#include "CalibUtils.hpp" #include "../GUI/I18N.hpp" #include "../GUI/GUI_App.hpp" #include "../GUI/DeviceManager.hpp" #include "../GUI/Jobs/ProgressIndicator.hpp" #include "../GUI/PartPlate.hpp" #include "libslic3r/Model.hpp" #include "../GUI/MsgDialog.hpp" namespace Slic3r { namespace GUI { const float MIN_PA_K_VALUE = 0.0; const float MAX_PA_K_VALUE = 1.0; std::shared_ptr CalibUtils::print_job; wxString wxstr_temp_dir = fs::path(fs::temp_directory_path() / "calib").wstring(); static const std::string temp_dir = wxstr_temp_dir.utf8_string(); static const std::string temp_gcode_path = temp_dir + "/temp.gcode"; static const std::string path = temp_dir + "/test.3mf"; static const std::string config_3mf_path = temp_dir + "/test_config.3mf"; static std::string MachineBedTypeString[5] = { "auto", "pc", "ep", "pei", "pte" }; std::string get_calib_mode_name(CalibMode cali_mode, int stage) { switch(cali_mode) { case CalibMode::Calib_PA_Line: return "pa_line_calib_mode"; case CalibMode::Calib_PA_Pattern: return "pa_pattern_calib_mode"; case CalibMode::Calib_Flow_Rate: if (stage == 1) return "flow_rate_coarse_calib_mode"; else if (stage == 2) return "flow_rate_fine_calib_mode"; else return "flow_rate_coarse_calib_mode"; case CalibMode::Calib_Temp_Tower: return "temp_tower_calib_mode"; case CalibMode::Calib_Vol_speed_Tower: return "vol_speed_tower_calib_mode"; case CalibMode::Calib_VFA_Tower: return "vfa_tower_calib_mode"; case CalibMode::Calib_Retraction_tower: return "retration_tower_calib_mode"; default: assert(false); return ""; } } static wxString to_wstring_name(std::string name) { if (name == "hardened_steel") { return _L("Hardened Steel"); } else if (name == "stainless_steel") { return _L("Stainless Steel"); } return wxEmptyString; } static bool is_same_nozzle_diameters(const DynamicPrintConfig &full_config, const MachineObject *obj, wxString& error_msg) { if (obj == nullptr) return true; try { std::string nozzle_type; const ConfigOptionEnum * config_nozzle_type = full_config.option>("nozzle_type"); if (config_nozzle_type->value == NozzleType::ntHardenedSteel) { nozzle_type = "hardened_steel"; } else if (config_nozzle_type->value == NozzleType::ntStainlessSteel) { nozzle_type = "stainless_steel"; } auto opt_nozzle_diameters = full_config.option("nozzle_diameter"); if (opt_nozzle_diameters != nullptr) { float preset_nozzle_diameter = opt_nozzle_diameters->get_at(0); if (preset_nozzle_diameter != obj->nozzle_diameter) { wxString nozzle_in_preset = wxString::Format(_L("nozzle in preset: %s %s"), wxString::Format("%.1f", preset_nozzle_diameter).ToStdString(), to_wstring_name(nozzle_type)); wxString nozzle_in_printer = wxString::Format(_L("nozzle memorized: %.1f %s"), obj->nozzle_diameter, to_wstring_name(obj->nozzle_type)); error_msg = _L("Your nozzle diameter in preset is not consistent with memorized nozzle diameter. Did you change your nozzle lately?") + "\n " + nozzle_in_preset + "\n " + nozzle_in_printer + "\n"; return false; } } } catch (...) {} return true; } static bool is_same_nozzle_type(const DynamicPrintConfig &full_config, const MachineObject *obj, wxString& error_msg) { if (obj == nullptr) return true; NozzleType nozzle_type = NozzleType::ntUndefine; if (obj->nozzle_type == "stainless_steel") { nozzle_type = NozzleType::ntStainlessSteel; } else if (obj->nozzle_type == "hardened_steel") { nozzle_type = NozzleType::ntHardenedSteel; } int printer_nozzle_hrc = Print::get_hrc_by_nozzle_type(nozzle_type); if (full_config.has("required_nozzle_HRC")) { int filament_nozzle_hrc = full_config.opt_int("required_nozzle_HRC", 0); if (abs(filament_nozzle_hrc) > abs(printer_nozzle_hrc)) { BOOST_LOG_TRIVIAL(info) << "filaments hardness mismatch: printer_nozzle_hrc = " << printer_nozzle_hrc << ", filament_nozzle_hrc = " << filament_nozzle_hrc; std::string filament_type = full_config.opt_string("filament_type", 0); error_msg = wxString::Format(_L("*Printing %s material with %s may cause nozzle damage"), filament_type, to_wstring_name(obj->nozzle_type)); error_msg += "\n"; MessageDialog msg_dlg(nullptr, error_msg, wxEmptyString, wxICON_WARNING | wxOK | wxCANCEL); auto result = msg_dlg.ShowModal(); if (result == wxID_OK) { error_msg.clear(); return true; } else { error_msg.clear(); return false; } } } return true; } static bool check_nozzle_diameter_and_type(const DynamicPrintConfig &full_config, wxString& error_msg) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) { error_msg = _L("Need select printer"); return false; } MachineObject *obj = dev->get_selected_machine(); if (obj == nullptr) { error_msg = _L("Need select printer"); return false; } // P1P/S if (obj->nozzle_type.empty()) return true; if (!is_same_nozzle_diameters(full_config, obj, error_msg)) return false; if (!is_same_nozzle_type(full_config, obj, error_msg)) return false; return true; } CalibMode CalibUtils::get_calib_mode_by_name(const std::string name, int& cali_stage) { if (name == "pa_line_calib_mode") { cali_stage = 0; return CalibMode::Calib_PA_Line; } else if (name == "pa_pattern_calib_mode") { cali_stage = 1; return CalibMode::Calib_PA_Line; } else if (name == "flow_rate_coarse_calib_mode") { cali_stage = 1; return CalibMode::Calib_Flow_Rate; } else if (name == "flow_rate_fine_calib_mode") { cali_stage = 2; return CalibMode::Calib_Flow_Rate; } else if (name == "temp_tower_calib_mode") return CalibMode::Calib_Temp_Tower; else if (name == "vol_speed_tower_calib_mode") return CalibMode::Calib_Vol_speed_Tower; else if (name == "vfa_tower_calib_mode") return CalibMode::Calib_VFA_Tower; else if (name == "retration_tower_calib_mode") return CalibMode::Calib_Retraction_tower; return CalibMode::Calib_None; } bool CalibUtils::validate_input_name(wxString name) { if (name.Length() > 40) { MessageDialog msg_dlg(nullptr, _L("The name cannot exceed 40 characters."), wxEmptyString, wxICON_WARNING | wxOK); msg_dlg.ShowModal(); return false; } name.erase(std::remove(name.begin(), name.end(), L' '), name.end()); if (name.IsEmpty()) { MessageDialog msg_dlg(nullptr, _L("The name cannot be empty."), wxEmptyString, wxICON_WARNING | wxOK); msg_dlg.ShowModal(); return false; } return true; } bool CalibUtils::validate_input_k_value(wxString k_text, float* output_value) { float default_k = 0.0f; if (k_text.IsEmpty()) { *output_value = default_k; return false; } double k_value = 0.0; try { if(!k_text.ToDouble(&k_value)) return false; } catch (...) { ; } if (k_value < MIN_PA_K_VALUE || k_value > MAX_PA_K_VALUE) { *output_value = default_k; return false; } *output_value = k_value; return true; }; bool CalibUtils::validate_input_flow_ratio(wxString flow_ratio, float* output_value) { float default_flow_ratio = 1.0f; if (flow_ratio.IsEmpty()) { *output_value = default_flow_ratio; return false; } double flow_ratio_value = 0.0; try { flow_ratio.ToDouble(&flow_ratio_value); } catch (...) { ; } if (flow_ratio_value <= 0.0 || flow_ratio_value >= 2.0) { *output_value = default_flow_ratio; return false; } *output_value = flow_ratio_value; return true; } static void cut_model(Model &model, std::array plane_points, ModelObjectCutAttributes attributes) { size_t obj_idx = 0; size_t instance_idx = 0; if (!attributes.has(ModelObjectCutAttribute::KeepUpper) && !attributes.has(ModelObjectCutAttribute::KeepLower)) return; auto* object = model.objects[0]; const auto new_objects = object->cut(instance_idx, plane_points, attributes); model.delete_object(obj_idx); for (ModelObject *model_object : new_objects) { auto *object = model.add_object(*model_object); object->sort_volumes(true); std::string object_name = object->name.empty() ? fs::path(object->input_file).filename().string() : object->name; object->ensure_on_bed(); } } static void read_model_from_file(const std::string& input_file, Model& model) { LoadStrategy strategy = LoadStrategy::LoadModel; ConfigSubstitutionContext config_substitutions{ForwardCompatibilitySubstitutionRule::Enable}; int plate_to_slice = 0; bool is_bbl_3mf; Semver file_version; DynamicPrintConfig config; PlateDataPtrs plate_data_src; std::vector project_presets; model = Model::read_from_file(input_file, &config, &config_substitutions, strategy, &plate_data_src, &project_presets, &is_bbl_3mf, &file_version, nullptr, nullptr, nullptr, nullptr, nullptr, plate_to_slice); model.add_default_instances(); for (auto object : model.objects) object->ensure_on_bed(); } std::array get_cut_plane_points(const BoundingBoxf3 &bbox, const double &cut_height) { std::array plane_pts; plane_pts[0] = Vec3d(bbox.min(0), bbox.min(1), cut_height); plane_pts[1] = Vec3d(bbox.max(0), bbox.min(1), cut_height); plane_pts[2] = Vec3d(bbox.max(0), bbox.max(1), cut_height); plane_pts[3] = Vec3d(bbox.min(0), bbox.max(1), cut_height); return plane_pts; } void CalibUtils::calib_PA(const X1CCalibInfos& calib_infos, int mode, wxString& error_message) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; if (calib_infos.calib_datas.size() > 0) obj_->command_start_pa_calibration(calib_infos, mode); } void CalibUtils::emit_get_PA_calib_results(float nozzle_diameter) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; obj_->command_get_pa_calibration_result(nozzle_diameter); } bool CalibUtils::get_PA_calib_results(std::vector& pa_calib_results) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return false; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return false; pa_calib_results = obj_->pa_calib_results; return pa_calib_results.size() > 0; } void CalibUtils::emit_get_PA_calib_infos(float nozzle_diameter) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; obj_->command_get_pa_calibration_tab(nozzle_diameter); } bool CalibUtils::get_PA_calib_tab(std::vector &pa_calib_infos) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return false; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return false; if (obj_->has_get_pa_calib_tab) { pa_calib_infos.assign(obj_->pa_calib_tab.begin(), obj_->pa_calib_tab.end()); } return obj_->has_get_pa_calib_tab; } void CalibUtils::emit_get_PA_calib_info(float nozzle_diameter, const std::string &filament_id) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; obj_->command_get_pa_calibration_tab(nozzle_diameter, filament_id); } bool CalibUtils::get_PA_calib_info(PACalibResult & pa_calib_info) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return false; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return false; if (!obj_->pa_calib_tab.empty()) { pa_calib_info = obj_->pa_calib_tab.front(); return true; } return false; } void CalibUtils::set_PA_calib_result(const std::vector &pa_calib_values, bool is_auto_cali) { DeviceManager* dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject* obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; obj_->command_set_pa_calibration(pa_calib_values, is_auto_cali); } void CalibUtils::select_PA_calib_result(const PACalibIndexInfo& pa_calib_info) { DeviceManager* dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject* obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; obj_->commnad_select_pa_calibration(pa_calib_info); } void CalibUtils::delete_PA_calib_result(const PACalibIndexInfo& pa_calib_info) { DeviceManager* dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject* obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; obj_->command_delete_pa_calibration(pa_calib_info); } void CalibUtils::calib_flowrate_X1C(const X1CCalibInfos& calib_infos, std::string& error_message) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; if (calib_infos.calib_datas.size() > 0) obj_->command_start_flow_ratio_calibration(calib_infos); else { BOOST_LOG_TRIVIAL(info) << "flow_rate_cali: auto | send info | cali_datas is empty."; } } void CalibUtils::emit_get_flow_ratio_calib_results(float nozzle_diameter) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return; obj_->command_get_flow_ratio_calibration_result(nozzle_diameter); } bool CalibUtils::get_flow_ratio_calib_results(std::vector& flow_ratio_calib_results) { DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) return false; MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) return false; flow_ratio_calib_results = obj_->flow_ratio_results; return flow_ratio_calib_results.size() > 0; } bool CalibUtils::calib_flowrate(int pass, const CalibInfo &calib_info, wxString &error_message) { if (pass != 1 && pass != 2) return false; Model model; std::string input_file; if (pass == 1) input_file = Slic3r::resources_dir() + "/calib/filament_flow/flowrate-test-pass1.3mf"; else input_file = Slic3r::resources_dir() + "/calib/filament_flow/flowrate-test-pass2.3mf"; read_model_from_file(input_file, model); DynamicConfig print_config = calib_info.print_prest->config; DynamicConfig filament_config = calib_info.filament_prest->config; DynamicConfig printer_config = calib_info.printer_prest->config; DynamicConfig config_config = calib_info.config_prest->config; /// --- scale --- // model is created for a 0.4 nozzle, scale z with nozzle size. const ConfigOptionFloats *nozzle_diameter_config = printer_config.option("nozzle_diameter"); assert(nozzle_diameter_config->values.size() > 0); float nozzle_diameter = nozzle_diameter_config->values[0]; float xyScale = nozzle_diameter / 0.6; // scale z to have 7 layers double first_layer_height = print_config.option("initial_layer_print_height")->value; double layer_height = nozzle_diameter / 2.0; // prefer 0.2 layer height for 0.4 nozzle first_layer_height = std::max(first_layer_height, layer_height); float zscale = (first_layer_height + 6 * layer_height) / 1.4; for (auto _obj : model.objects) _obj->scale(1, 1, zscale); // only enlarge //if (xyScale > 1.2) { // for (auto _obj : model.objects) _obj->scale(xyScale, xyScale, zscale); //} else { // for (auto _obj : model.objects) _obj->scale(1, 1, zscale); //} Flow infill_flow = Flow(nozzle_diameter * 1.2f, layer_height, nozzle_diameter); double filament_max_volumetric_speed = filament_config.option("filament_max_volumetric_speed")->get_at(0); double max_infill_speed = filament_max_volumetric_speed / (infill_flow.mm3_per_mm() * (pass == 1 ? 1.2 : 1)); double internal_solid_speed = std::floor(std::min(print_config.opt_float("internal_solid_infill_speed"), max_infill_speed)); double top_surface_speed = std::floor(std::min(print_config.opt_float("top_surface_speed"), max_infill_speed)); // adjust parameters filament_config.set_key_value("curr_bed_type", new ConfigOptionEnum(calib_info.bed_type)); for (auto _obj : model.objects) { _obj->ensure_on_bed(); _obj->config.set_key_value("wall_loops", new ConfigOptionInt(3)); _obj->config.set_key_value("top_one_wall_type", new ConfigOptionEnum(TopOneWallType::Topmost)); _obj->config.set_key_value("top_area_threshold", new ConfigOptionPercent(100)); _obj->config.set_key_value("sparse_infill_density", new ConfigOptionPercent(35)); _obj->config.set_key_value("bottom_shell_layers", new ConfigOptionInt(1)); _obj->config.set_key_value("top_shell_layers", new ConfigOptionInt(5)); _obj->config.set_key_value("detect_thin_wall", new ConfigOptionBool(true)); _obj->config.set_key_value("filter_out_gap_fill", new ConfigOptionFloat(0)); // OrcaSlicer parameter _obj->config.set_key_value("sparse_infill_pattern", new ConfigOptionEnum(ipRectilinear)); _obj->config.set_key_value("top_surface_line_width", new ConfigOptionFloat(nozzle_diameter * 1.2f)); _obj->config.set_key_value("internal_solid_infill_line_width", new ConfigOptionFloat(nozzle_diameter * 1.2f)); _obj->config.set_key_value("top_surface_pattern", new ConfigOptionEnum(ipMonotonic)); _obj->config.set_key_value("top_solid_infill_flow_ratio", new ConfigOptionFloat(1.0f)); _obj->config.set_key_value("infill_direction", new ConfigOptionFloat(45)); _obj->config.set_key_value("ironing_type", new ConfigOptionEnum(IroningType::NoIroning)); _obj->config.set_key_value("internal_solid_infill_speed", new ConfigOptionFloat(internal_solid_speed)); _obj->config.set_key_value("top_surface_speed", new ConfigOptionFloat(top_surface_speed)); // extract flowrate from name, filename format: flowrate_xxx std::string obj_name = _obj->name; assert(obj_name.length() > 9); obj_name = obj_name.substr(9); if (obj_name[0] == 'm') obj_name[0] = '-'; auto modifier = stof(obj_name); _obj->config.set_key_value("print_flow_ratio", new ConfigOptionFloat(1.0f + modifier / 100.f)); } print_config.set_key_value("layer_height", new ConfigOptionFloat(layer_height)); print_config.set_key_value("initial_layer_print_height", new ConfigOptionFloat(first_layer_height)); print_config.set_key_value("reduce_crossing_wall", new ConfigOptionBool(true)); // apply preset DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); Calib_Params params; params.mode = CalibMode::Calib_Flow_Rate; if (!process_and_store_3mf(&model, full_config, params, error_message)) return false; DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) { error_message = _L("Need select printer"); return false; } MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) { error_message = _L("Need select printer"); return false; } try { json js; if (pass == 1) js["cali_type"] = "cali_flow_rate_1"; else if (pass == 2) js["cali_type"] = "cali_flow_rate_2"; js["nozzle_diameter"] = nozzle_diameter; js["filament_id"] = calib_info.filament_prest->filament_id; js["printer_type"] = obj_->printer_type; NetworkAgent *agent = GUI::wxGetApp().getAgent(); if (agent) agent->track_event("cali", js.dump()); } catch (...) {} send_to_print(calib_info, error_message, pass); return true; } void CalibUtils::calib_pa_pattern(const CalibInfo &calib_info, Model& model) { DynamicPrintConfig& print_config = calib_info.print_prest->config; DynamicPrintConfig& filament_config = calib_info.filament_prest->config; DynamicPrintConfig& printer_config = calib_info.printer_prest->config; DynamicPrintConfig& config_config = calib_info.config_prest->config; DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); float nozzle_diameter = printer_config.option("nozzle_diameter")->get_at(0); for (const auto opt : SuggestedConfigCalibPAPattern().float_pairs) { print_config.set_key_value(opt.first, new ConfigOptionFloat(opt.second)); } print_config.set_key_value("outer_wall_speed", new ConfigOptionFloat(CalibPressureAdvance::find_optimal_PA_speed( full_config, print_config.get_abs_value("line_width"), print_config.get_abs_value("layer_height"), 0))); for (const auto opt : SuggestedConfigCalibPAPattern().nozzle_ratio_pairs) { print_config.set_key_value(opt.first, new ConfigOptionFloat(nozzle_diameter * opt.second / 100)); } for (const auto opt : SuggestedConfigCalibPAPattern().int_pairs) { print_config.set_key_value(opt.first, new ConfigOptionInt(opt.second)); } print_config.set_key_value(SuggestedConfigCalibPAPattern().brim_pair.first, new ConfigOptionEnum(SuggestedConfigCalibPAPattern().brim_pair.second)); //DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); Vec3d plate_origin(0, 0, 0); CalibPressureAdvancePattern pa_pattern(calib_info.params, full_config, true, model, plate_origin); Pointfs bedfs = full_config.opt("printable_area")->values; double current_width = bedfs[2].x() - bedfs[0].x(); double current_depth = bedfs[2].y() - bedfs[0].y(); Vec3d half_pattern_size = Vec3d(pa_pattern.print_size_x() / 2, pa_pattern.print_size_y() / 2, 0); Vec3d offset = Vec3d(current_width / 2, current_depth / 2, 0) - half_pattern_size; pa_pattern.set_start_offset(offset); pa_pattern.generate_custom_gcodes(full_config, true, model, plate_origin); model.calib_pa_pattern = std::make_unique(pa_pattern); } bool CalibUtils::calib_generic_PA(const CalibInfo &calib_info, wxString &error_message) { const Calib_Params ¶ms = calib_info.params; if (params.mode != CalibMode::Calib_PA_Line && params.mode != CalibMode::Calib_PA_Pattern) return false; Model model; std::string input_file; if (params.mode == CalibMode::Calib_PA_Line) input_file = Slic3r::resources_dir() + "/calib/pressure_advance/pressure_advance_test.stl"; else if (params.mode == CalibMode::Calib_PA_Pattern) input_file = Slic3r::resources_dir() + "/calib/pressure_advance/pa_pattern.3mf"; read_model_from_file(input_file, model); if (params.mode == CalibMode::Calib_PA_Pattern) calib_pa_pattern(calib_info, model); DynamicPrintConfig print_config = calib_info.print_prest->config; DynamicPrintConfig filament_config = calib_info.filament_prest->config; DynamicPrintConfig printer_config = calib_info.printer_prest->config; DynamicPrintConfig config_config = calib_info.config_prest->config; filament_config.set_key_value("curr_bed_type", new ConfigOptionEnum(calib_info.bed_type)); DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); if (!process_and_store_3mf(&model, full_config, params, error_message)) return false; DeviceManager *dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) { error_message = _L("Need select printer"); return false; } MachineObject *obj_ = dev->get_selected_machine(); if (obj_ == nullptr) { error_message = _L("Need select printer"); return false; } try { json js; if (params.mode == CalibMode::Calib_PA_Line) js["cali_type"] = "cali_pa_line"; else if (params.mode == CalibMode::Calib_PA_Pattern) js["cali_type"] = "cali_pa_pattern"; const ConfigOptionFloats *nozzle_diameter_config = printer_config.option("nozzle_diameter"); assert(nozzle_diameter_config->values.size() > 0); float nozzle_diameter = nozzle_diameter_config->values[0]; js["nozzle_diameter"] = nozzle_diameter; js["filament_id"] = calib_info.filament_prest->filament_id; js["printer_type"] = obj_->printer_type; NetworkAgent *agent = GUI::wxGetApp().getAgent(); if (agent) agent->track_event("cali", js.dump()); } catch (...) {} send_to_print(calib_info, error_message); return true; } void CalibUtils::calib_temptue(const CalibInfo &calib_info, wxString &error_message) { const Calib_Params ¶ms = calib_info.params; if (params.mode != CalibMode::Calib_Temp_Tower) return; Model model; std::string input_file = Slic3r::resources_dir() + "/calib/temperature_tower/temperature_tower.stl"; read_model_from_file(input_file, model); // cut upper auto obj_bb = model.objects[0]->bounding_box(); auto block_count = lround((350 - params.start) / 5 + 1); if (block_count > 0) { // add EPSILON offset to avoid cutting at the exact location where the flat surface is auto new_height = block_count * 10.0 + EPSILON; if (new_height < obj_bb.size().z()) { std::array plane_pts; plane_pts[0] = Vec3d(obj_bb.min(0), obj_bb.min(1), new_height); plane_pts[1] = Vec3d(obj_bb.max(0), obj_bb.min(1), new_height); plane_pts[2] = Vec3d(obj_bb.max(0), obj_bb.max(1), new_height); plane_pts[3] = Vec3d(obj_bb.min(0), obj_bb.max(1), new_height); cut_model(model, plane_pts, ModelObjectCutAttribute::KeepLower); } } // cut bottom obj_bb = model.objects[0]->bounding_box(); block_count = lround((350 - params.end) / 5); if (block_count > 0) { auto new_height = block_count * 10.0 + EPSILON; if (new_height < obj_bb.size().z()) { std::array plane_pts; plane_pts[0] = Vec3d(obj_bb.min(0), obj_bb.min(1), new_height); plane_pts[1] = Vec3d(obj_bb.max(0), obj_bb.min(1), new_height); plane_pts[2] = Vec3d(obj_bb.max(0), obj_bb.max(1), new_height); plane_pts[3] = Vec3d(obj_bb.min(0), obj_bb.max(1), new_height); cut_model(model, plane_pts, ModelObjectCutAttribute::KeepUpper); } } // edit preset DynamicPrintConfig print_config = calib_info.print_prest->config; DynamicPrintConfig filament_config = calib_info.filament_prest->config; DynamicPrintConfig printer_config = calib_info.printer_prest->config; DynamicPrintConfig config_config = calib_info.config_prest->config; auto start_temp = lround(params.start); filament_config.set_key_value("nozzle_temperature_initial_layer", new ConfigOptionInts(1, (int) start_temp)); filament_config.set_key_value("nozzle_temperature", new ConfigOptionInts(1, (int) start_temp)); filament_config.set_key_value("curr_bed_type", new ConfigOptionEnum(calib_info.bed_type)); model.objects[0]->config.set_key_value("brim_type", new ConfigOptionEnum(btOuterOnly)); model.objects[0]->config.set_key_value("brim_width", new ConfigOptionFloat(5.0)); model.objects[0]->config.set_key_value("brim_object_gap", new ConfigOptionFloat(0.0)); model.objects[0]->config.set_key_value("enable_support", new ConfigOptionBool(false)); // apply preset DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); process_and_store_3mf(&model, full_config, params, error_message); if (!error_message.empty()) return; send_to_print(calib_info, error_message); } void CalibUtils::calib_max_vol_speed(const CalibInfo &calib_info, wxString &error_message) { const Calib_Params ¶ms = calib_info.params; if (params.mode != CalibMode::Calib_Vol_speed_Tower) return; Model model; std::string input_file = Slic3r::resources_dir() + "/calib/volumetric_speed/SpeedTestStructure.step"; read_model_from_file(input_file, model); DynamicPrintConfig print_config = calib_info.print_prest->config; DynamicPrintConfig filament_config = calib_info.filament_prest->config; DynamicPrintConfig printer_config = calib_info.printer_prest->config; DynamicPrintConfig config_config = calib_info.config_prest->config; auto obj = model.objects[0]; auto bed_shape = printer_config.option("printable_area")->values; BoundingBoxf bed_ext = get_extents(bed_shape); auto scale_obj = (bed_ext.size().x() - 10) / obj->bounding_box().size().x(); if (scale_obj < 1.0) obj->scale(scale_obj, 1, 1); const ConfigOptionFloats *nozzle_diameter_config = printer_config.option("nozzle_diameter"); assert(nozzle_diameter_config->values.size() > 0); double nozzle_diameter = nozzle_diameter_config->values[0]; double line_width = nozzle_diameter * 1.75; double layer_height = nozzle_diameter * 0.8; auto max_lh = printer_config.option("max_layer_height"); if (max_lh->values[0] < layer_height) max_lh->values[0] = {layer_height}; filament_config.set_key_value("filament_max_volumetric_speed", new ConfigOptionFloats{50}); filament_config.set_key_value("slow_down_layer_time", new ConfigOptionInts{0}); filament_config.set_key_value("curr_bed_type", new ConfigOptionEnum(calib_info.bed_type)); print_config.set_key_value("enable_overhang_speed", new ConfigOptionBool{false}); print_config.set_key_value("timelapse_type", new ConfigOptionEnum(tlTraditional)); print_config.set_key_value("wall_loops", new ConfigOptionInt(1)); print_config.set_key_value("top_shell_layers", new ConfigOptionInt(0)); print_config.set_key_value("bottom_shell_layers", new ConfigOptionInt(1)); print_config.set_key_value("sparse_infill_density", new ConfigOptionPercent(0)); print_config.set_key_value("spiral_mode", new ConfigOptionBool(true)); print_config.set_key_value("outer_wall_line_width", new ConfigOptionFloat(line_width)); print_config.set_key_value("initial_layer_print_height", new ConfigOptionFloat(layer_height)); print_config.set_key_value("layer_height", new ConfigOptionFloat(layer_height)); obj->config.set_key_value("brim_type", new ConfigOptionEnum(btOuterAndInner)); obj->config.set_key_value("brim_width", new ConfigOptionFloat(3.0)); obj->config.set_key_value("brim_object_gap", new ConfigOptionFloat(0.0)); // cut upper auto obj_bb = obj->bounding_box(); double height = (params.end - params.start + 1) / params.step; if (height < obj_bb.size().z()) { std::array plane_pts; plane_pts[0] = Vec3d(obj_bb.min(0), obj_bb.min(1), height); plane_pts[1] = Vec3d(obj_bb.max(0), obj_bb.min(1), height); plane_pts[2] = Vec3d(obj_bb.max(0), obj_bb.max(1), height); plane_pts[3] = Vec3d(obj_bb.min(0), obj_bb.max(1), height); cut_model(model, plane_pts, ModelObjectCutAttribute::KeepLower); } auto new_params = params; auto mm3_per_mm = Flow(line_width, layer_height, nozzle_diameter).mm3_per_mm() * filament_config.option("filament_flow_ratio")->get_at(0); //auto mm3_per_mm = Flow(line_width, layer_height, nozzle_diameter).mm3_per_mm() * filament_config.option("fibre_feed_rate")->get_at(0); new_params.end = params.end / mm3_per_mm; new_params.start = params.start / mm3_per_mm; new_params.step = params.step / mm3_per_mm; DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); process_and_store_3mf(&model, full_config, new_params, error_message); if (!error_message.empty()) return; send_to_print(calib_info, error_message); } void CalibUtils::calib_VFA(const CalibInfo &calib_info, wxString &error_message) { const Calib_Params ¶ms = calib_info.params; if (params.mode != CalibMode::Calib_VFA_Tower) return; Model model; std::string input_file = Slic3r::resources_dir() + "/calib/vfa/VFA.stl"; read_model_from_file(input_file, model); DynamicPrintConfig print_config = calib_info.print_prest->config; DynamicPrintConfig filament_config = calib_info.filament_prest->config; DynamicPrintConfig printer_config = calib_info.printer_prest->config; DynamicPrintConfig config_config = calib_info.config_prest->config; filament_config.set_key_value("slow_down_layer_time", new ConfigOptionInts{0}); filament_config.set_key_value("filament_max_volumetric_speed", new ConfigOptionFloats{200}); filament_config.set_key_value("curr_bed_type", new ConfigOptionEnum(calib_info.bed_type)); print_config.set_key_value("enable_overhang_speed", new ConfigOptionBool{false}); print_config.set_key_value("timelapse_type", new ConfigOptionEnum(tlTraditional)); print_config.set_key_value("wall_loops", new ConfigOptionInt(1)); print_config.set_key_value("top_shell_layers", new ConfigOptionInt(0)); print_config.set_key_value("bottom_shell_layers", new ConfigOptionInt(1)); print_config.set_key_value("sparse_infill_density", new ConfigOptionPercent(0)); print_config.set_key_value("spiral_mode", new ConfigOptionBool(true)); model.objects[0]->config.set_key_value("brim_type", new ConfigOptionEnum(btOuterOnly)); model.objects[0]->config.set_key_value("brim_width", new ConfigOptionFloat(3.0)); model.objects[0]->config.set_key_value("brim_object_gap", new ConfigOptionFloat(0.0)); // cut upper auto obj_bb = model.objects[0]->bounding_box(); auto height = 5 * ((params.end - params.start) / params.step + 1); if (height < obj_bb.size().z()) { std::array plane_pts; plane_pts[0] = Vec3d(obj_bb.min(0), obj_bb.min(1), height); plane_pts[1] = Vec3d(obj_bb.max(0), obj_bb.min(1), height); plane_pts[2] = Vec3d(obj_bb.max(0), obj_bb.max(1), height); plane_pts[3] = Vec3d(obj_bb.min(0), obj_bb.max(1), height); cut_model(model, plane_pts, ModelObjectCutAttribute::KeepLower); } else { error_message = _L("The start, end or step is not valid value."); return; } DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); process_and_store_3mf(&model, full_config, params, error_message); if (!error_message.empty()) return; send_to_print(calib_info, error_message); } void CalibUtils::calib_retraction(const CalibInfo &calib_info, wxString &error_message) { const Calib_Params ¶ms = calib_info.params; if (params.mode != CalibMode::Calib_Retraction_tower) return; Model model; std::string input_file = Slic3r::resources_dir() + "/calib/retraction/retraction_tower.stl"; read_model_from_file(input_file, model); DynamicPrintConfig print_config = calib_info.print_prest->config; DynamicPrintConfig filament_config = calib_info.filament_prest->config; DynamicPrintConfig printer_config = calib_info.printer_prest->config; DynamicPrintConfig config_config = calib_info.config_prest->config; auto obj = model.objects[0]; double layer_height = 0.2; auto max_lh = printer_config.option("max_layer_height"); if (max_lh->values[0] < layer_height) max_lh->values[0] = {layer_height}; filament_config.set_key_value("curr_bed_type", new ConfigOptionEnum(calib_info.bed_type)); obj->config.set_key_value("wall_loops", new ConfigOptionInt(2)); obj->config.set_key_value("top_shell_layers", new ConfigOptionInt(0)); obj->config.set_key_value("bottom_shell_layers", new ConfigOptionInt(3)); obj->config.set_key_value("sparse_infill_density", new ConfigOptionPercent(0)); obj->config.set_key_value("initial_layer_print_height", new ConfigOptionFloat(layer_height)); obj->config.set_key_value("layer_height", new ConfigOptionFloat(layer_height)); // cut upper auto obj_bb = obj->bounding_box(); auto height = 1.0 + 0.4 + ((params.end - params.start)) / params.step; if (height < obj_bb.size().z()) { std::array plane_pts = get_cut_plane_points(obj_bb, height); cut_model(model, plane_pts, ModelObjectCutAttribute::KeepLower); } DynamicPrintConfig full_config; full_config.apply(FullPrintConfig::defaults()); full_config.apply(print_config); full_config.apply(filament_config); full_config.apply(printer_config); full_config.apply(config_config); process_and_store_3mf(&model, full_config, params, error_message); if (!error_message.empty()) return; send_to_print(calib_info, error_message); } int CalibUtils::get_selected_calib_idx(const std::vector &pa_calib_values, int cali_idx) { for (int i = 0; i < pa_calib_values.size(); ++i) { if(pa_calib_values[i].cali_idx == cali_idx) return i; } return -1; } bool CalibUtils::get_pa_k_n_value_by_cali_idx(const MachineObject *obj, int cali_idx, float &out_k, float &out_n) { if (!obj) return false; for (auto pa_calib_info : obj->pa_calib_tab) { if (pa_calib_info.cali_idx == cali_idx) { out_k = pa_calib_info.k_value; out_n = pa_calib_info.n_coef; return true; } } return false; } bool CalibUtils::process_and_store_3mf(Model *model, const DynamicPrintConfig &full_config, const Calib_Params ¶ms, wxString &error_message) { Pointfs bedfs = full_config.opt("printable_area")->values; double print_height = full_config.opt_float("printable_height"); double current_width = bedfs[2].x() - bedfs[0].x(); double current_depth = bedfs[2].y() - bedfs[0].y(); Vec3i plate_size; plate_size[0] = bedfs[2].x() - bedfs[0].x(); plate_size[1] = bedfs[2].y() - bedfs[0].y(); plate_size[2] = print_height; if (params.mode == CalibMode::Calib_PA_Line) { double space_y = 3.5; int max_line_nums = int(plate_size[1] - 10) / space_y; int count = std::llround(std::ceil((params.end - params.start) / params.step)) + 1; if (count > max_line_nums) { error_message = _L("Unable to calibrate: maybe because the set calibration value range is too large, or the step is too small"); return false; } } if (params.mode == CalibMode::Calib_PA_Pattern) { ModelInstance *instance = model->objects[0]->instances[0]; Vec3d offset = model->calib_pa_pattern->get_start_offset() + Vec3d(model->calib_pa_pattern->handle_xy_size() / 2, -model->calib_pa_pattern->handle_xy_size() / 2 - model->calib_pa_pattern->handle_spacing(), 0); instance->set_offset(offset); } else if (model->objects.size() == 1) { ModelInstance *instance = model->objects[0]->instances[0]; instance->set_offset(instance->get_offset() + Vec3d(current_width / 2, current_depth / 2, 0)); } else { BoundingBoxf3 bbox = model->bounding_box(); Vec3d bbox_center = bbox.center(); for (auto object : model->objects) { ModelInstance *instance = object->instances[0]; instance->set_offset(instance->get_offset() + Vec3d(current_width / 2 - bbox_center.x(), current_depth / 2 - bbox_center.y(), 0)); } } Slic3r::GUI::PartPlateList partplate_list(nullptr, model, PrinterTechnology::ptFFF); partplate_list.reset_size(plate_size.x(), plate_size.y(), plate_size.z(), false); Slic3r::GUI::PartPlate *part_plate = partplate_list.get_plate(0); PrintBase * print = NULL; Slic3r::GUI::GCodeResult *gcode_result = NULL; int print_index; part_plate->get_print(&print, &gcode_result, &print_index); BuildVolume build_volume(bedfs, print_height); unsigned int count = model->update_print_volume_state(build_volume); if (count == 0) { error_message = _L("Unable to calibrate: maybe because the set calibration value range is too large, or the step is too small"); return false; } // apply the new print config DynamicPrintConfig new_print_config = full_config; print->apply(*model, new_print_config); Print *fff_print = dynamic_cast(print); fff_print->set_calib_params(params); //StringObjectException warning; //auto err = print->validate(&warning); //if (!err.string.empty()) { // error_message = "slice validate: " + err.string; // return; //} if (!check_nozzle_diameter_and_type(full_config, error_message)) return false; fff_print->process(); part_plate->update_slice_result_valid_state(true); gcode_result->reset(); fff_print->export_gcode(temp_gcode_path, gcode_result, nullptr); std::vector thumbnails; PlateDataPtrs plate_data_list; partplate_list.store_to_3mf_structure(plate_data_list, true, 0); for (auto plate_data : plate_data_list) { plate_data->gcode_file = temp_gcode_path; plate_data->is_sliced_valid = true; FilamentInfo& filament_info = plate_data->slice_filaments_info.front(); filament_info.type = full_config.opt_string("filament_type", 0); } //draw thumbnails { GLVolumeCollection glvolume_collection; std::vector> colors_out(1); unsigned char rgb_color[4] = {255, 255, 255, 255}; std::array new_color {1.0f, 1.0f, 1.0f, 1.0f}; colors_out.push_back(new_color); ThumbnailData* thumbnail_data = &plate_data_list[0]->plate_thumbnail; unsigned int thumbnail_width = 512, thumbnail_height = 512; const ThumbnailsParams thumbnail_params = {{}, false, true, true, true, 0}; GLShaderProgram* shader = wxGetApp().get_shader("thumbnail"); for (unsigned int obj_idx = 0; obj_idx < (unsigned int)model->objects.size(); ++ obj_idx) { const ModelObject &model_object = *model->objects[obj_idx]; for (int volume_idx = 0; volume_idx < (int)model_object.volumes.size(); ++ volume_idx) { const ModelVolume &model_volume = *model_object.volumes[volume_idx]; for (int instance_idx = 0; instance_idx < (int)model_object.instances.size(); ++ instance_idx) { const ModelInstance &model_instance = *model_object.instances[instance_idx]; glvolume_collection.load_object_volume(&model_object, obj_idx, volume_idx, instance_idx, "volume", true, false, true); glvolume_collection.volumes.back()->set_render_color( new_color[0], new_color[1], new_color[2], new_color[3]); glvolume_collection.volumes.back()->set_color(new_color); //glvolume_collection.volumes.back()->printable = model_instance.printable; } } } switch (Slic3r::GUI::OpenGLManager::get_framebuffers_type()) { case Slic3r::GUI::OpenGLManager::EFramebufferType::Arb: { BOOST_LOG_TRIVIAL(info) << __FUNCTION__<< boost::format(": framebuffer_type: ARB"); Slic3r::GUI::GLCanvas3D::render_thumbnail_framebuffer(*thumbnail_data, thumbnail_width, thumbnail_height, thumbnail_params, partplate_list, model->objects, glvolume_collection, colors_out, shader, Slic3r::GUI::Camera::EType::Ortho); break; } case Slic3r::GUI::OpenGLManager::EFramebufferType::Ext: { BOOST_LOG_TRIVIAL(info) << __FUNCTION__<< boost::format(": framebuffer_type: EXT"); Slic3r::GUI::GLCanvas3D::render_thumbnail_framebuffer_ext(*thumbnail_data, thumbnail_width, thumbnail_height, thumbnail_params, partplate_list, model->objects, glvolume_collection, colors_out, shader, Slic3r::GUI::Camera::EType::Ortho); break; } default: BOOST_LOG_TRIVIAL(info) << boost::format("framebuffer_type: unknown"); break; } thumbnails.push_back(thumbnail_data); } StoreParams store_params; store_params.path = path.c_str(); store_params.model = model; store_params.plate_data_list = plate_data_list; store_params.config = &new_print_config; store_params.export_plate_idx = 0; store_params.thumbnail_data = thumbnails; store_params.strategy = SaveStrategy::Silence | SaveStrategy::WithGcode | SaveStrategy::SplitModel | SaveStrategy::SkipModel; bool success = Slic3r::store_bbs_3mf(store_params); store_params.strategy = SaveStrategy::Silence | SaveStrategy::SplitModel | SaveStrategy::WithSliceInfo | SaveStrategy::SkipAuxiliary; store_params.path = config_3mf_path.c_str(); success = Slic3r::store_bbs_3mf(store_params); release_PlateData_list(plate_data_list); return true; } void CalibUtils::send_to_print(const CalibInfo &calib_info, wxString &error_message, int flow_ratio_mode) { { // before send json j; j["print"]["cali_mode"] = calib_info.params.mode; j["print"]["start"] = calib_info.params.start; j["print"]["end"] = calib_info.params.end; j["print"]["step"] = calib_info.params.step; j["print"]["print_numbers"] = calib_info.params.print_numbers; j["print"]["flow_ratio_mode"] = flow_ratio_mode; j["print"]["tray_id"] = calib_info.select_ams; j["print"]["dev_id"] = calib_info.dev_id; j["print"]["bed_type"] = calib_info.bed_type; j["print"]["printer_prest"] = calib_info.printer_prest ? calib_info.printer_prest->name : ""; j["print"]["filament_prest"] = calib_info.filament_prest ? calib_info.filament_prest->name : ""; j["print"]["print_prest"] = calib_info.print_prest ? calib_info.print_prest->name : ""; BOOST_LOG_TRIVIAL(info) << "send_cali_job - before send: " << j.dump(); } std::string dev_id = calib_info.dev_id; std::string select_ams = calib_info.select_ams; std::shared_ptr process_bar = calib_info.process_bar; BedType bed_type = calib_info.bed_type; DeviceManager* dev = Slic3r::GUI::wxGetApp().getDeviceManager(); if (!dev) { error_message = _L("Need select printer"); return; } MachineObject* obj_ = dev->get_selected_machine(); if (obj_ == nullptr) { error_message = _L("Need select printer"); return; } if (obj_->is_in_upgrading()) { error_message = _L("Cannot send the print job when the printer is updating firmware"); return; } else if (obj_->is_system_printing()) { error_message = _L("The printer is executing instructions. Please restart printing after it ends"); return; } else if (obj_->is_in_printing()) { error_message = _L("The printer is busy on other print job"); return; } else if (!obj_->is_support_print_without_sd && (obj_->get_sdcard_state() == MachineObject::SdcardState::NO_SDCARD)) { error_message = _L("An SD card needs to be inserted before printing."); return; } if (obj_->is_lan_mode_printer()) { if (obj_->get_sdcard_state() == MachineObject::SdcardState::NO_SDCARD) { error_message = _L("An SD card needs to be inserted before printing via LAN."); return; } } print_job = std::make_shared(std::move(process_bar), wxGetApp().plater(), dev_id); print_job->m_dev_ip = obj_->dev_ip; print_job->m_ftp_folder = obj_->get_ftp_folder(); print_job->m_access_code = obj_->get_access_code(); #if !BBL_RELEASE_TO_PUBLIC print_job->m_local_use_ssl_for_ftp = wxGetApp().app_config->get("enable_ssl_for_ftp") == "true" ? true : false; print_job->m_local_use_ssl_for_mqtt = wxGetApp().app_config->get("enable_ssl_for_mqtt") == "true" ? true : false; #else print_job->m_local_use_ssl_for_ftp = obj_->local_use_ssl_for_ftp; print_job->m_local_use_ssl_for_mqtt = obj_->local_use_ssl_for_mqtt; #endif print_job->connection_type = obj_->connection_type(); print_job->cloud_print_only = obj_->is_support_cloud_print_only; PrintPrepareData job_data; job_data.is_from_plater = false; job_data.plate_idx = 0; job_data._3mf_config_path = config_3mf_path; job_data._3mf_path = path; job_data._temp_path = temp_dir; PlateListData plate_data; plate_data.is_valid = true; plate_data.plate_count = 1; plate_data.cur_plate_index = 0; plate_data.bed_type = bed_type; print_job->job_data = job_data; print_job->plate_data = plate_data; print_job->m_print_type = "from_normal"; print_job->task_ams_mapping = select_ams; print_job->task_ams_mapping_info = ""; print_job->task_use_ams = select_ams == "[254]" ? false : true; CalibMode cali_mode = calib_info.params.mode; print_job->m_project_name = get_calib_mode_name(cali_mode, flow_ratio_mode); print_job->set_calibration_task(true); print_job->has_sdcard = obj_->has_sdcard(); print_job->set_print_config(MachineBedTypeString[bed_type], true, false, false, false, true); print_job->set_print_job_finished_event(wxGetApp().plater()->get_send_calibration_finished_event(), print_job->m_project_name); { // after send: record the print job json j; j["print"]["project_name"] = print_job->m_project_name; j["print"]["is_cali_task"] = print_job->m_is_calibration_task; BOOST_LOG_TRIVIAL(info) << "send_cali_job - after send: " << j.dump(); } print_job->start(); } } }