovery_step_loss = on_off; xcam_auto_recovery_hold_start = time(nullptr); return command_set_printing_option(on_off); } int MachineObject::command_xcam_control_allow_prompt_sound(bool on_off) { xcam_allow_prompt_sound = on_off; xcam_prompt_sound_hold_start = time(nullptr); return command_set_prompt_sound(on_off); } int MachineObject::command_xcam_control_filament_tangle_detect(bool on_off) { xcam_filament_tangle_detect = on_off; xcam_filament_tangle_detect_hold_start = time(nullptr); return command_set_filament_tangle_detect(on_off); } void MachineObject::set_bind_status(std::string status) { bind_user_name = status; } std::string MachineObject::get_bind_str() { std::string default_result = "N/A"; if (bind_user_name.compare("null") == 0) { return "Free"; } else if (!bind_user_name.empty()) { return bind_user_name; } return default_result; } bool MachineObject::can_print() { if (print_status.compare("RUNNING") == 0) { return false; } if (print_status.compare("IDLE") == 0 || print_status.compare("FINISH") == 0) { return true; } return true; } bool MachineObject::can_resume() { if (print_status.compare("PAUSE") == 0) return true; return false; } bool MachineObject::can_pause() { if (print_status.compare("RUNNING") == 0) return true; return false; } bool MachineObject::can_abort() { return MachineObject::is_in_printing_status(print_status); } bool MachineObject::is_in_printing_status(std::string status) { if (status.compare("PAUSE") == 0 || status.compare("RUNNING") == 0 || status.compare("SLICING") == 0 || status.compare("PREPARE") == 0) { return true; } return false; } bool MachineObject::is_in_printing() { /* use print_status if print_status is valid */ if (!print_status.empty()) return MachineObject::is_in_printing_status(print_status); else { return MachineObject::is_in_printing_status(iot_print_status); } return false; } bool MachineObject::is_in_prepare() { return print_status == "PREPARE"; } bool MachineObject::is_in_printing_pause() const { return print_status == "PAUSE"; } bool MachineObject::is_printing_finished() { if (print_status.compare("FINISH") == 0 || print_status.compare("FAILED") == 0) { return true; } return false; } bool MachineObject::is_core_xy() { if (get_printer_arch() == PrinterArch::ARCH_CORE_XY) return true; return false; } void MachineObject::reset_update_time() { BOOST_LOG_TRIVIAL(trace) << "reset reset_update_time, dev_id =" << dev_id; last_update_time = std::chrono::system_clock::now(); subscribe_counter = SUBSCRIBE_RETRY_COUNT; } void MachineObject::reset() { BOOST_LOG_TRIVIAL(trace) << "reset dev_id=" << dev_id; last_update_time = std::chrono::system_clock::now(); subscribe_counter = SUBSCRIBE_RETRY_COUNT; m_push_count = 0; m_full_msg_count = 0; is_220V_voltage = false; get_version_retry = 0; camera_recording = false; camera_recording_when_printing = false; camera_timelapse = false; //camera_resolution = ""; printing_speed_mag = 100; gcode_file_prepare_percent = 0; iot_print_status = ""; print_status = ""; last_mc_print_stage = -1; m_new_ver_list_exist = false; network_wired = false; dev_connection_name = ""; job_id_ = ""; jobState_ = 0; m_plate_index = -1; // reset print_json json empty_j; print_json.diff2all_base_reset(empty_j); for (auto i = 0; i < vt_slot.size(); i++) { vt_slot[i].reset(); if (i == 1) { vt_slot.erase(vt_slot.begin() + 1); } } subtask_ = nullptr; } void MachineObject::set_print_state(std::string status) { print_status = status; } int MachineObject::connect(bool use_openssl) { if (get_dev_ip().empty()) return -1; std::string username = "bblp"; std::string password = get_access_code(); if (m_agent) { try { return m_agent->connect_printer(get_dev_id(), get_dev_ip(), username, password, use_openssl); } catch (...) { ; } } return -1; } int MachineObject::disconnect() { if (m_agent) { return m_agent->disconnect_printer(); } return -1; } bool MachineObject::is_connected() { std::chrono::system_clock::time_point curr_time = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(curr_time - last_update_time); if (diff.count() > DISCONNECT_TIMEOUT) { BOOST_LOG_TRIVIAL(trace) << "machine_object: dev_id=" << dev_id <<", diff count = " << diff.count(); return false; } if (!is_lan_mode_printer()) { NetworkAgent* m_agent = Slic3r::GUI::wxGetApp().getAgent(); if (m_agent) { return m_agent->is_server_connected(); } } return true; } bool MachineObject::is_connecting() { return is_connected() && m_push_count == 0; } void MachineObject::set_online_state(bool on_off) { m_is_online = on_off; if (!on_off) m_active_state = NotActive; } bool MachineObject::is_info_ready(bool check_version) const { if (check_version && module_vers.empty()) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << ": not ready, failed to check version"; return false; } std::chrono::system_clock::time_point curr_time = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(last_push_time - curr_time); if (m_full_msg_count > 0 && m_push_count > 0 && diff.count() < PUSHINFO_TIMEOUT) { return true; } BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << ": not ready, m_full_msg_count=" << m_full_msg_count << ", m_push_count=" << m_push_count << ", diff.count()=" << diff.count() << ", dev_id=" << dev_id; return false; } std::vector MachineObject::get_resolution_supported() { return camera_resolution_supported; } std::vector MachineObject::get_compatible_machine() { return DevPrinterConfigUtil::get_compatible_machine(printer_type); } bool MachineObject::is_camera_busy_off() { if (get_printer_series() == PrinterSeries::SERIES_P1P) return is_in_prepare() || is_in_upgrading(); return false; } int MachineObject::publish_json(const json& json_item, int qos, int flag) { int rtn = 0; if (is_lan_mode_printer()) { rtn = local_publish_json(json_item.dump(), qos, flag); } else { rtn = cloud_publish_json(json_item.dump(), qos, flag); } if (rtn == 0) { BOOST_LOG_TRIVIAL(info) << "publish_json: " << json_item.dump() << " code: " << rtn; } else { BOOST_LOG_TRIVIAL(error) << "publish_json: " << json_item.dump() << " code: " << rtn; } return rtn; } int MachineObject::cloud_publish_json(std::string json_str, int qos, int flag) { int result = -1; if (m_agent) result = m_agent->send_message(get_dev_id(), json_str, qos, flag); return result; } int MachineObject::local_publish_json(std::string json_str, int qos, int flag) { int result = -1; if (m_agent) { result = m_agent->send_message_to_printer(get_dev_id(), json_str, qos, flag); } return result; } std::string MachineObject::setting_id_to_type(std::string setting_id, std::string tray_type) { std::string type; PresetBundle* preset_bundle = GUI::wxGetApp().preset_bundle; if (preset_bundle) { for (auto it = preset_bundle->filaments.begin(); it != preset_bundle->filaments.end(); it++) { if (it->filament_id.compare(setting_id) == 0 && it->is_system) { std::string display_filament_type; it->config.get_filament_type(display_filament_type); type = display_filament_type; break; } } } if (tray_type != type || type.empty()) { if (type.empty()) { type = tray_type; } BOOST_LOG_TRIVIAL(info) << "The values of tray_info_idx and tray_type do not match tray_info_idx " << setting_id << " tray_type " << tray_type << " system_type" << type; } return type; } template static ENUM enum_index_of(char const *key, char const **enum_names, int enum_count, ENUM defl = static_cast(0)) { for (int i = 0; i < enum_count; ++i) if (strcmp(enum_names[i], key) == 0) return static_cast(i); return defl; } int MachineObject::parse_json(std::string tunnel, std::string payload, bool key_field_only) { #ifdef ORCA_NETWORK_DEBUG BOOST_LOG_TRIVIAL(info) << "parse_json: payload = " << payload; flush_logs(); #endif parse_msg_count++; std::chrono::system_clock::time_point clock_start = std::chrono::system_clock::now(); this->set_online_state(true); std::chrono::system_clock::time_point curr_time = std::chrono::system_clock::now(); auto diff1 = std::chrono::duration_cast(curr_time - last_update_time); /* update last received time */ last_update_time = std::chrono::system_clock::now(); json j_pre; bool parse_ok = false; try { j_pre = json::parse(payload); parse_ok = true; } catch(...) { parse_ok = false; /* post process payload */ sanitizeToUtf8(payload); BOOST_LOG_TRIVIAL(info) << "parse_json: sanitize to utf8"; } try { bool restored_json = false; json j; if (!parse_ok) j_pre = json::parse(payload); CNumericLocalesSetter locales_setter; if (j_pre.empty()) { return 0; } if (j_pre.contains("print")) { if (m_active_state == NotActive) m_active_state = Active; if (j_pre["print"].contains("command")) { if (j_pre["print"]["command"].get() == "push_status") { if (j_pre["print"].contains("msg")) { if (j_pre["print"]["msg"].get() == 0) { //all message BOOST_LOG_TRIVIAL(trace) << "static: get push_all msg, dev_id=" << dev_id; m_push_count++; m_full_msg_count++; if (!printer_type.empty()) print_json.load_compatible_settings(printer_type, ""); print_json.diff2all_base_reset(j_pre); } else if (j_pre["print"]["msg"].get() == 1) { //diff message if (print_json.diff2all(j_pre, j) == 0) { restored_json = true; } else { BOOST_LOG_TRIVIAL(trace) << "parse_json: restore failed! count = " << parse_msg_count; if (print_json.is_need_request()) { BOOST_LOG_TRIVIAL(trace) << "parse_json: need request pushall, count = " << parse_msg_count; // request new push GUI::wxGetApp().CallAfter([this]{ this->command_request_push_all(); }); return -1; } return -1; } } else { BOOST_LOG_TRIVIAL(warning) << "unsupported msg_type=" << j_pre["print"]["msg"].get(); } } else { if (!printer_type.empty()) { m_full_msg_count++;/* all message package is full at LAN mode*/ print_json.load_compatible_settings(printer_type, ""); } print_json.diff2all_base_reset(j_pre); } } } } if (j_pre.contains("system")) { if (j_pre["system"].contains("command")) { if (j_pre["system"]["command"].get() == "get_access_code") { if (j_pre["system"].contains("access_code")) { std::string access_code = j_pre["system"]["access_code"].get(); if (!access_code.empty()) { set_access_code(access_code); set_user_access_code(access_code); } } } } } if (!restored_json) { j = j_pre; } uint64_t t_utc = j.value("t_utc", 0ULL); if (t_utc > 0) { last_utc_time = std::chrono::system_clock::time_point(t_utc * 1ms); std::chrono::system_clock::time_point now = std::chrono::system_clock::now(); auto millisec_since_epoch = std::chrono::duration_cast(now.time_since_epoch()).count(); auto delay = millisec_since_epoch - t_utc; //ms std::string message_type = is_lan_mode_printer() ? "Local Mqtt" : is_tunnel_mqtt ? "Tunnel Mqtt" : "Cloud Mqtt"; if (!message_delay.empty()) { const auto& [first_type, first_time_stamp, first_delay] = message_delay.front(); const auto& [last_type, last_time_stap, last_delay] = message_delay.back(); BOOST_LOG_TRIVIAL(debug) << __FUNCTION__ << ", message delay, last time stamp: " << last_time_stap; if (last_time_stap - first_time_stamp >= MINUTE_30) { // record, excluding current data int total = message_delay.size(); int local_mqtt = 0; int tunnel_mqtt = 0; int cloud_mqtt = 0; int local_mqtt_timeout = 0; int tunnel_mqtt_timeout = 0; int cloud_mqtt_timeout = 0; for (const auto& [type, time_stamp, delay] : message_delay) { if (type == "Local Mqtt") { local_mqtt++; if (delay >= TIME_OUT) { local_mqtt_timeout++; } } else if (type == "Tunnel Mqtt") { tunnel_mqtt++; if (delay >= TIME_OUT) { tunnel_mqtt_timeout++; } } else if (type == "Cloud Mqtt"){ cloud_mqtt++; if (delay >= TIME_OUT) { cloud_mqtt_timeout++; } } } BOOST_LOG_TRIVIAL(debug) << __FUNCTION__ << ", message delay, message total: " << total; message_delay.clear(); message_delay.shrink_to_fit(); } } message_delay.push_back(std::make_tuple(message_type, t_utc, delay)); } else last_utc_time = last_update_time; #if !BBL_RELEASE_TO_PUBLIC BOOST_LOG_TRIVIAL(info) << "parse_json: dev_id=" << dev_id << ", tunnel is=" << tunnel << ", merged playload=" << j.dump(); #else if (Slic3r::get_logging_level() < level_string_to_boost("trace")) { BOOST_LOG_TRIVIAL(info) << "parse_json: dev_id=" << dev_id << ", origin playload=" << j_pre.dump(); } else { BOOST_LOG_TRIVIAL(trace) << "parse_json: dev_id=" << dev_id << ", tunnel is=" << tunnel << ", merged playload=" << j.dump(); } #endif // Parse version info first, as if version arrive or change, 'print' need parse again with new compatible settings try { if (j.contains("info")) { if (j["info"].contains("command") && j["info"]["command"].get() == "get_version") { json j_module = j["info"]["module"]; clear_version_info(); for (auto it = j_module.begin(); it != j_module.end(); it++) { DevFirmwareVersionInfo ver_info; ver_info.name = (*it)["name"].get(); if ((*it).contains("product_name")) ver_info.product_name = wxString::FromUTF8((*it)["product_name"].get()); if ((*it).contains("sw_ver")) ver_info.sw_ver = (*it)["sw_ver"].get(); if ((*it).contains("sw_new_ver")) ver_info.sw_new_ver = (*it)["sw_new_ver"].get(); if ((*it).contains("visible") && (*it).contains("new_ver")) { ver_info.sw_new_ver = (*it)["new_ver"].get(); } if ((*it).contains("sn")) ver_info.sn = (*it)["sn"].get(); if ((*it).contains("hw_ver")) ver_info.hw_ver = (*it)["hw_ver"].get(); if((*it).contains("flag")) ver_info.firmware_flag= (*it)["flag"].get(); store_version_info(ver_info); if (ver_info.name == "ota") { NetworkAgent* agent = GUI::wxGetApp().getAgent(); if (agent) { std::string dev_ota_str = "dev_ota_ver:" + this->get_dev_id(); agent->track_update_property(dev_ota_str, ver_info.sw_ver); } } } parse_version_func(); bool get_version_result = true; if (j["info"].contains("result")) if (j["info"]["result"].get() == "fail") get_version_result = false; if ((!check_version_valid() && get_version_retry-- >= 0) && get_version_result) { BOOST_LOG_TRIVIAL(info) << "get_version_retry = " << get_version_retry; boost::thread retry = boost::thread([this] { boost::this_thread::sleep_for(boost::chrono::milliseconds(RETRY_INTERNAL)); GUI::wxGetApp().CallAfter([this] { this->command_get_version(false); }); }); } } std::string version = parse_version(); if (!version.empty() && print_json.load_compatible_settings(printer_type, version)) { // reload because compatible settings changed j.clear(); print_json.diff2all(json{}, j); } } } catch (...) {} if (j.contains("print")) { json jj = j["print"]; int sequence_id = 0; if (jj.contains("sequence_id")) { if (jj["sequence_id"].is_string()) { std::string str_seq = jj["sequence_id"].get(); try { sequence_id = stoi(str_seq); } catch(...) { ; } } } if (!key_field_only) { if (!m_manager->IsMultiMachineEnabled() && !is_support_agora) { if (jj.contains("support_tunnel_mqtt")) { if (jj["support_tunnel_mqtt"].is_boolean()) { is_support_tunnel_mqtt = jj["support_tunnel_mqtt"].get(); } } } //nozzle temp range if (jj.contains("nozzle_temp_range")) { if (jj["nozzle_temp_range"].is_array()) { nozzle_temp_range.clear(); for (auto it = jj["nozzle_temp_range"].begin(); it != jj["nozzle_temp_range"].end(); it++) { nozzle_temp_range.push_back(it.value().get()); } } } // bed temp range if (jj.contains("bed_temp_range")) { if (jj["bed_temp_range"].is_array()) { bed_temp_range.clear(); for (auto it = jj["bed_temp_range"].begin(); it != jj["bed_temp_range"].end(); it++) { bed_temp_range.push_back(it.value().get()); } } } //supported function m_config->ParseConfig(jj); if (jj.contains("support_build_plate_marker_detect")) { if (jj["support_build_plate_marker_detect"].is_boolean()) { is_support_build_plate_marker_detect = jj["support_build_plate_marker_detect"].get(); } } if(jj.contains("support_build_plate_marker_detect_type") && jj["support_build_plate_marker_detect_type"].is_number()) { m_plate_maker_detect_type = (PlateMakerDectect)jj["support_build_plate_marker_detect_type"].get(); } if (jj.contains("support_flow_calibration") && jj["support_flow_calibration"].is_boolean()) { is_support_pa_calibration = jj["support_flow_calibration"].get(); } if (jj.contains("support_send_to_sd")) { if (jj["support_send_to_sd"].is_boolean()) { is_support_send_to_sdcard = jj["support_send_to_sd"].get(); } } m_fan->ParseV2_0(jj); if (jj.contains("support_filament_backup")) { if (jj["support_filament_backup"].is_boolean()) { is_support_filament_backup = jj["support_filament_backup"].get(); } } if (jj.contains("support_update_remain")) { if (jj["support_update_remain"].is_boolean()) { is_support_update_remain = jj["support_update_remain"].get(); } } if (jj.contains("support_bed_leveling")) { if (jj["support_bed_leveling"].is_number_integer()) { is_support_bed_leveling = jj["support_bed_leveling"].get(); } } if (jj.contains("support_auto_recovery_step_loss")) { if (jj["support_auto_recovery_step_loss"].is_boolean()) { is_support_auto_recovery_step_loss = jj["support_auto_recovery_step_loss"].get(); } } if (jj.contains("support_ams_humidity")) { if (jj["support_ams_humidity"].is_boolean()) { is_support_ams_humidity = jj["support_ams_humidity"].get(); } } if (jj.contains("support_prompt_sound")) { if (jj["support_prompt_sound"].is_boolean()) { is_support_prompt_sound = jj["support_prompt_sound"].get(); } } if (jj.contains("support_filament_tangle_detect")) { if (jj["support_filament_tangle_detect"].is_boolean()) { is_support_filament_tangle_detect = jj["support_filament_tangle_detect"].get(); } } if (jj.contains("support_1080dpi")) { if (jj["support_1080dpi"].is_boolean()) { is_support_1080dpi = jj["support_1080dpi"].get(); } } if (jj.contains("support_cloud_print_only")) { if (jj["support_cloud_print_only"].is_boolean()) { is_support_cloud_print_only = jj["support_cloud_print_only"].get(); } } if (jj.contains("support_command_ams_switch")) { if (jj["support_command_ams_switch"].is_boolean()) { is_support_command_ams_switch = jj["support_command_ams_switch"].get(); } } if (jj.contains("support_mqtt_alive")) { if (jj["support_mqtt_alive"].is_boolean()) { is_support_mqtt_alive = jj["support_mqtt_alive"].get(); } } if (jj.contains("support_motor_noise_cali")) { if (jj["support_motor_noise_cali"].is_boolean()) { is_support_motor_noise_cali = jj["support_motor_noise_cali"].get(); } } if (jj.contains("support_timelapse")) { if (jj["support_timelapse"].is_boolean()) { is_support_timelapse = jj["support_timelapse"].get(); } } if (jj.contains("support_user_preset")) { if (jj["support_user_preset"].is_boolean()) { is_support_user_preset = jj["support_user_preset"].get(); } } if (jj.contains("bed_temperature_limit")) { if (jj["bed_temperature_limit"].is_number_integer()) { bed_temperature_limit = jj["bed_temperature_limit"].get(); } } } if (jj.contains("command")) { if (jj["command"].get() == "ams_change_filament") { if (jj.contains("errno")) { if (jj["errno"].is_number()) { if (jj.contains("soft_temp")) { int soft_temp = jj["soft_temp"].get(); if (jj["errno"].get() == -2) { wxString text = wxString::Format(_L("The chamber temperature is too high, which may cause the filament to soften. Please wait until the chamber temperature drops below %d\u2103. You may open the front door or enable fans to cool down."), soft_temp); GUI::wxGetApp().push_notification(this, text); } else if (jj["errno"].get() == -4) { wxString text = wxString::Format(_L("AMS temperature is too high, which may cause the filament to soften. Please wait until the AMS temperature drops below %d\u2103."), soft_temp); GUI::wxGetApp().push_notification(this, text); } } else { if (jj["errno"].get() == -2) { wxString text = _L("The current chamber temperature or the target chamber temperature exceeds 45\u2103. In order to avoid extruder clogging,low temperature filament(PLA/PETG/TPU) is not allowed to be loaded."); GUI::wxGetApp().push_notification(this, text); } } } } } if (jj["command"].get() == "set_ctt") { if (m_agent && is_studio_cmd(sequence_id)) { if (jj["errno"].is_number()) { wxString text; if (jj["errno"].get() == -2) { text = _L("Low temperature filament(PLA/PETG/TPU) is loaded in the extruder.In order to avoid extruder clogging,it is not allowed to set the chamber temperature."); } else if (jj["errno"].get() == -4) { text = _L("When you set the chamber temperature below 40\u2103, the chamber temperature control will not be activated, " "and the target chamber temperature will automatically be set to 0\u2103." /* 0°C */); } if(!text.empty()){ #if __WXOSX__ set_ctt_dlg(text); #else GUI::wxGetApp().push_notification(this, text); #endif } } } } if (!key_field_only) { if (is_studio_cmd(sequence_id) && jj.contains("command") && jj.contains("err_code") && jj.contains("result")) { if (jj["err_code"].is_number()) { add_command_error_code_dlg(jj["err_code"].get());} } } if (jj["command"].get() == "push_status") { m_push_count++; last_push_time = last_update_time; #pragma region printing // U0 firmware if (jj.contains("print_type")) { print_type = jj["print_type"].get(); } if (jj.contains("mc_percent")) { if (jj["mc_percent"].is_string()) mc_print_percent = stoi(j["print"]["mc_percent"].get()); else if (jj["mc_percent"].is_number_integer()) mc_print_percent = j["print"]["mc_percent"].get(); } if (jj.contains("mc_print_sub_stage")) { if (jj["mc_print_sub_stage"].is_number_integer()) mc_print_sub_stage = j["print"]["mc_print_sub_stage"].get(); } /* printing */ if (jj.contains("mc_print_stage")) { if (jj["mc_print_stage"].is_string()) mc_print_stage = atoi(jj["mc_print_stage"].get().c_str()); if (jj["mc_print_stage"].is_number()) mc_print_stage = jj["mc_print_stage"].get(); } if (jj.contains("mc_print_error_code")) { if (jj["mc_print_error_code"].is_number()) mc_print_error_code = jj["mc_print_error_code"].get(); } if (jj.contains("mc_remaining_time")) { if (jj["mc_remaining_time"].is_string()) mc_left_time = stoi(j["print"]["mc_remaining_time"].get()) * 60; else if (jj["mc_remaining_time"].is_number_integer()) mc_left_time = j["print"]["mc_remaining_time"].get() * 60; } if (jj.contains("print_error")) { if (jj["print_error"].is_number()) print_error = jj["print_error"].get(); } DevStorage::ParseV1_0(jj, m_storage); if (!key_field_only) { if (jj.contains("home_flag")) { home_flag = jj["home_flag"].get(); parse_status(home_flag); } /*the param is invalid in np for Yeshu*/ if (jj.contains("hw_switch_state")) { hw_switch_state = jj["hw_switch_state"].get(); m_extder_system->m_extders[MAIN_EXTRUDER_ID].m_ext_has_filament = hw_switch_state; } if (jj.contains("mc_print_line_number")) { if (jj["mc_print_line_number"].is_string() && !jj["mc_print_line_number"].is_null()) mc_print_line_number = atoi(jj["mc_print_line_number"].get().c_str()); } } if (!key_field_only) { if (jj.contains("flag3")) { int flag3 = jj["flag3"].get(); is_support_filament_setting_inprinting = get_flag_bits(flag3, 3); is_enable_ams_np = get_flag_bits(flag3, 9); } } if (!key_field_only) { if (jj.contains("net")) { if (jj["net"].contains("conf")) { network_wired = (jj["net"]["conf"].get() & (0x1)) != 0; } if (jj["net"].contains("info")) { for (auto info_item = jj["net"]["info"].begin(); info_item != jj["net"]["info"].end(); info_item++) { if (info_item->contains("ip")) { auto tmp_dev_ip = (*info_item)["ip"].get(); if (tmp_dev_ip == 0) continue ; else { set_dev_ip(DevUtil::convertToIp(tmp_dev_ip)); } } else { break; } } } } } #pragma endregion #pragma region online if (!key_field_only) { // parse online info try { if (jj.contains("online")) { if (jj["online"].contains("ahb")) { if (jj["online"]["ahb"].get()) { online_ahb = true; } else { online_ahb = false; } } if (jj["online"].contains("rfid")) { if (jj["online"]["rfid"].get()) { online_rfid = true; } else { online_rfid = false; } } std::string str = jj.dump(); if (jj["online"].contains("version")) { online_version = jj["online"]["version"].get(); } if (last_online_version != online_version) { last_online_version = online_version; GUI::wxGetApp().CallAfter([this] { this->command_get_version(); }); } } } catch (...) { ; } } #pragma endregion #pragma region print_task if (jj.contains("gcode_state")) { this->set_print_state(jj["gcode_state"].get()); } if (jj.contains("job_id")) { is_support_wait_sending_finish = true; this->job_id_ = DevJsonValParser::get_longlong_val(jj["job_id"]); } else { is_support_wait_sending_finish = false; } if (jj.contains("subtask_name")) { subtask_name = jj["subtask_name"].get(); } if (!key_field_only) { if (jj.contains("printer_type")) { printer_type = _parse_printer_type(jj["printer_type"].get()); } if (jj.contains("layer_num")) { curr_layer = jj["layer_num"].get(); } if (jj.contains("total_layer_num")) { total_layers = jj["total_layer_num"].get(); if (total_layers == 0) is_support_layer_num = false; else is_support_layer_num = true; } else { is_support_layer_num = false; } if (jj.contains("queue_number")) { this->queue_number = jj["queue_number"].get(); } else { this->queue_number = 0; } if (jj.contains("task_id")) { this->task_id_ = jj["task_id"].get(); } if (jj.contains("job_attr")) { int jobAttr = jj["job_attr"].get(); jobState_ = get_flag_bits(jobAttr, 4, 4); } if (jj.contains("gcode_file")) this->m_gcode_file = jj["gcode_file"].get(); if (jj.contains("gcode_file_prepare_percent")) { std::string percent_str = jj["gcode_file_prepare_percent"].get(); if (!percent_str.empty()) { try { this->gcode_file_prepare_percent = atoi(percent_str.c_str()); } catch (...) {} } } } if (jj.contains("project_id") && jj.contains("profile_id") && jj.contains("subtask_id") ) { obj_subtask_id = jj["subtask_id"].get(); int plate_index = -1; /* parse local plate_index from task */ if (obj_subtask_id.compare("0") == 0 && jj["profile_id"].get() != "0") { if (jj.contains("gcode_file")) { m_gcode_file = jj["gcode_file"].get(); int idx_start = m_gcode_file.find_last_of("_") + 1; int idx_end = m_gcode_file.find_last_of("."); if (idx_start > 0 && idx_end > idx_start) { try { plate_index = atoi(m_gcode_file.substr(idx_start, idx_end - idx_start).c_str()); this->m_plate_index = plate_index; } catch (...) { ; } } } } update_slice_info(jj["project_id"].get(), jj["profile_id"].get(), jj["subtask_id"].get(), plate_index); BBLSubTask* curr_task = get_subtask(); if (curr_task) { curr_task->task_progress = mc_print_percent; curr_task->printing_status = print_status; curr_task->task_id = jj["subtask_id"].get(); } } #pragma endregion #pragma region status if (!key_field_only) { /* temperature */ DevBed::ParseV1_0(jj,m_bed); if (jj.contains("frame_temper")) { if (jj["frame_temper"].is_number()) { frame_temp = jj["frame_temper"].get(); } } ExtderSystemParser::ParseV1_0(jj, m_extder_system); if (jj.contains("chamber_temper")) { if (jj["chamber_temper"].is_number()) { chamber_temp = jj["chamber_temper"].get(); } } if (jj.contains("ctt")) { if (jj["ctt"].is_number()) { chamber_temp_target = jj["ctt"].get(); } } /* signals */ if (jj.contains("link_th_state")) link_th = jj["link_th_state"].get(); if (jj.contains("link_ams_state")) link_ams = jj["link_ams_state"].get(); if (jj.contains("wifi_signal")) wifi_signal = jj["wifi_signal"].get(); /* cooling */ m_fan->ParseV1_0(jj); /* parse speed */ DevPrintOptionsParser::Parse(m_print_options, jj); try { if (jj.contains("spd_mag")) { printing_speed_mag = jj["spd_mag"].get(); } } catch (...) { ; } } try { if (jj.contains("stg")) { stage_list_info.clear(); if (jj["stg"].is_array()) { for (auto it = jj["stg"].begin(); it != jj["stg"].end(); it++) { for (auto kv = (*it).begin(); kv != (*it).end(); kv++) { stage_list_info.push_back(kv.value().get()); } } } } if (jj.contains("stg_cur")) { stage_curr = jj["stg_cur"].get(); } } catch (...) { ; } if (!key_field_only) { /*get filam_bak*/ try { m_extder_system->m_extders[MAIN_EXTRUDER_ID].m_filam_bak.clear(); if (jj.contains("filam_bak")) { if (jj["filam_bak"].is_array()) { for (auto it = jj["filam_bak"].begin(); it != jj["filam_bak"].end(); it++) { const auto& filam_bak_val = it.value().get(); m_extder_system->m_extders[MAIN_EXTRUDER_ID].m_filam_bak.push_back(filam_bak_val); } } } } catch (...) { ; } /* get fimware type */ try { if (jj.contains("mess_production_state")) { if (jj["mess_production_state"].get() == "engineer") firmware_type = PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER; else if (jj["mess_production_state"].get() == "product") firmware_type = PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION; } } catch (...) { ; } } if (!key_field_only) { try { if (jj.contains("lifecycle")) { if (jj["lifecycle"].get() == "engineer") lifecycle = PrinterFirmwareType::FIRMWARE_TYPE_ENGINEER; else if (jj["lifecycle"].get() == "product") lifecycle = PrinterFirmwareType::FIRMWARE_TYPE_PRODUCTION; } } catch (...) { ; } try { if (jj.contains("lights_report") && jj["lights_report"].is_array()) { for (auto it = jj["lights_report"].begin(); it != jj["lights_report"].end(); it++) { if ((*it)["node"].get().compare("chamber_light") == 0) { m_lamp->SetChamberLight((*it)["mode"].get()); } } } } catch (...) { ; } } #pragma endregion if (!key_field_only) { if (jj.contains("nozzle_diameter") && jj.contains("nozzle_type")) { DevNozzleSystemParser::ParseV1_0(jj["nozzle_type"], jj["nozzle_diameter"], m_nozzle_system); } } #pragma region upgrade try { if (jj.contains("upgrade_state")) { if (jj["upgrade_state"].contains("status")) upgrade_status = jj["upgrade_state"]["status"].get(); if (jj["upgrade_state"].contains("progress")) { upgrade_progress = jj["upgrade_state"]["progress"].get(); } if (jj["upgrade_state"].contains("new_version_state")) upgrade_new_version = jj["upgrade_state"]["new_version_state"].get() == 1 ? true : false; if (!check_enable_np(jj) && jj["upgrade_state"].contains("ams_new_version_number"))/* is not used in new np, by AP*/ ams_new_version_number = jj["upgrade_state"]["ams_new_version_number"].get(); if (jj["upgrade_state"].contains("ota_new_version_number")) ota_new_version_number = jj["upgrade_state"]["ota_new_version_number"].get(); if (jj["upgrade_state"].contains("ahb_new_version_number")) ahb_new_version_number = jj["upgrade_state"]["ahb_new_version_number"].get(); if (jj["upgrade_state"].contains("module")) upgrade_module = jj["upgrade_state"]["module"].get(); if (jj["upgrade_state"].contains("message")) upgrade_message = jj["upgrade_state"]["message"].get(); if (jj["upgrade_state"].contains("consistency_request")) upgrade_consistency_request = jj["upgrade_state"]["consistency_request"].get(); if (jj["upgrade_state"].contains("force_upgrade")) upgrade_force_upgrade = jj["upgrade_state"]["force_upgrade"].get(); if (jj["upgrade_state"].contains("err_code")) upgrade_err_code = jj["upgrade_state"]["err_code"].get(); if (jj["upgrade_state"].contains("dis_state")) { if ((int)upgrade_display_state != jj["upgrade_state"]["dis_state"].get() && jj["upgrade_state"]["dis_state"].get() == 3) { GUI::wxGetApp().CallAfter([this] { this->command_get_version(); }); } if (upgrade_display_hold_count > 0) { upgrade_display_hold_count--; } else { upgrade_display_state = (DevFirmwareUpgradingState)jj["upgrade_state"]["dis_state"].get(); if ((upgrade_display_state == DevFirmwareUpgradingState::UpgradingAvaliable) && is_lan_mode_printer()) { upgrade_display_state = DevFirmwareUpgradingState::UpgradingUnavaliable; } } } else { if (upgrade_display_hold_count > 0) upgrade_display_hold_count--; else { //BBS compatibility with old version if (upgrade_status == "DOWNLOADING" || upgrade_status == "FLASHING" || upgrade_status == "UPGRADE_REQUEST" || upgrade_status == "PRE_FLASH_START" || upgrade_status == "PRE_FLASH_SUCCESS") { upgrade_display_state = DevFirmwareUpgradingState::UpgradingInProgress; } else if (upgrade_status == "UPGRADE_SUCCESS" || upgrade_status == "DOWNLOAD_FAIL" || upgrade_status == "FLASH_FAIL" || upgrade_status == "PRE_FLASH_FAIL" || upgrade_status == "UPGRADE_FAIL") { upgrade_display_state = DevFirmwareUpgradingState::UpgradingFinished; } else { if (upgrade_new_version) { upgrade_display_state = DevFirmwareUpgradingState::UpgradingAvaliable; } else { upgrade_display_state = DevFirmwareUpgradingState::UpgradingUnavaliable; } } } } // new ver list if (jj["upgrade_state"].contains("new_ver_list")) { m_new_ver_list_exist = true; new_ver_list.clear(); for (auto ver_item = jj["upgrade_state"]["new_ver_list"].begin(); ver_item != jj["upgrade_state"]["new_ver_list"].end(); ver_item++) { DevFirmwareVersionInfo ver_info; if (ver_item->contains("name")) ver_info.name = (*ver_item)["name"].get(); else continue; if (ver_item->contains("cur_ver")) ver_info.sw_ver = (*ver_item)["cur_ver"].get(); if (ver_item->contains("new_ver")) ver_info.sw_new_ver = (*ver_item)["new_ver"].get(); if (ver_info.name == "ota") { ota_new_version_number = ver_info.sw_new_ver; } new_ver_list.insert(std::make_pair(ver_info.name, ver_info)); } } else { new_ver_list.clear(); } } } catch (...) { ; } #pragma endregion #pragma region camera if (!key_field_only) { // parse camera info try { if (jj.contains("ipcam")) { json const & ipcam = jj["ipcam"]; if (ipcam.contains("ipcam_record")) { if (time(nullptr) - camera_recording_ctl_start > HOLD_TIME_3SEC) { if (ipcam["ipcam_record"].get() == "enable") { camera_recording_when_printing = true; } else { camera_recording_when_printing = false; } } } if (ipcam.contains("timelapse")) { if (camera_timelapse_hold_count > 0) camera_timelapse_hold_count--; else { if (ipcam["timelapse"].get() == "enable") { camera_timelapse = true; } else { camera_timelapse = false; } } } if (ipcam.contains("ipcam_dev")) { if (ipcam["ipcam_dev"].get() == "1") { has_ipcam = true; } else { has_ipcam = false; } } if (ipcam.contains("resolution")) { if (camera_resolution_hold_count > 0) camera_resolution_hold_count--; else { camera_resolution = ipcam["resolution"].get(); } } if (ipcam.contains("resolution_supported")) { std::vector resolution_supported; for (auto res : ipcam["resolution_supported"]) resolution_supported.emplace_back(res.get()); camera_resolution_supported.swap(resolution_supported); } if (ipcam.contains("liveview")) { char const *local_protos[] = {"none", "disabled", "local", "rtsps", "rtsp"}; liveview_local = enum_index_of(ipcam["liveview"].value("local", "none").c_str(), local_protos, 5, LiveviewLocal::LVL_None); char const *remote_protos[] = {"none", "tutk", "agora", "tutk_agaro"}; liveview_remote = enum_index_of(ipcam["liveview"].value("remote", "none").c_str(), remote_protos, 4, LiveviewRemote::LVR_None); } if (ipcam.contains("file")) { char const *local_protos[] = {"none", "local"}; file_local = enum_index_of(ipcam["file"].value("local", "none").c_str(), local_protos, 2, FileLocal::FL_None); char const *remote_protos[] = {"none", "tutk", "agora", "tutk_agaro"}; file_remote = enum_index_of(ipcam["file"].value("remote", "none").c_str(), remote_protos, 4, FileRemote::FR_None); file_model_download = ipcam["file"].value("model_download", "disabled") == "enabled"; } virtual_camera = ipcam.value("virtual_camera", "disabled") == "enabled"; if (ipcam.contains("rtsp_url")) { local_rtsp_url = ipcam["rtsp_url"].get(); liveview_local = local_rtsp_url.empty() ? LVL_None : local_rtsp_url == "disable" ? LVL_Disable : boost::algorithm::starts_with(local_rtsp_url, "rtsps") ? LVL_Rtsps : LVL_Rtsp; } if (ipcam.contains("tutk_server")) { tutk_state = ipcam["tutk_server"].get(); } } } catch (...) { ; } try { if (jj.contains("xcam")) { if (time(nullptr) - xcam_ai_monitoring_hold_start > HOLD_TIME_3SEC) { if (jj["xcam"].contains("cfg")) { xcam_disable_ai_detection_display = true; // std::string cfg = jj["xcam"]["cfg"].get(); int cfg = jj["xcam"]["cfg"].get(); xcam_spaghetti_detection = get_flag_bits(cfg,7); switch (get_flag_bits(cfg, 8, 2)) { case 0: xcam_spaghetti_detection_sensitivity = "low"; break; case 1: xcam_spaghetti_detection_sensitivity = "medium"; break; case 2: xcam_spaghetti_detection_sensitivity = "high"; break; default: break; } xcam_purgechutepileup_detection = get_flag_bits(cfg, 10); switch (get_flag_bits(cfg, 11, 2)) { case 0: xcam_purgechutepileup_detection_sensitivity = "low"; break; case 1: xcam_purgechutepileup_detection_sensitivity = "medium"; break; case 2: xcam_purgechutepileup_detection_sensitivity = "high"; break; default: break; } xcam_nozzleclumping_detection = get_flag_bits(cfg, 13); switch (get_flag_bits(cfg, 14, 2)) { case 0: xcam_nozzleclumping_detection_sensitivity = "low"; break; case 1: xcam_nozzleclumping_detection_sensitivity = "medium"; break; case 2: xcam_nozzleclumping_detection_sensitivity = "high"; break; default: break; } xcam_airprinting_detection = get_flag_bits(cfg, 16); switch (get_flag_bits(cfg, 17, 2)) { case 0: xcam_airprinting_detection_sensitivity = "low"; break; case 1: xcam_airprinting_detection_sensitivity = "medium"; break; case 2: xcam_airprinting_detection_sensitivity = "high"; break; default: break; } } else if (jj["xcam"].contains("printing_monitor")) { // new protocol xcam_ai_monitoring = jj["xcam"]["printing_monitor"].get(); } else { // old version protocol if (jj["xcam"].contains("spaghetti_detector")) { xcam_ai_monitoring = jj["xcam"]["spaghetti_detector"].get(); if (jj["xcam"].contains("print_halt")) { bool print_halt = jj["xcam"]["print_halt"].get(); if (print_halt) { xcam_ai_monitoring_sensitivity = "medium"; } } } } if (jj["xcam"].contains("halt_print_sensitivity")) { xcam_ai_monitoring_sensitivity = jj["xcam"]["halt_print_sensitivity"].get(); } } if (time(nullptr) - xcam_first_layer_hold_start > HOLD_TIME_3SEC) { if (jj["xcam"].contains("first_layer_inspector")) { xcam_first_layer_inspector = jj["xcam"]["first_layer_inspector"].get(); } } if (time(nullptr) - xcam_buildplate_marker_hold_start > HOLD_TIME_3SEC) { if (jj["xcam"].contains("buildplate_marker_detector")) { xcam_buildplate_marker_detector = jj["xcam"]["buildplate_marker_detector"].get(); is_support_build_plate_marker_detect = true; } else { is_support_build_plate_marker_detect = false; } } } } catch (...) { ; } } #pragma endregion #pragma region hms if (!key_field_only && jj.contains("hms")) { m_hms_system->ParseHMSItems(jj["hms"]); } #pragma endregion #pragma region push_ams /* ams status */ try { if (jj.contains("ams_status")) { int ams_status = jj["ams_status"].get(); this->_parse_ams_status(ams_status); } std::string str_j = jj.dump(); if (jj.contains("cali_version")) { cali_version = jj["cali_version"].get(); } else { cali_version = -1; } std::string str = jj.dump(); } catch (...) { ; } update_printer_preset_name(); update_filament_list(); if (jj.contains("ams")) { DevFilaSystemParser::ParseV1_0(jj, this, m_fila_system, key_field_only); } /* vitrual tray*/ if (!key_field_only) { try { if (jj.contains("vir_slot") && jj["vir_slot"].is_array()) { for (auto it = jj["vir_slot"].begin(); it != jj["vir_slot"].end(); it++) { auto vslot = parse_vt_tray(it.value().get()); if (vslot.id == std::to_string(VIRTUAL_TRAY_MAIN_ID)) { auto it = std::next(vt_slot.begin(), 0); if (it != vt_slot.end()) { vt_slot[0] = vslot; } else { vt_slot.push_back(vslot); } } else if (vslot.id == std::to_string(VIRTUAL_TRAY_DEPUTY_ID)) { auto it = std::next(vt_slot.begin(), 1); if (it != vt_slot.end()) { vt_slot[1] = vslot; } else { vt_slot.push_back(vslot); } } } } else if (jj.contains("vt_tray")) { auto main_slot = parse_vt_tray(jj["vt_tray"].get()); main_slot.id = std::to_string(VIRTUAL_TRAY_MAIN_ID); auto it = std::next(vt_slot.begin(), 0); if (it != vt_slot.end()) { vt_slot[0] = main_slot; } else { vt_slot.push_back(main_slot); } } else { ams_support_virtual_tray = false; } } catch (...) { ; } } /*parse new print data*/ try { parse_new_info(jj); } catch (...) {} #pragma endregion } else if (jj["command"].get() == "gcode_line") { //ack of gcode_line BOOST_LOG_TRIVIAL(debug) << "parse_json, ack of gcode_line = " << j.dump(4); } else if (jj["command"].get() == "project_prepare") { //ack of project file BOOST_LOG_TRIVIAL(info) << "parse_json, ack of project_prepare = " << j.dump(4); if (m_agent) { if (jj.contains("job_id")) { this->job_id_ = DevJsonValParser::get_longlong_val(jj["job_id"]); } } } else if (jj["command"].get() == "project_file") { //ack of project file BOOST_LOG_TRIVIAL(debug) << "parse_json, ack of project_file = " << j.dump(4); std::string result; if (jj.contains("result")) { result = jj["result"].get(); if (result == "FAIL") { wxString text = _L("Failed to start print job"); GUI::wxGetApp().push_notification(this, text); } } } else if (jj["command"].get() == "ams_filament_setting" && !key_field_only) { // BBS trigger ams UI update ams_version = -1; if (jj["ams_id"].is_number()) { int ams_id = jj["ams_id"].get(); int tray_id = 0; if (jj.contains("tray_id")) { tray_id = jj["tray_id"].get(); } if (ams_id == 255 && tray_id == VIRTUAL_TRAY_MAIN_ID) { BOOST_LOG_TRIVIAL(info) << "ams_filament_setting, parse tray info"; vt_slot[0].nozzle_temp_max = std::to_string(jj["nozzle_temp_max"].get()); vt_slot[0].nozzle_temp_min = std::to_string(jj["nozzle_temp_min"].get()); vt_slot[0].color = jj["tray_color"].get(); vt_slot[0].setting_id = jj["tray_info_idx"].get(); //vt_tray.type = jj["tray_type"].get(); vt_slot[0].type = setting_id_to_type(vt_slot[0].setting_id, jj["tray_type"].get()); // delay update vt_slot[0].set_hold_count(); } else { auto ams = m_fila_system->GetAmsById(std::to_string(ams_id)); if (ams) { tray_id = jj["tray_id"].get(); auto tray_it = ams->GetTrays().find(std::to_string(tray_id)); if (tray_it != ams->GetTrays().end()) { BOOST_LOG_TRIVIAL(trace) << "ams_filament_setting, parse tray info"; tray_it->second->nozzle_temp_max = std::to_string(jj["nozzle_temp_max"].get()); tray_it->second->nozzle_temp_min = std::to_string(jj["nozzle_temp_min"].get()); //tray_it->second->type = jj["tray_type"].get(); tray_it->second->color = jj["tray_color"].get(); /*tray_it->second->cols.clear(); if (jj.contains("cols")) { if (jj["cols"].is_array()) { for (auto it = jj["cols"].begin(); it != jj["cols"].end(); it++) { tray_it->second->cols.push_back(it.value().get()); } } }*/ tray_it->second->setting_id = jj["tray_info_idx"].get(); tray_it->second->type = setting_id_to_type(tray_it->second->setting_id, jj["tray_type"].get()); // delay update tray_it->second->set_hold_count(); } else { BOOST_LOG_TRIVIAL(warning) << "ams_filament_setting, can not find in trayList, tray_id=" << tray_id; } } else { BOOST_LOG_TRIVIAL(warning) << "ams_filament_setting, can not find in amsList, ams_id=" << ams_id; } } } } else if (jj["command"].get() == "xcam_control_set" && !key_field_only) { if (jj.contains("module_name")) { if (jj.contains("enable") || jj.contains("control")) { bool enable = false; if (jj.contains("enable")) enable = jj["enable"].get(); else if (jj.contains("control")) enable = jj["control"].get(); else { ; } if (jj["module_name"].get() == "first_layer_inspector") { if (time(nullptr) - xcam_first_layer_hold_start > HOLD_TIME_3SEC) { xcam_first_layer_inspector = enable; } } else if (jj["module_name"].get() == "buildplate_marker_detector") { if (time(nullptr) - xcam_buildplate_marker_hold_start > HOLD_TIME_3SEC) { xcam_buildplate_marker_detector = enable; } } else if (jj["module_name"].get() == "printing_monitor") { if (time(nullptr) - xcam_ai_monitoring_hold_start > HOLD_TIME_3SEC) { xcam_ai_monitoring = enable; if (jj.contains("halt_print_sensitivity")) { xcam_ai_monitoring_sensitivity = jj["halt_print_sensitivity"].get(); } } } else if (jj["module_name"].get() == "spaghetti_detector") { if (time(nullptr) - xcam_ai_monitoring_hold_start > HOLD_TIME_3SEC) { // old protocol xcam_ai_monitoring = enable; if (jj.contains("print_halt")) { if (jj["print_halt"].get()) { xcam_ai_monitoring_sensitivity = "medium"; } } } } } } } else if(jj["command"].get() == "print_option") { try { if (jj.contains("option")) { if (jj["option"].is_number()) { int option = jj["option"].get(); if (time(nullptr) - xcam_auto_recovery_hold_start > HOLD_TIME_3SEC) { xcam_auto_recovery_step_loss = ((option >> (int)PRINT_OP_AUTO_RECOVERY) & 0x01) != 0; } } } if (time(nullptr) - xcam_auto_recovery_hold_start > HOLD_TIME_3SEC) { if (jj.contains("auto_recovery")) { xcam_auto_recovery_step_loss = jj["auto_recovery"].get(); } } } catch(...) { } } else if (jj["command"].get() == "extrusion_cali" || jj["command"].get() == "flowrate_cali") { if (jj.contains("result")) { if (jj["result"].get() == "success") { ; } else if (jj["result"].get() == "fail") { std::string cali_mode = jj["command"].get(); std::string reason = jj["reason"].get(); wxString info = ""; if (reason == "invalid nozzle_diameter" || reason == "nozzle_diameter is not supported") { info = _L("This calibration does not support the currently selected nozzle diameter"); } else if (reason == "invalid handle_flowrate_cali param") { info = _L("Current flowrate cali param is invalid"); } else if (reason == "nozzle_diameter is not matched") { info = _L("Selected diameter and machine diameter do not match"); } else if (reason == "generate auto filament cali gcode failure") { info = _L("Failed to generate cali G-code"); } else { info = reason; } GUI::wxGetApp().push_notification(this, info, _L("Calibration error"), UserNotificationStyle::UNS_WARNING_CONFIRM); BOOST_LOG_TRIVIAL(info) << cali_mode << " result fail, reason = " << reason; } } } else if (jj["command"].get() == "extrusion_cali_set") { int ams_id = -1; int tray_id = -1; int curr_tray_id = -1; if (jj.contains("tray_id")) { try { curr_tray_id = jj["tray_id"].get(); if (curr_tray_id == VIRTUAL_TRAY_MAIN_ID) tray_id = curr_tray_id; else if (curr_tray_id >= 0 && curr_tray_id < 16){ ams_id = curr_tray_id / 4; tray_id = curr_tray_id % 4; } else { BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_set: unsupported tray_id = " << curr_tray_id; } } catch(...) { ; } } if (tray_id == VIRTUAL_TRAY_MAIN_ID) { if (jj.contains("k_value")) vt_slot[0].k = jj["k_value"].get(); if (jj.contains("n_coef")) vt_slot[0].n = jj["n_coef"].get(); } else { auto ams_item = m_fila_system->GetAmsById(std::to_string(ams_id)); if (ams_item) { auto tray_item = ams_item->GetTrays().find(std::to_string(tray_id)); if (tray_item != ams_item->GetTrays().end()) { if (jj.contains("k_value")) tray_item->second->k = jj["k_value"].get(); if (jj.contains("n_coef")) tray_item->second->n = jj["n_coef"].get(); } } } extrusion_cali_set_tray_id = curr_tray_id; extrusion_cali_set_hold_start = std::chrono::system_clock::now(); } else if (jj["command"].get() == "extrusion_cali_sel") { int ams_id = -1; int slot_id = -1; int tray_id = -1; if (jj.contains("ams_id")) { try { ams_id = jj["ams_id"].get(); slot_id = jj["slot_id"].get(); } catch (...) { ; } } else { tray_id = jj["tray_id"].get(); if(tray_id >= 0 && tray_id < 16) { ams_id = tray_id / 4; slot_id = tray_id % 4; } else if(tray_id == VIRTUAL_TRAY_MAIN_ID || tray_id == VIRTUAL_TRAY_DEPUTY_ID){ ams_id = tray_id; slot_id = 0; } } BOOST_LOG_TRIVIAL(trace) << "extrusion_cali_sel: unsupported ams_id = " << ams_id << "slot_id = " << slot_id; if (jj.contains("cali_idx")) { if (ams_id == VIRTUAL_TRAY_MAIN_ID || ams_id == VIRTUAL_TRAY_DEPUTY_ID) { if (ams_id == VIRTUAL_TRAY_MAIN_ID && vt_slot.size() > 0) { vt_slot[MAIN_EXTRUDER_ID].cali_idx = jj["cali_idx"].get(); vt_slot[MAIN_EXTRUDER_ID].set_hold_count(); } else if (ams_id == VIRTUAL_TRAY_DEPUTY_ID && vt_slot.size() > 1) { vt_slot[DEPUTY_EXTRUDER_ID].cali_idx = jj["cali_idx"].get(); vt_slot[DEPUTY_EXTRUDER_ID].set_hold_count(); } } else { auto tray_item = m_fila_system->GetAmsTray(std::to_string(ams_id), std::to_string(slot_id)); if (tray_item) { tray_item->cali_idx = jj["cali_idx"].get(); tray_item->set_hold_count(); } } } } else if (jj["command"].get() == "extrusion_cali_get") { std::string str = jj.dump(); if (request_tab_from_bbs) { BOOST_LOG_TRIVIAL(info) << "bbs extrusion_cali_get: " << str; request_tab_from_bbs = false; reset_pa_cali_history_result(); bool is_succeed = true; if (jj.contains("result") && jj.contains("reason")) { if (jj["result"].get() == "fail") { is_succeed = false; } is_succeed = false; } if (is_succeed) { last_cali_version = cali_version; has_get_pa_calib_tab = true; } if (jj.contains("filaments") && jj["filaments"].is_array()) { try { for (auto it = jj["filaments"].begin(); it != jj["filaments"].end(); it++) { PACalibResult pa_calib_result; pa_calib_result.filament_id = (*it)["filament_id"].get(); pa_calib_result.name = (*it)["name"].get(); pa_calib_result.cali_idx = (*it)["cali_idx"].get(); if ((*it).contains("setting_id")) { pa_calib_result.setting_id = (*it)["setting_id"].get(); } if ((*it).contains("extruder_id")) { pa_calib_result.extruder_id = (*it)["extruder_id"].get(); } if ((*it).contains("nozzle_id")) { pa_calib_result.nozzle_volume_type = convert_to_nozzle_type((*it)["nozzle_id"].get()); } if (jj["nozzle_diameter"].is_number_float()) { pa_calib_result.nozzle_diameter = jj["nozzle_diameter"].get(); } else if (jj["nozzle_diameter"].is_string()) { pa_calib_result.nozzle_diameter = string_to_float(jj["nozzle_diameter"].get()); } if ((*it)["k_value"].is_number_float()) pa_calib_result.k_value = (*it)["k_value"].get(); else if ((*it)["k_value"].is_string()) pa_calib_result.k_value = string_to_float((*it)["k_value"].get()); if ((*it)["n_coef"].is_number_float()) pa_calib_result.n_coef = (*it)["n_coef"].get(); else if ((*it)["n_coef"].is_string()) pa_calib_result.n_coef = string_to_float((*it)["n_coef"].get()); if (check_pa_result_validation(pa_calib_result)) pa_calib_tab.push_back(pa_calib_result); else { BOOST_LOG_TRIVIAL(info) << "pa result is invalid"; } } } catch (...) { } } // notify cali history to update } } else if (jj["command"].get() == "extrusion_cali_get_result") { std::string str = jj.dump(); BOOST_LOG_TRIVIAL(info) << "extrusion_cali_get_result: " << str; reset_pa_cali_result(); bool is_succeed = true; if (jj.contains("result") && jj.contains("reason")) { if (jj["result"].get() == "fail") { if (jj.contains("err_code")) { is_succeed = false; } } } if (is_succeed) get_pa_calib_result = true; if (jj.contains("filaments") && jj["filaments"].is_array()) { try { for (auto it = jj["filaments"].begin(); it != jj["filaments"].end(); it++) { PACalibResult pa_calib_result; pa_calib_result.filament_id = (*it)["filament_id"].get(); if ((*it).contains("setting_id")) { pa_calib_result.setting_id = (*it)["setting_id"].get(); } if (jj["nozzle_diameter"].is_number_float()) { pa_calib_result.nozzle_diameter = jj["nozzle_diameter"].get(); } else if (jj["nozzle_diameter"].is_string()) { pa_calib_result.nozzle_diameter = string_to_float(jj["nozzle_diameter"].get()); } if (it->contains("ams_id")) { pa_calib_result.ams_id = (*it)["ams_id"].get(); } else { pa_calib_result.ams_id = 0; } if (it->contains("slot_id")) { pa_calib_result.slot_id = (*it)["slot_id"].get(); } else { pa_calib_result.slot_id = 0; } if (it->contains("extruder_id")) { pa_calib_result.extruder_id = (*it)["extruder_id"].get(); } else { pa_calib_result.extruder_id = -1; } if (it->contains("nozzle_id")) { pa_calib_result.nozzle_volume_type = convert_to_nozzle_type((*it)["nozzle_id"].get()); } else { pa_calib_result.nozzle_volume_type = NozzleVolumeType::nvtStandard; } if ((*it)["k_value"].is_number_float()) pa_calib_result.k_value = (*it)["k_value"].get(); else if ((*it)["k_value"].is_string()) pa_calib_result.k_value = string_to_float((*it)["k_value"].get()); if ((*it)["n_coef"].is_number_float()) pa_calib_result.n_coef = (*it)["n_coef"].get(); else if ((*it)["n_coef"].is_string()) pa_calib_result.n_coef = string_to_float((*it)["n_coef"].get()); if (it->contains("confidence")) { pa_calib_result.confidence = (*it)["confidence"].get(); } else { pa_calib_result.confidence = 0; } if (this->is_support_new_auto_cali_method) pa_calib_result.tray_id = get_tray_id_by_ams_id_and_slot_id(pa_calib_result.ams_id, pa_calib_result.slot_id); else pa_calib_result.tray_id = (*it)["tray_id"].get(); if (check_pa_result_validation(pa_calib_result)) pa_calib_results.push_back(pa_calib_result); else { BOOST_LOG_TRIVIAL(info) << "pa result is invalid"; } } } catch (...) {} } if (pa_calib_results.empty()) { BOOST_LOG_TRIVIAL(info) << "no pa calib result"; } } else if (jj["command"].get() == "flowrate_get_result" && !key_field_only) { this->reset_flow_rate_cali_result(); get_flow_calib_result = true; if (jj.contains("filaments") && jj["filaments"].is_array()) { try { #ifdef CALI_DEBUG std::string str = jj.dump(); BOOST_LOG_TRIVIAL(info) << "flowrate_get_result: " << str; #endif for (auto it = jj["filaments"].begin(); it != jj["filaments"].end(); it++) { FlowRatioCalibResult flow_ratio_calib_result; flow_ratio_calib_result.tray_id = (*it)["tray_id"].get(); flow_ratio_calib_result.filament_id = (*it)["filament_id"].get(); flow_ratio_calib_result.setting_id = (*it)["setting_id"].get(); flow_ratio_calib_result.nozzle_diameter = string_to_float(jj["nozzle_diameter"].get()); flow_ratio_calib_result.flow_ratio = string_to_float((*it)["flow_ratio"].get()); if (it->contains("confidence")) { flow_ratio_calib_result.confidence = (*it)["confidence"].get(); } else { flow_ratio_calib_result.confidence = 0; } flow_ratio_results.push_back(flow_ratio_calib_result); } } catch (...) {} } } m_fan->command_handle_response(jj); } } if (!key_field_only) { try { if (j.contains("camera")) { if (j["camera"].contains("command")) { if (j["camera"]["command"].get() == "ipcam_timelapse") { if (camera_timelapse_hold_count > 0) { camera_timelapse_hold_count--; } else { if (j["camera"]["control"].get() == "enable") this->camera_timelapse = true; if (j["camera"]["control"].get() == "disable") this->camera_timelapse = false; BOOST_LOG_TRIVIAL(info) << "ack of timelapse = " << camera_timelapse; } } else if (j["camera"]["command"].get() == "ipcam_record_set") { if (time(nullptr) - camera_recording_ctl_start > HOLD_TIME_3SEC) { if (j["camera"]["control"].get() == "enable") this->camera_recording_when_printing = true; if (j["camera"]["control"].get() == "disable") this->camera_recording_when_printing = false; BOOST_LOG_TRIVIAL(info) << "ack of ipcam_record_set " << camera_recording_when_printing; } } else if (j["camera"]["command"].get() == "ipcam_resolution_set") { if (camera_resolution_hold_count > 0) { camera_resolution_hold_count--; } else { this->camera_resolution = j["camera"]["resolution"].get(); BOOST_LOG_TRIVIAL(info) << "ack of resolution = " << camera_resolution; } } } } } catch (...) {} } if (!key_field_only) { // upgrade try { if (j.contains("upgrade")) { if (j["upgrade"].contains("command")) { if (j["upgrade"]["command"].get() == "upgrade_confirm") { this->upgrade_display_state = DevFirmwareUpgradingState::UpgradingInProgress; upgrade_display_hold_count = HOLD_COUNT_MAX; BOOST_LOG_TRIVIAL(info) << "ack of upgrade_confirm"; } bool check_studio_cmd = true; if (j["upgrade"].contains("sequence_id")) { try { std::string str_seq = j["upgrade"]["sequence_id"].get(); check_studio_cmd = is_studio_cmd(stoi(str_seq)); } catch (...) { } } if (check_studio_cmd && j["upgrade"].contains("err_code")) { if (j["upgrade"]["err_code"].is_number()) { add_command_error_code_dlg(j["upgrade"]["err_code"].get()); } } } } } catch (...) { ; } } // event info try { if (j.contains("event")) { if (j["event"].contains("event")) { if (j["event"]["event"].get() == "client.disconnected") set_online_state(false); else if (j["event"]["event"].get() == "client.connected") set_online_state(true); } } } catch (...) {} if (!key_field_only) { BOOST_LOG_TRIVIAL(trace) << "parse_json m_active_state =" << m_active_state; parse_state_changed_event(); } } catch (...) { BOOST_LOG_TRIVIAL(trace) << "parse_json failed! dev_id=" << this->get_dev_id() <<", payload = " << payload; } std::chrono::system_clock::time_point clock_stop = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(clock_stop - clock_start); if (diff.count() > 10.0f) { BOOST_LOG_TRIVIAL(trace) << "parse_json timeout = " << diff.count(); } DeviceManager::update_local_machine(*this); return 0; } void MachineObject::set_ctt_dlg( wxString text){ if (!m_set_ctt_dlg) { m_set_ctt_dlg = true; auto print_error_dlg = new GUI::SecondaryCheckDialog(nullptr, wxID_ANY, _L("Warning"), GUI::SecondaryCheckDialog::ButtonStyle::ONLY_CONFIRM); print_error_dlg->update_text(text); print_error_dlg->Bind(wxEVT_SHOW, [this](auto& e) { if (!e.IsShown()) { m_set_ctt_dlg = false; } }); print_error_dlg->Bind(wxEVT_CLOSE_WINDOW, [this](auto& e) { e.Skip(); m_set_ctt_dlg = false; }); print_error_dlg->on_show(); } } int MachineObject::publish_gcode(std::string gcode_str) { json j; j["print"]["command"] = "gcode_line"; j["print"]["param"] = gcode_str; j["print"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); return publish_json(j); } BBLSubTask* MachineObject::get_subtask() { if (!subtask_) subtask_ = new BBLSubTask(nullptr); return subtask_; } BBLModelTask* MachineObject::get_modeltask() { return model_task; } void MachineObject::set_modeltask(BBLModelTask* task) { model_task = task; } void MachineObject::update_model_task() { if (request_model_result > 10) return; if (!m_agent) return; if (!model_task) return; if (!subtask_) return; if (model_task->task_id != subtask_->task_id) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " times: " << request_model_result << " model_task_id !=subtask_id"; return; } if (model_task->instance_id <= 0) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " times: " << request_model_result << " instance_id <= 0"; return; } if ((!subtask_id_.empty() && last_subtask_id_ != subtask_id_) || get_model_mall_result_need_retry) { if (!subtask_id_.empty() && last_subtask_id_ != subtask_id_) { BOOST_LOG_TRIVIAL(info) << "update_model_task: last=" << last_subtask_id_ << ", curr=" << subtask_id_; last_subtask_id_ = subtask_id_; request_model_result = 0; } if (get_model_mall_result_need_retry) { BOOST_LOG_TRIVIAL(info) << "need retry"; get_model_mall_result_need_retry = false; } } else { BOOST_LOG_TRIVIAL(info) << "subtask_id_ no change and do not need retry"; return; } int curr_instance_id = model_task->instance_id; if (rating_info) { delete rating_info; rating_info = nullptr; } get_model_task_thread = new boost::thread([this, curr_instance_id, token = std::weak_ptr(m_token)]{ if (token.expired()) { return; } try { std::string rating_result; unsigned int http_code = 404; std::string http_error; int res = -1; res = m_agent->get_model_mall_rating_result(curr_instance_id, rating_result, http_code, http_error); request_model_result++; BOOST_LOG_TRIVIAL(info) << "request times: " << request_model_result << " http code: " << http_code; auto rating_info = new DevPrintTaskRatingInfo(); rating_info->http_code = http_code; if (0 == res && 200 == http_code) { try { json rating_json = json::parse(rating_result); if (rating_json.contains("id")) { rating_info->rating_id = rating_json["id"].get(); //rating id is necessary info, so rating id must have request_model_result = 0; rating_info->request_successful = true; BOOST_LOG_TRIVIAL(info) << "get rating id"; } else { rating_info->request_successful = false; BOOST_LOG_TRIVIAL(info) << "can not get rating id"; Slic3r::GUI::wxGetApp().CallAfter([this, token, rating_info]() { if (!token.expired()) this->rating_info = rating_info; }); return; } if (rating_json.contains("score")) { rating_info->start_count = rating_json["score"].get(); } if (rating_json.contains("content")) rating_info->content = rating_json["content"].get(); if (rating_json.contains("successPrinted")) rating_info->success_printed = rating_json["successPrinted"].get(); if (rating_json.contains("images")) { rating_info->image_url_paths = rating_json["images"].get>(); } Slic3r::GUI::wxGetApp().CallAfter([this, token, rating_info]() { if (!token.expired()) this->rating_info = rating_info; }); } catch (...) { BOOST_LOG_TRIVIAL(info) << "parse model mall result json failed"; } } else { rating_info->request_successful = false; Slic3r::GUI::wxGetApp().CallAfter([this, token, rating_info]() { if (!token.expired()) this->rating_info = rating_info; }); BOOST_LOG_TRIVIAL(info) << "model mall result request failed, request time: " << request_model_result << " http_code: " << http_code << " error msg: " << http_error; return; } } catch (...) { BOOST_LOG_TRIVIAL(info) << "get mall model rating id failed and hide scoring page"; } }); } void MachineObject::free_slice_info() { if (get_slice_info_thread) { if (get_slice_info_thread->joinable()) { get_slice_info_thread->interrupt(); get_slice_info_thread->join(); } delete get_slice_info_thread; get_slice_info_thread = nullptr; } if (slice_info) { delete slice_info; slice_info = nullptr; } } void MachineObject::update_slice_info(std::string project_id, std::string profile_id, std::string subtask_id, int plate_idx) { if (!m_agent) return; if (project_id_ != project_id || profile_id_ != profile_id || slice_info == nullptr || subtask_id_ != subtask_id) { project_id_ = project_id; profile_id_ = profile_id; subtask_id_ = subtask_id; if (project_id.empty() || profile_id.empty() || subtask_id.empty()) { return; } if (project_id.compare("0") == 0 || profile_id.compare("0") == 0 || subtask_id.compare("0") == 0) return; BOOST_LOG_TRIVIAL(trace) << "slice_info: start"; slice_info = new BBLSliceInfo(); get_slice_info_thread = new boost::thread([this, project_id, profile_id, subtask_id, plate_idx] { int plate_index = -1; if (!m_agent) return; if (!slice_info) return; if (!get_slice_info_thread) return;/*STUDIO-12264*/ if (get_slice_info_thread->interruption_requested()) { return;} if (plate_idx >= 0) { plate_index = plate_idx; } else { std::string subtask_json; unsigned http_code = 0; std::string http_body; if (m_agent->get_subtask_info(subtask_id, &subtask_json, &http_code, &http_body) == 0) { try { if (!subtask_json.empty()) { json task_j = json::parse(subtask_json); if (task_j.contains("content")) { std::string content_str = task_j["content"].get(); json content_j = json::parse(content_str); plate_index = content_j["info"]["plate_idx"].get(); } if (task_j.contains("context") && task_j["context"].contains("plates")) { for (int i = 0; i < task_j["context"]["plates"].size(); i++) { if (task_j["context"]["plates"][i].contains("index") && task_j["context"]["plates"][i]["index"].get() == plate_index) { if (task_j["context"]["plates"][i].contains("thumbnail") && task_j["context"]["plates"][i]["thumbnail"].contains("url")) { slice_info->thumbnail_url = task_j["context"]["plates"][i]["thumbnail"]["url"].get(); } if (task_j["context"]["plates"][i].contains("prediction")) { slice_info->prediction = task_j["context"]["plates"][i]["prediction"].get(); } if (task_j["context"]["plates"][i].contains("weight")) { slice_info->weight = task_j["context"]["plates"][i]["weight"].get(); } if (!task_j["context"]["plates"][i]["filaments"].is_null()) { for (auto filament : task_j["context"]["plates"][i]["filaments"]) { FilamentInfo f; if(filament.contains("color")){ f.color = filament["color"].get(); } if (filament.contains("type")) { f.type = filament["type"].get(); } if (filament.contains("used_g")) { f.used_g = stof(filament["used_g"].get()); } if (filament.contains("used_m")) { f.used_m = stof(filament["used_m"].get()); } slice_info->filaments_info.push_back(f); } } BOOST_LOG_TRIVIAL(trace) << "task_info: thumbnail url=" << slice_info->thumbnail_url; } } } else { BOOST_LOG_TRIVIAL(error) << "task_info: no context or plates"; } } } catch (...) { } } else { BOOST_LOG_TRIVIAL(error) << "task_info: get subtask id failed!"; } } this->m_plate_index = plate_index; }); } } void MachineObject::get_firmware_info() { m_firmware_valid = false; if (m_firmware_thread_started) return; boost::thread update_info_thread = Slic3r::create_thread( [&] { m_firmware_thread_started = true; int result = 0; unsigned int http_code; std::string http_body; if (!m_agent) return; result = m_agent->get_printer_firmware(get_dev_id(), &http_code, &http_body); if (result < 0) { // get upgrade list failed return; } try { json j = json::parse(http_body); if (j.contains("devices") && !j["devices"].is_null()) { firmware_list.clear(); for (json::iterator it = j["devices"].begin(); it != j["devices"].end(); it++) { if ((*it)["dev_id"].get() == this->get_dev_id()) { try { json firmware = (*it)["firmware"]; for (json::iterator firmware_it = firmware.begin(); firmware_it != firmware.end(); firmware_it++) { FirmwareInfo item; item.version = (*firmware_it)["version"].get(); item.url = (*firmware_it)["url"].get(); if ((*firmware_it).contains("description")) item.description = (*firmware_it)["description"].get(); item.module_type = "ota"; int name_start = item.url.find_last_of('/') + 1; if (name_start > 0) { item.name = item.url.substr(name_start, item.url.length() - name_start); firmware_list.push_back(item); } else { BOOST_LOG_TRIVIAL(trace) << "skip"; } } } catch (...) {} try { if ((*it).contains("ams")) { json ams_list = (*it)["ams"]; if (ams_list.size() > 0) { auto ams_front = ams_list.front(); json firmware_ams = (ams_front)["firmware"]; for (json::iterator ams_it = firmware_ams.begin(); ams_it != firmware_ams.end(); ams_it++) { FirmwareInfo item; item.version = (*ams_it)["version"].get(); item.url = (*ams_it)["url"].get(); if ((*ams_it).contains("description")) item.description = (*ams_it)["description"].get(); item.module_type = "ams"; int name_start = item.url.find_last_of('/') + 1; if (name_start > 0) { item.name = item.url.substr(name_start, item.url.length() - name_start); firmware_list.push_back(item); } else { BOOST_LOG_TRIVIAL(trace) << "skip"; } } } } } catch (...) { ; } } } } } catch (...) { return; } m_firmware_thread_started = false; m_firmware_valid = true; } ); return; } bool MachineObject::is_firmware_info_valid() { return m_firmware_valid; } DevAmsTray MachineObject::parse_vt_tray(json vtray) { auto vt_tray = DevAmsTray(std::to_string(VIRTUAL_TRAY_MAIN_ID)); if (vtray.contains("id")) vt_tray.id = vtray["id"].get(); auto curr_time = std::chrono::system_clock::now(); auto diff = std::chrono::duration_cast(curr_time - extrusion_cali_set_hold_start); if (diff.count() > HOLD_TIMEOUT || diff.count() < 0 || extrusion_cali_set_tray_id != VIRTUAL_TRAY_MAIN_ID) { if (vtray.contains("k")) vt_tray.k = vtray["k"].get(); if (vtray.contains("n")) vt_tray.n = vtray["n"].get(); } ams_support_virtual_tray = true; if (vt_tray.hold_count > 0) { vt_tray.hold_count--; } else { if (vtray.contains("tag_uid")) vt_tray.tag_uid = vtray["tag_uid"].get(); else vt_tray.tag_uid = "0"; if (vtray.contains("tray_info_idx") && vtray.contains("tray_type")) { vt_tray.setting_id = vtray["tray_info_idx"].get(); //std::string type = vtray["tray_type"].get(); std::string type = setting_id_to_type(vt_tray.setting_id, vtray["tray_type"].get()); if (vt_tray.setting_id == "GFS00") { vt_tray.type = "PLA-S"; } else if (vt_tray.setting_id == "GFS01") { vt_tray.type = "PA-S"; } else { vt_tray.type = type; } } else { vt_tray.setting_id = ""; vt_tray.type = ""; } if (vtray.contains("tray_sub_brands")) vt_tray.sub_brands = vtray["tray_sub_brands"].get(); else vt_tray.sub_brands = ""; if (vtray.contains("tray_weight")) vt_tray.weight = vtray["tray_weight"].get(); else vt_tray.weight = ""; if (vtray.contains("tray_diameter")) vt_tray.diameter = vtray["tray_diameter"].get(); else vt_tray.diameter = ""; if (vtray.contains("tray_temp")) vt_tray.temp = vtray["tray_temp"].get(); else vt_tray.temp = ""; if (vtray.contains("tray_time")) vt_tray.time = vtray["tray_time"].get(); else vt_tray.time = ""; if (vtray.contains("bed_temp_type")) vt_tray.bed_temp_type = vtray["bed_temp_type"].get(); else vt_tray.bed_temp_type = ""; if (vtray.contains("bed_temp")) vt_tray.bed_temp = vtray["bed_temp"].get(); else vt_tray.bed_temp = ""; if (vtray.contains("tray_color")) { auto color = vtray["tray_color"].get(); vt_tray.UpdateColorFromStr(color); } else { vt_tray.color = ""; } if (vtray.contains("ctype")) { vt_tray.ctype = vtray["ctype"].get(); } else { vt_tray.ctype = 1; } if (vtray.contains("nozzle_temp_max")) vt_tray.nozzle_temp_max = vtray["nozzle_temp_max"].get(); else vt_tray.nozzle_temp_max = ""; if (vtray.contains("nozzle_temp_min")) vt_tray.nozzle_temp_min = vtray["nozzle_temp_min"].get(); else vt_tray.nozzle_temp_min = ""; if (vtray.contains("xcam_info")) vt_tray.xcam_info = vtray["xcam_info"].get(); else vt_tray.xcam_info = ""; if (vtray.contains("tray_uuid")) vt_tray.uuid = vtray["tray_uuid"].get(); else vt_tray.uuid = "0"; if (vtray.contains("cali_idx")) vt_tray.cali_idx = vtray["cali_idx"].get(); else vt_tray.cali_idx = -1; vt_tray.cols.clear(); if (vtray.contains("cols")) { if (vtray["cols"].is_array()) { for (auto it = vtray["cols"].begin(); it != vtray["cols"].end(); it++) { vt_tray.cols.push_back(it.value().get()); } } } else { vt_tray.cols.push_back(vt_tray.color); } if (vtray.contains("remain")) { vt_tray.remain = vtray["remain"].get(); } else { vt_tray.remain = -1; } } return vt_tray; } bool MachineObject::contains_tray(const std::string &ams_id, const std::string &tray_id) const { if (ams_id != VIRTUAL_AMS_MAIN_ID_STR && ams_id != VIRTUAL_AMS_DEPUTY_ID_STR) { return m_fila_system->GetAmsTray(ams_id, tray_id) != nullptr; } else { for (const auto& tray : vt_slot) { if (tray.id == ams_id) { return true; } } } return false; } DevAmsTray MachineObject::get_tray(const std::string &ams_id, const std::string &tray_id) const { if (ams_id.empty() && tray_id.empty()) { return DevAmsTray(tray_id); } if (ams_id != VIRTUAL_AMS_MAIN_ID_STR && ams_id != VIRTUAL_AMS_DEPUTY_ID_STR) { auto tray = m_fila_system->GetAmsTray(ams_id, tray_id); if (tray) { return *tray;}; } else { for (const auto &tray : vt_slot) { if (tray.id == ams_id) { return tray; } } } assert(0);/*use contains_tray() check first*/ return DevAmsTray(tray_id); } bool MachineObject::check_enable_np(const json& print) const { if (print.contains("cfg") && print.contains("fun") && print.contains("aux") && print.contains("stat")) { return true; } return false; } void MachineObject::parse_new_info(json print) { is_enable_np = check_enable_np(print); if (!is_enable_np) { return; } BOOST_LOG_TRIVIAL(info) << "using new print data for parsing"; /*cfg*/ std::string cfg = print["cfg"].get(); BOOST_LOG_TRIVIAL(info) << "new print data cfg = " << cfg; if(!cfg.empty()){ if (camera_resolution_hold_count > 0) camera_resolution_hold_count--; if (camera_timelapse_hold_count > 0) camera_timelapse_hold_count--; if (time(nullptr) - ams_user_setting_start > HOLD_COUNT_MAX) { m_fila_system->GetAmsSystemSetting().SetDetectOnInsertEnabled(get_flag_bits(cfg, 0)); m_fila_system->GetAmsSystemSetting().SetDetectOnPowerupEnabled(get_flag_bits(cfg, 1)); } upgrade_force_upgrade = get_flag_bits(cfg, 2); if (time(nullptr) - camera_recording_ctl_start > HOLD_COUNT_MAX) { camera_recording_when_printing = get_flag_bits(cfg, 3); } if (camera_resolution_hold_count > 0) { camera_resolution_hold_count--; } else { camera_resolution = get_flag_bits(cfg, 4) == 0 ? "720p" : "1080p"; } if (camera_timelapse_hold_count > 0) { camera_timelapse_hold_count--; } else { camera_timelapse = get_flag_bits(cfg, 5); } tutk_state = get_flag_bits(cfg, 6) == 1 ? "disable" : ""; m_lamp->SetChamberLight(get_flag_bits(cfg, 7) == 1 ? DevLamp::LIGHT_EFFECT_ON : DevLamp::LIGHT_EFFECT_OFF); //is_support_build_plate_marker_detect = get_flag_bits(cfg, 12); todo yangcong if (time(nullptr) - xcam_first_layer_hold_start > HOLD_TIME_3SEC) { xcam_first_layer_inspector = get_flag_bits(cfg, 12); } if (time(nullptr) - xcam_ai_monitoring_hold_start > HOLD_COUNT_MAX) { xcam_ai_monitoring = get_flag_bits(cfg, 15); switch (get_flag_bits(cfg, 13, 2)) { case 0: xcam_ai_monitoring_sensitivity = "never_halt"; break; case 1: xcam_ai_monitoring_sensitivity = "low"; break; case 2: xcam_ai_monitoring_sensitivity = "medium"; break; case 3: xcam_ai_monitoring_sensitivity = "high"; break; default: break; } } if (time(nullptr) - xcam_auto_recovery_hold_start > HOLD_COUNT_MAX) { xcam_auto_recovery_step_loss = get_flag_bits(cfg, 16); } if (time(nullptr) - ams_user_setting_start > HOLD_COUNT_MAX){ m_fila_system->GetAmsSystemSetting().SetDetectRemainEnabled(get_flag_bits(cfg, 17)); } if (time(nullptr) - ams_switch_filament_start > HOLD_TIME_3SEC){ m_fila_system->GetAmsSystemSetting().SetAutoRefillEnabled(get_flag_bits(cfg, 18)); } if (time(nullptr) - xcam__save_remote_print_file_to_storage_start_time > HOLD_TIME_3SEC){ xcam__save_remote_print_file_to_storage = get_flag_bits(cfg, 19); } if (time(nullptr) - xcam_door_open_check_start_time > HOLD_TIME_3SEC){ xcam_door_open_check = (DoorOpenCheckState) get_flag_bits(cfg, 20, 2); } if (time(nullptr) - xcam_prompt_sound_hold_start > HOLD_TIME_3SEC) { xcam_allow_prompt_sound = get_flag_bits(cfg, 22); } if (time(nullptr) - xcam_filament_tangle_detect_hold_start > HOLD_TIME_3SEC){ xcam_filament_tangle_detect = get_flag_bits(cfg, 23); } if (time(nullptr) - nozzle_blob_detection_hold_start > HOLD_TIME_3SEC) { nozzle_blob_detection_enabled = get_flag_bits(cfg, 24); } installed_upgrade_kit = get_flag_bits(cfg, 25); } /*fun*/ std::string fun = print["fun"].get(); BOOST_LOG_TRIVIAL(info) << "new print data fun = " << fun; if (!fun.empty()) { is_support_agora = get_flag_bits(fun, 1); if (is_support_agora) is_support_tunnel_mqtt = false; is_220V_voltage = get_flag_bits(fun, 2) == 0?false:true; is_support_flow_calibration = get_flag_bits(fun, 6); if (this->is_series_o()) { is_support_flow_calibration = false; } // todo: Temp modification due to incorrect machine push message for H2D is_support_pa_calibration = get_flag_bits(fun, 7); if (this->is_series_p()) { is_support_pa_calibration = false; } // todo: Temp modification due to incorrect machine push message for P is_support_prompt_sound = get_flag_bits(fun, 8); is_support_filament_tangle_detect = get_flag_bits(fun, 9); is_support_motor_noise_cali = get_flag_bits(fun, 10); is_support_user_preset = get_flag_bits(fun, 11); is_support_door_open_check = get_flag_bits(fun, 12); is_support_nozzle_blob_detection = get_flag_bits(fun, 13); is_support_upgrade_kit = get_flag_bits(fun, 14); is_support_internal_timelapse = get_flag_bits(fun, 28); is_support_command_homing = get_flag_bits(fun, 32); is_support_brtc = get_flag_bits(fun, 31); m_support_mqtt_axis_control = get_flag_bits(fun, 38); m_support_mqtt_bet_ctrl = get_flag_bits(fun, 39); is_support_new_auto_cali_method = get_flag_bits(fun, 40); is_support_spaghetti_detection = get_flag_bits(fun, 42); is_support_purgechutepileup_detection = get_flag_bits(fun, 43); is_support_nozzleclumping_detection = get_flag_bits(fun, 44); is_support_airprinting_detection = get_flag_bits(fun, 45); m_fan->SetSupportCoolingFilter(get_flag_bits(fun, 46)); is_support_ext_change_assist = get_flag_bits(fun, 48); } /*aux*/ std::string aux = print["aux"].get(); BOOST_LOG_TRIVIAL(info) << "new print data aux = " << aux; if (!aux.empty()) { m_storage->set_sdcard_state(get_flag_bits(aux, 12, 2)); //sdcard_state = MachineObject::SdcardState(get_flag_bits(aux, 12, 2)); } /*stat*/ std::string stat = print["stat"].get(); BOOST_LOG_TRIVIAL(info) << "new print data stat = " << stat; if (!stat.empty()) { camera_recording = get_flag_bits(stat, 7); m_lamp->SetLampCloseRecheck((get_flag_bits(stat, 36) == 1)); } /*device*/ if (print.contains("device")) { json const& device = print["device"]; //new fan data m_fan->ParseV3_0(device); if (device.contains("type")) { m_device_mode = (DeviceMode)device["type"].get();// FDM:1<<0 Laser:1<< Cut:1<<2 } DevBed::ParseV2_0(device,m_bed); if (device.contains("nozzle")) { DevNozzleSystemParser::ParseV2_0(device["nozzle"], m_nozzle_system); } if (device.contains("extruder")) { ExtderSystemParser::ParseV2_0(device["extruder"], m_extder_system);} if (device.contains("ctc")) { json const& ctc = device["ctc"]; int state = get_flag_bits(ctc["state"].get(), 0, 4); if (ctc.contains("info")) { json const &info = ctc["info"]; chamber_temp = get_flag_bits(info["temp"].get(), 0, 16); chamber_temp_target = get_flag_bits(info["temp"].get(), 16, 16); } } } } int MachineObject::get_flag_bits(std::string str, int start, int count) const { try { unsigned long long decimal_value = std::stoull(str, nullptr, 16); unsigned long long mask = (1ULL << count) - 1; int flag = (decimal_value >> start) & mask; return flag; } catch (...) { return 0; } } int MachineObject::get_flag_bits(int num, int start, int count, int base) const { try { unsigned long long mask = (1ULL << count) - 1; unsigned long long value; if (base == 10) { value = static_cast(num); } else if (base == 16) { value = static_cast(std::stoul(std::to_string(num), nullptr, 16)); } else { throw std::invalid_argument("Unsupported base"); } int flag = (value >> start) & mask; return flag; } catch (...) { return 0; } } void MachineObject::update_filament_list() { PresetBundle *preset_bundle = Slic3r::GUI::wxGetApp().preset_bundle; // custom filament typedef std::map> map_pair; std::map map_list; for (auto &pair : m_nozzle_filament_data) { map_list[pair.second.printer_preset_name] = map_pair{}; } for (auto &preset : preset_bundle->filaments()) { if (preset.is_user() && preset.inherits() == "") { ConfigOption * printer_opt = const_cast(preset).config.option("compatible_printers"); ConfigOptionStrings *printer_strs = dynamic_cast(printer_opt); for (const std::string &printer_str : printer_strs->values) { if (map_list.find(printer_str) != map_list.end()) { auto & filament_list = map_list[printer_str]; ConfigOption *opt_min = const_cast(preset).config.option("nozzle_temperature_range_low"); int min_temp = -1; if (opt_min) { ConfigOptionInts *opt_min_ints = dynamic_cast(opt_min); min_temp = opt_min_ints->get_at(0); } ConfigOption *opt_max = const_cast(preset).config.option("nozzle_temperature_range_high"); int max_temp = -1; if (opt_max) { ConfigOptionInts *opt_max_ints = dynamic_cast(opt_max); max_temp = opt_max_ints->get_at(0); } filament_list[preset.filament_id] = std::make_pair(min_temp, max_temp); break; } } } } for (auto& pair : m_nozzle_filament_data) { auto & m_printer_preset_name = pair.second.printer_preset_name; auto & m_filament_list = pair.second.filament_list; auto & m_checked_filament = pair.second.checked_filament; auto & filament_list = map_list[m_printer_preset_name]; for (auto it = filament_list.begin(); it != filament_list.end(); it++) { if (m_filament_list.find(it->first) != m_filament_list.end()) { assert(it->first.size() == 8 && it->first[0] == 'P'); if (it->second.first != m_filament_list[it->first].first) { BOOST_LOG_TRIVIAL(info) << "old min temp is not equal to new min temp and filament id: " << it->first; continue; } if (it->second.second != m_filament_list[it->first].second) { BOOST_LOG_TRIVIAL(info) << "old max temp is not equal to new max temp and filament id: " << it->first; continue; } m_filament_list.erase(it->first); } } for (auto it = m_filament_list.begin(); it != m_filament_list.end(); it++) { m_checked_filament.insert(it->first); } m_filament_list = filament_list; } } void MachineObject::update_printer_preset_name() { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << "start update preset_name"; PresetBundle * preset_bundle = Slic3r::GUI::wxGetApp().preset_bundle; if (!preset_bundle) return; auto printer_model = DevPrinterConfigUtil::get_printer_display_name(this->printer_type); std::set diameter_set; for (auto &nozzle : m_extder_system->m_extders) { float diameter = nozzle.GetNozzleDiameter(); std::ostringstream stream; stream << std::fixed << std::setprecision(1) << diameter; std::string nozzle_diameter_str = stream.str(); diameter_set.insert(nozzle_diameter_str); if (m_nozzle_filament_data.find(nozzle_diameter_str) != m_nozzle_filament_data.end()) continue; auto data = FilamentData(); auto printer_set = preset_bundle->get_printer_names_by_printer_type_and_nozzle(printer_model, nozzle_diameter_str); if (printer_set.size() > 0) { data.printer_preset_name = *printer_set.begin(); m_nozzle_filament_data[nozzle_diameter_str] = data; } else BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " update printer preset name failed: "<< "printer_type: " << printer_type << "nozzle_diameter_str" << nozzle_diameter_str; } for (auto iter = m_nozzle_filament_data.begin(); iter != m_nozzle_filament_data.end();) { if (diameter_set.find(iter->first) == diameter_set.end()) { iter = m_nozzle_filament_data.erase(iter); } else { ++iter; } } } void MachineObject::check_ams_filament_valid() { PresetBundle * preset_bundle = Slic3r::GUI::wxGetApp().preset_bundle; auto printer_model = DevPrinterConfigUtil::get_printer_display_name(this->printer_type); std::map> need_checked_filament_id; for (auto &ams_pair : m_fila_system->GetAmsList()) { auto ams_id = ams_pair.first; auto &ams = ams_pair.second; std::ostringstream stream; if (ams->GetExtruderId() < 0 || ams->GetExtruderId() >= m_extder_system->GetTotalExtderCount()) { return; } stream << std::fixed << std::setprecision(1) << m_extder_system->GetNozzleDiameter(ams->GetExtruderId()); std::string nozzle_diameter_str = stream.str(); assert(nozzle_diameter_str.size() == 3); if (m_nozzle_filament_data.find(nozzle_diameter_str) == m_nozzle_filament_data.end()) { //assert(false); continue; } auto &data = m_nozzle_filament_data[nozzle_diameter_str]; auto &filament_list = data.filament_list; auto &checked_filament = data.checked_filament; for (const auto &[slot_id, curr_tray] : ams->GetTrays()) { if (curr_tray->setting_id.size() == 8 && curr_tray->setting_id[0] == 'P' && filament_list.find(curr_tray->setting_id) == filament_list.end()) { if (checked_filament.find(curr_tray->setting_id) != checked_filament.end()) { need_checked_filament_id[nozzle_diameter_str].insert(curr_tray->setting_id); wxColour color = *wxWHITE; char col_buf[10]; sprintf(col_buf, "%02X%02X%02XFF", (int) color.Red(), (int) color.Green(), (int) color.Blue()); try { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " ams settings_id is not exist in filament_list and reset, ams_id: " << ams_id << " tray_id" << slot_id << "filament_id: " << curr_tray->setting_id; command_ams_filament_settings(std::stoi(ams_id), std::stoi(slot_id), "", "", std::string(col_buf), "", 0, 0); continue; } catch (...) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " stoi error and ams_id: " << ams_id << " tray_id" << slot_id; } } } if (curr_tray->setting_id.size() == 8 && curr_tray->setting_id[0] == 'P' && curr_tray->nozzle_temp_min != "" && curr_tray->nozzle_temp_max != "") { if (checked_filament.find(curr_tray->setting_id) != checked_filament.end()) { need_checked_filament_id[nozzle_diameter_str].insert(curr_tray->setting_id); try { std::string preset_setting_id; bool is_equation = preset_bundle->check_filament_temp_equation_by_printer_type_and_nozzle_for_mas_tray(printer_model, nozzle_diameter_str, curr_tray->setting_id, curr_tray->tag_uid, curr_tray->nozzle_temp_min, curr_tray->nozzle_temp_max, preset_setting_id); if (!is_equation) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " ams filament is not match min max temp and reset, ams_id: " << ams_id << " tray_id" << slot_id << "filament_id: " << curr_tray->setting_id; command_ams_filament_settings(std::stoi(ams_id), std::stoi(slot_id), curr_tray->setting_id, preset_setting_id, curr_tray->color, curr_tray->type, std::stoi(curr_tray->nozzle_temp_min), std::stoi(curr_tray->nozzle_temp_max)); } continue; } catch (...) { BOOST_LOG_TRIVIAL(info) << "check fail and curr_tray ams_id" << ams_id << " curr_tray tray_id" << slot_id; } } } } } for (auto vt_tray : vt_slot) { int vt_id = std::stoi(vt_tray.id); int index = 255 - vt_id; if (index >= m_extder_system->GetTotalExtderCount()) { BOOST_LOG_TRIVIAL(error) << " vt_tray id map for nozzle id is not exist, index is: " << index << " nozzle count" << m_extder_system->GetTotalExtderCount(); continue; } auto diameter = m_extder_system->GetNozzleDiameter(index); std::ostringstream stream; stream << std::fixed << std::setprecision(1) << diameter; std::string nozzle_diameter_str = stream.str(); if (m_nozzle_filament_data.find(nozzle_diameter_str) == m_nozzle_filament_data.end()) { continue; } auto &data = m_nozzle_filament_data[nozzle_diameter_str]; auto &checked_filament = data.checked_filament; auto &filament_list = data.filament_list; if (vt_tray.setting_id.size() == 8 && vt_tray.setting_id[0] == 'P' && filament_list.find(vt_tray.setting_id) == filament_list.end()) { if (checked_filament.find(vt_tray.setting_id) != checked_filament.end()) { need_checked_filament_id[nozzle_diameter_str].insert(vt_tray.setting_id); wxColour color = *wxWHITE; char col_buf[10]; sprintf(col_buf, "%02X%02X%02XFF", (int) color.Red(), (int) color.Green(), (int) color.Blue()); try { BOOST_LOG_TRIVIAL(info) << "vt_tray.setting_id is not exist in filament_list and reset vt_tray and the filament_id is: " << vt_tray.setting_id; command_ams_filament_settings(vt_id, 0, "", "", std::string(col_buf), "", 0, 0); continue; } catch (...) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " stoi error and tray_id" << vt_tray.id; } } } if (vt_tray.setting_id.size() == 8 && vt_tray.setting_id[0] == 'P' && vt_tray.nozzle_temp_min != "" && vt_tray.nozzle_temp_max != "") { if (checked_filament.find(vt_tray.setting_id) != checked_filament.end()) { need_checked_filament_id[nozzle_diameter_str].insert(vt_tray.setting_id); try { std::string preset_setting_id; PresetBundle * preset_bundle = Slic3r::GUI::wxGetApp().preset_bundle; std::ostringstream stream; stream << std::fixed << std::setprecision(1) << m_extder_system->GetNozzleDiameter(MAIN_EXTRUDER_ID); std::string nozzle_diameter_str = stream.str(); bool is_equation = preset_bundle->check_filament_temp_equation_by_printer_type_and_nozzle_for_mas_tray(DevPrinterConfigUtil::get_printer_display_name( this->printer_type), nozzle_diameter_str, vt_tray.setting_id, vt_tray.tag_uid, vt_tray.nozzle_temp_min, vt_tray.nozzle_temp_max, preset_setting_id); if (!is_equation) { BOOST_LOG_TRIVIAL(info) << __FUNCTION__ << " " << __LINE__ << " vt_tray filament is not match min max temp and reset, filament_id: " << vt_tray.setting_id; command_ams_filament_settings(vt_id, 0, vt_tray.setting_id, preset_setting_id, vt_tray.color, vt_tray.type, std::stoi(vt_tray.nozzle_temp_min), std::stoi(vt_tray.nozzle_temp_max)); } } catch (...) { BOOST_LOG_TRIVIAL(info) << "check fail and vt_tray.id" << vt_tray.id; } } } } for (auto &diameter_pair : m_nozzle_filament_data) { auto &diameter = diameter_pair.first; auto &data = diameter_pair.second; for (auto &filament_id : need_checked_filament_id[diameter]) { data.checked_filament.erase(filament_id); } } } void MachineObject::command_set_door_open_check(DoorOpenCheckState state) { json j; j["system"]["command"] = "set_door_stat"; j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); switch (state) { case Slic3r::MachineObject::DOOR_OPEN_CHECK_DISABLE: j["system"]["config"] = 0; break; case Slic3r::MachineObject::DOOR_OPEN_CHECK_ENABLE_WARNING: j["system"]["config"] = 1; break; case Slic3r::MachineObject::DOOR_OPEN_CHECK_ENABLE_PAUSE_PRINT: j["system"]["config"] = 2; break; default: assert(0); return; } if (publish_json(j) == 0) { xcam_door_open_check = state; xcam_door_open_check_start_time = time(nullptr); } } void MachineObject::command_set_save_remote_print_file_to_storage(bool save) { if (get_save_remote_print_file_to_storage() != save) { json j; j["system"]["command"] = "print_cache_set"; j["system"]["sequence_id"] = std::to_string(MachineObject::m_sequence_id++); j["system"]["config"] = save ? true : false; if (publish_json(j) == 0) { xcam__save_remote_print_file_to_storage = save; xcam__save_remote_print_file_to_storage_start_time = time(nullptr); } } } wxString MachineObject::get_nozzle_replace_url() const { const wxString& strLanguage = GUI::wxGetApp().app_config->get("language"); const wxString& lan_code = strLanguage.BeforeFirst('_'); const json& link_map = DevPrinterConfigUtil::get_json_from_config(printer_type, "print", "nozzle_replace_wiki"); if (link_map.contains(lan_code.ToStdString())) { return link_map[lan_code.ToStdString()].get(); } if (link_map.contains("en")){ return link_map["en"].get(); }/*retry with en*/ return "https://wiki.bambulab.com/en/h2/maintenance/replace-hotend"; } std::string MachineObject::get_error_code_str(int error_code) { if (error_code < 0) { return std::string();} char buf[32]; ::sprintf(buf, "%08X", error_code); std::string print_error_str = std::string(buf); if (print_error_str.size() > 4) { print_error_str.insert(4, "-"); } return print_error_str; } void MachineObject::add_command_error_code_dlg(int command_err) { if (command_err > 0 && !Slic3r::GUI::wxGetApp().get_hms_query()->is_internal_error(this, command_err)) { GUI::wxGetApp().CallAfter([this, command_err, token = std::weak_ptr(m_token)] { if (token.expired()) { return;} GUI::DeviceErrorDialog* device_error_dialog = new GUI::DeviceErrorDialog(this, (wxWindow*)GUI::wxGetApp().mainframe); device_error_dialog->Bind(wxEVT_DESTROY, [this, token = std::weak_ptr(m_token)](auto& event) { if (!token.expired()) { m_command_error_code_dlgs.erase((GUI::DeviceErrorDialog*)event.GetEventObject());} event.Skip(); }); device_error_dialog->show_error_code(command_err); m_command_error_code_dlgs.insert(device_error_dialog); }); }; } bool MachineObject::is_multi_extruders() const { return m_extder_system->GetTotalExtderCount() > 1; } int MachineObject::get_extruder_id_by_ams_id(const std::string& ams_id) { return m_fila_system->GetExtruderIdByAmsId(ams_id); } Slic3r::DevPrintingSpeedLevel MachineObject::GetPrintingSpeedLevel() const { return m_print_options->GetPrintingSpeedLevel(); } bool MachineObject::is_ams_unload() { return m_extder_system->GetTargetAmsId().compare("255") == 0; } Slic3r::DevAms* MachineObject::get_curr_Ams() { return m_fila_system->GetAmsById(m_extder_system->GetCurrentAmsId()); } Slic3r::DevAmsTray* MachineObject::get_ams_tray(std::string ams_id, std::string tray_id) { return m_fila_system->GetAmsTray(ams_id, tray_id); } bool MachineObject::HasAms() const { return m_fila_system->HasAms(); } bool MachineObject::IsDetectOnInsertEnabled() const { return m_fila_system->GetAmsSystemSetting().IsDetectOnInsertEnabled(); } void change_the_opacity(wxColour& colour) { if (colour.Alpha() == 255) { colour = wxColour(colour.Red(), colour.Green(), colour.Blue(), 254); } } } // namespace Slic3r