#include "AppController.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include namespace Slic3r { class AppControllerBoilerplate::PriMap { public: using M = std::unordered_map; std::mutex m; M store; std::thread::id ui_thread; inline explicit PriMap(std::thread::id uit): ui_thread(uit) {} }; AppControllerBoilerplate::AppControllerBoilerplate() :progressind_(new PriMap(std::this_thread::get_id())) {} AppControllerBoilerplate::~AppControllerBoilerplate() { progressind_.reset(); } bool AppControllerBoilerplate::is_main_thread() const { return progressind_->ui_thread == std::this_thread::get_id(); } namespace GUI { PresetBundle* get_preset_bundle(); } static const PrintObjectStep STEP_SLICE = posSlice; static const PrintObjectStep STEP_PERIMETERS = posPerimeters; static const PrintObjectStep STEP_PREPARE_INFILL = posPrepareInfill; static const PrintObjectStep STEP_INFILL = posInfill; static const PrintObjectStep STEP_SUPPORTMATERIAL = posSupportMaterial; static const PrintStep STEP_SKIRT = psSkirt; static const PrintStep STEP_BRIM = psBrim; static const PrintStep STEP_WIPE_TOWER = psWipeTower; void AppControllerBoilerplate::progress_indicator( AppControllerBoilerplate::ProgresIndicatorPtr progrind) { progressind_->m.lock(); progressind_->store[std::this_thread::get_id()] = progrind; progressind_->m.unlock(); } void AppControllerBoilerplate::progress_indicator(unsigned statenum, const string &title, const string &firstmsg) { progressind_->m.lock(); progressind_->store[std::this_thread::get_id()] = create_progress_indicator(statenum, title, firstmsg); progressind_->m.unlock(); } void AppControllerBoilerplate::progress_indicator(unsigned statenum, const string &title) { progressind_->m.lock(); progressind_->store[std::this_thread::get_id()] = create_progress_indicator(statenum, title); progressind_->m.unlock(); } AppControllerBoilerplate::ProgresIndicatorPtr AppControllerBoilerplate::progress_indicator() { PriMap::M::iterator pret; ProgresIndicatorPtr ret; progressind_->m.lock(); if( (pret = progressind_->store.find(std::this_thread::get_id())) == progressind_->store.end()) { progressind_->store[std::this_thread::get_id()] = ret = global_progressind_; } else ret = pret->second; progressind_->m.unlock(); return ret; } void PrintController::make_skirt() { assert(print_ != nullptr); // prerequisites for(auto obj : print_->objects) make_perimeters(obj); for(auto obj : print_->objects) infill(obj); for(auto obj : print_->objects) gen_support_material(obj); if(!print_->state.is_done(STEP_SKIRT)) { print_->state.set_started(STEP_SKIRT); print_->skirt.clear(); if(print_->has_skirt()) print_->_make_skirt(); print_->state.set_done(STEP_SKIRT); } } void PrintController::make_brim() { assert(print_ != nullptr); // prerequisites for(auto obj : print_->objects) make_perimeters(obj); for(auto obj : print_->objects) infill(obj); for(auto obj : print_->objects) gen_support_material(obj); make_skirt(); if(!print_->state.is_done(STEP_BRIM)) { print_->state.set_started(STEP_BRIM); // since this method must be idempotent, we clear brim paths *before* // checking whether we need to generate them print_->brim.clear(); if(print_->config.brim_width > 0) print_->_make_brim(); print_->state.set_done(STEP_BRIM); } } void PrintController::make_wipe_tower() { assert(print_ != nullptr); // prerequisites for(auto obj : print_->objects) make_perimeters(obj); for(auto obj : print_->objects) infill(obj); for(auto obj : print_->objects) gen_support_material(obj); make_skirt(); make_brim(); if(!print_->state.is_done(STEP_WIPE_TOWER)) { print_->state.set_started(STEP_WIPE_TOWER); // since this method must be idempotent, we clear brim paths *before* // checking whether we need to generate them print_->brim.clear(); if(print_->has_wipe_tower()) print_->_make_wipe_tower(); print_->state.set_done(STEP_WIPE_TOWER); } } void PrintController::slice(PrintObject *pobj) { assert(pobj != nullptr && print_ != nullptr); if(pobj->state.is_done(STEP_SLICE)) return; pobj->state.set_started(STEP_SLICE); pobj->_slice(); auto msg = pobj->_fix_slicing_errors(); if(!msg.empty()) report_issue(IssueType::WARN, msg); // simplify slices if required if (print_->config.resolution) pobj->_simplify_slices(scale_(print_->config.resolution)); if(pobj->layers.empty()) report_issue(IssueType::ERR, _(L("No layers were detected. You might want to repair your " "STL file(s) or check their size or thickness and retry")) ); pobj->state.set_done(STEP_SLICE); } void PrintController::make_perimeters(PrintObject *pobj) { assert(pobj != nullptr); slice(pobj); auto&& prgind = progress_indicator(); if (!pobj->state.is_done(STEP_PERIMETERS)) { pobj->_make_perimeters(); } } void PrintController::infill(PrintObject *pobj) { assert(pobj != nullptr); make_perimeters(pobj); if (!pobj->state.is_done(STEP_PREPARE_INFILL)) { pobj->state.set_started(STEP_PREPARE_INFILL); pobj->_prepare_infill(); pobj->state.set_done(STEP_PREPARE_INFILL); } pobj->_infill(); } void PrintController::gen_support_material(PrintObject *pobj) { assert(pobj != nullptr); // prerequisites slice(pobj); if(!pobj->state.is_done(STEP_SUPPORTMATERIAL)) { pobj->state.set_started(STEP_SUPPORTMATERIAL); pobj->clear_support_layers(); if((pobj->config.support_material || pobj->config.raft_layers > 0) && pobj->layers.size() > 1) { pobj->_generate_support_material(); } pobj->state.set_done(STEP_SUPPORTMATERIAL); } } void PrintController::slice(AppControllerBoilerplate::ProgresIndicatorPtr pri) { auto st = pri->state(); Slic3r::trace(3, "Starting the slicing process."); pri->update(st+20, _(L("Generating perimeters"))); for(auto obj : print_->objects) make_perimeters(obj); pri->update(st+60, _(L("Infilling layers"))); for(auto obj : print_->objects) infill(obj); pri->update(st+70, _(L("Generating support material"))); for(auto obj : print_->objects) gen_support_material(obj); pri->message_fmt(_(L("Weight: %.1fg, Cost: %.1f")), print_->total_weight, print_->total_cost); pri->state(st+85); pri->update(st+88, _(L("Generating skirt"))); make_skirt(); pri->update(st+90, _(L("Generating brim"))); make_brim(); pri->update(st+95, _(L("Generating wipe tower"))); make_wipe_tower(); pri->update(st+100, _(L("Done"))); // time to make some statistics.. Slic3r::trace(3, _(L("Slicing process finished."))); } void PrintController::slice() { auto pri = progress_indicator(); slice(pri); } void IProgressIndicator::message_fmt( const string &fmtstr, ...) { std::stringstream ss; va_list args; va_start(args, fmtstr); auto fmt = fmtstr.begin(); while (*fmt != '\0') { if (*fmt == 'd') { int i = va_arg(args, int); ss << i << '\n'; } else if (*fmt == 'c') { // note automatic conversion to integral type int c = va_arg(args, int); ss << static_cast(c) << '\n'; } else if (*fmt == 'f') { double d = va_arg(args, double); ss << d << '\n'; } ++fmt; } va_end(args); message(ss.str()); } const PrintConfig &PrintController::config() const { return print_->config; } void AppController::arrange_model() { auto ftr = std::async( supports_asynch()? std::launch::async : std::launch::deferred, [this]() { unsigned count = 0; for(auto obj : model_->objects) count += obj->instances.size(); auto pind = progress_indicator(); float pmax = 1.0; if(pind) { pmax = pind->max(); // Set the range of the progress to the object count pind->max(count); } auto dist = print_ctl()->config().min_object_distance(); BoundingBoxf bb(print_ctl()->config().bed_shape.values); if(pind) pind->update(0, _(L("Arranging objects..."))); try { model_->arrange_objects(dist, &bb, [pind, count](unsigned rem){ if(pind) pind->update(count - rem, _(L("Arranging objects..."))); }); } catch(std::exception& e) { std::cerr << e.what() << std::endl; report_issue(IssueType::ERR, _(L("Could not arrange model objects! " "Some geometries may be invalid.")), _(L("Exception occurred"))); } // Restore previous max value if(pind) { pind->max(pmax); pind->update(0, _(L("Arranging done."))); } }); while( ftr.wait_for(std::chrono::milliseconds(10)) != std::future_status::ready) { process_events(); } } }