#include "../libslic3r.h" #include "../Model.hpp" #include "../Utils.hpp" #include "../GCode.hpp" #include "../Geometry.hpp" #include "3mf.hpp" #include #include #include #include #include #include #include #include #include #include #include namespace pt = boost::property_tree; #include #include #include "miniz_extension.hpp" // VERSION NUMBERS // 0 : .3mf, files saved by older slic3r or other applications. No version definition in them. // 1 : Introduction of 3mf versioning. No other change in data saved into 3mf files. const unsigned int VERSION_3MF = 1; const char* SLIC3RPE_3MF_VERSION = "slic3rpe:Version3mf"; // definition of the metadata name saved into .model file const std::string MODEL_FOLDER = "3D/"; const std::string MODEL_EXTENSION = ".model"; const std::string MODEL_FILE = "3D/3dmodel.model"; // << this is the only format of the string which works with CURA const std::string CONTENT_TYPES_FILE = "[Content_Types].xml"; const std::string RELATIONSHIPS_FILE = "_rels/.rels"; const std::string PRINT_CONFIG_FILE = "Metadata/Slic3r_PE.config"; const std::string MODEL_CONFIG_FILE = "Metadata/Slic3r_PE_model.config"; const std::string LAYER_HEIGHTS_PROFILE_FILE = "Metadata/Slic3r_PE_layer_heights_profile.txt"; const std::string LAYER_CONFIG_RANGES_FILE = "Metadata/Prusa_Slicer_layer_config_ranges.xml"; const std::string SLA_SUPPORT_POINTS_FILE = "Metadata/Slic3r_PE_sla_support_points.txt"; const char* MODEL_TAG = "model"; const char* RESOURCES_TAG = "resources"; const char* OBJECT_TAG = "object"; const char* MESH_TAG = "mesh"; const char* VERTICES_TAG = "vertices"; const char* VERTEX_TAG = "vertex"; const char* TRIANGLES_TAG = "triangles"; const char* TRIANGLE_TAG = "triangle"; const char* COMPONENTS_TAG = "components"; const char* COMPONENT_TAG = "component"; const char* BUILD_TAG = "build"; const char* ITEM_TAG = "item"; const char* METADATA_TAG = "metadata"; const char* CONFIG_TAG = "config"; const char* VOLUME_TAG = "volume"; const char* UNIT_ATTR = "unit"; const char* NAME_ATTR = "name"; const char* TYPE_ATTR = "type"; const char* ID_ATTR = "id"; const char* X_ATTR = "x"; const char* Y_ATTR = "y"; const char* Z_ATTR = "z"; const char* V1_ATTR = "v1"; const char* V2_ATTR = "v2"; const char* V3_ATTR = "v3"; const char* OBJECTID_ATTR = "objectid"; const char* TRANSFORM_ATTR = "transform"; const char* KEY_ATTR = "key"; const char* VALUE_ATTR = "value"; const char* FIRST_TRIANGLE_ID_ATTR = "firstid"; const char* LAST_TRIANGLE_ID_ATTR = "lastid"; const char* OBJECT_TYPE = "object"; const char* VOLUME_TYPE = "volume"; const char* NAME_KEY = "name"; const char* MODIFIER_KEY = "modifier"; const char* VOLUME_TYPE_KEY = "volume_type"; const unsigned int VALID_OBJECT_TYPES_COUNT = 1; const char* VALID_OBJECT_TYPES[] = { "model" }; const unsigned int INVALID_OBJECT_TYPES_COUNT = 4; const char* INVALID_OBJECT_TYPES[] = { "solidsupport", "support", "surface", "other" }; const char* get_attribute_value_charptr(const char** attributes, unsigned int attributes_size, const char* attribute_key) { if ((attributes == nullptr) || (attributes_size == 0) || (attributes_size % 2 != 0) || (attribute_key == nullptr)) return nullptr; for (unsigned int a = 0; a < attributes_size; a += 2) { if (::strcmp(attributes[a], attribute_key) == 0) return attributes[a + 1]; } return nullptr; } std::string get_attribute_value_string(const char** attributes, unsigned int attributes_size, const char* attribute_key) { const char* text = get_attribute_value_charptr(attributes, attributes_size, attribute_key); return (text != nullptr) ? text : ""; } float get_attribute_value_float(const char** attributes, unsigned int attributes_size, const char* attribute_key) { const char* text = get_attribute_value_charptr(attributes, attributes_size, attribute_key); return (text != nullptr) ? (float)::atof(text) : 0.0f; } int get_attribute_value_int(const char** attributes, unsigned int attributes_size, const char* attribute_key) { const char* text = get_attribute_value_charptr(attributes, attributes_size, attribute_key); return (text != nullptr) ? ::atoi(text) : 0; } Slic3r::Transform3d get_transform_from_string(const std::string& mat_str) { if (mat_str.empty()) // empty string means default identity matrix return Slic3r::Transform3d::Identity(); std::vector mat_elements_str; boost::split(mat_elements_str, mat_str, boost::is_any_of(" "), boost::token_compress_on); unsigned int size = (unsigned int)mat_elements_str.size(); if (size != 12) // invalid data, return identity matrix return Slic3r::Transform3d::Identity(); Slic3r::Transform3d ret = Slic3r::Transform3d::Identity(); unsigned int i = 0; // matrices are stored into 3mf files as 4x3 // we need to transpose them for (unsigned int c = 0; c < 4; ++c) { for (unsigned int r = 0; r < 3; ++r) { ret(r, c) = ::atof(mat_elements_str[i++].c_str()); } } return ret; } float get_unit_factor(const std::string& unit) { const char* text = unit.c_str(); if (::strcmp(text, "micron") == 0) return 0.001f; else if (::strcmp(text, "centimeter") == 0) return 10.0f; else if (::strcmp(text, "inch") == 0) return 25.4f; else if (::strcmp(text, "foot") == 0) return 304.8f; else if (::strcmp(text, "meter") == 0) return 1000.0f; else // default "millimeters" (see specification) return 1.0f; } bool is_valid_object_type(const std::string& type) { // if the type is empty defaults to "model" (see specification) if (type.empty()) return true; for (unsigned int i = 0; i < VALID_OBJECT_TYPES_COUNT; ++i) { if (::strcmp(type.c_str(), VALID_OBJECT_TYPES[i]) == 0) return true; } return false; } namespace Slic3r { // Base class with error messages management class _3MF_Base { std::vector m_errors; protected: void add_error(const std::string& error) { m_errors.push_back(error); } void clear_errors() { m_errors.clear(); } public: void log_errors() { for (const std::string& error : m_errors) { printf("%s\n", error.c_str()); } } }; class _3MF_Importer : public _3MF_Base { struct Component { int object_id; Transform3d transform; explicit Component(int object_id) : object_id(object_id) , transform(Transform3d::Identity()) { } Component(int object_id, const Transform3d& transform) : object_id(object_id) , transform(transform) { } }; typedef std::vector ComponentsList; struct Geometry { std::vector vertices; std::vector triangles; bool empty() { return vertices.empty() || triangles.empty(); } void reset() { vertices.clear(); triangles.clear(); } }; struct CurrentObject { // ID of the object inside the 3MF file, 1 based. int id; // Index of the ModelObject in its respective Model, zero based. int model_object_idx; Geometry geometry; ModelObject* object; ComponentsList components; CurrentObject() { reset(); } void reset() { id = -1; model_object_idx = -1; geometry.reset(); object = nullptr; components.clear(); } }; struct CurrentConfig { int object_id; int volume_id; }; struct Instance { ModelInstance* instance; Transform3d transform; Instance(ModelInstance* instance, const Transform3d& transform) : instance(instance) , transform(transform) { } }; struct Metadata { std::string key; std::string value; Metadata(const std::string& key, const std::string& value) : key(key) , value(value) { } }; typedef std::vector MetadataList; struct ObjectMetadata { struct VolumeMetadata { unsigned int first_triangle_id; unsigned int last_triangle_id; MetadataList metadata; VolumeMetadata(unsigned int first_triangle_id, unsigned int last_triangle_id) : first_triangle_id(first_triangle_id) , last_triangle_id(last_triangle_id) { } }; typedef std::vector VolumeMetadataList; MetadataList metadata; VolumeMetadataList volumes; }; // Map from a 1 based 3MF object ID to a 0 based ModelObject index inside m_model->objects. typedef std::map IdToModelObjectMap; typedef std::map IdToAliasesMap; typedef std::vector InstancesList; typedef std::map IdToMetadataMap; typedef std::map IdToGeometryMap; typedef std::map> IdToLayerHeightsProfileMap; typedef std::map IdToLayerConfigRangesMap; typedef std::map> IdToSlaSupportPointsMap; // Version of the 3mf file unsigned int m_version; XML_Parser m_xml_parser; Model* m_model; float m_unit_factor; CurrentObject m_curr_object; IdToModelObjectMap m_objects; IdToAliasesMap m_objects_aliases; InstancesList m_instances; IdToGeometryMap m_geometries; CurrentConfig m_curr_config; IdToMetadataMap m_objects_metadata; IdToLayerHeightsProfileMap m_layer_heights_profiles; IdToLayerConfigRangesMap m_layer_config_ranges; IdToSlaSupportPointsMap m_sla_support_points; std::string m_curr_metadata_name; std::string m_curr_characters; std::string m_name; public: _3MF_Importer(); ~_3MF_Importer(); bool load_model_from_file(const std::string& filename, Model& model, DynamicPrintConfig& config); private: void _destroy_xml_parser(); void _stop_xml_parser(); bool _load_model_from_file(const std::string& filename, Model& model, DynamicPrintConfig& config); bool _extract_model_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat); void _extract_layer_heights_profile_config_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat); void _extract_layer_config_ranges_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat); void _extract_sla_support_points_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat); void _extract_print_config_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat, DynamicPrintConfig& config, const std::string& archive_filename); bool _extract_model_config_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat, Model& model); // handlers to parse the .model file void _handle_start_model_xml_element(const char* name, const char** attributes); void _handle_end_model_xml_element(const char* name); void _handle_model_xml_characters(const XML_Char* s, int len); // handlers to parse the MODEL_CONFIG_FILE file void _handle_start_config_xml_element(const char* name, const char** attributes); void _handle_end_config_xml_element(const char* name); bool _handle_start_model(const char** attributes, unsigned int num_attributes); bool _handle_end_model(); bool _handle_start_resources(const char** attributes, unsigned int num_attributes); bool _handle_end_resources(); bool _handle_start_object(const char** attributes, unsigned int num_attributes); bool _handle_end_object(); bool _handle_start_mesh(const char** attributes, unsigned int num_attributes); bool _handle_end_mesh(); bool _handle_start_vertices(const char** attributes, unsigned int num_attributes); bool _handle_end_vertices(); bool _handle_start_vertex(const char** attributes, unsigned int num_attributes); bool _handle_end_vertex(); bool _handle_start_triangles(const char** attributes, unsigned int num_attributes); bool _handle_end_triangles(); bool _handle_start_triangle(const char** attributes, unsigned int num_attributes); bool _handle_end_triangle(); bool _handle_start_components(const char** attributes, unsigned int num_attributes); bool _handle_end_components(); bool _handle_start_component(const char** attributes, unsigned int num_attributes); bool _handle_end_component(); bool _handle_start_build(const char** attributes, unsigned int num_attributes); bool _handle_end_build(); bool _handle_start_item(const char** attributes, unsigned int num_attributes); bool _handle_end_item(); bool _handle_start_metadata(const char** attributes, unsigned int num_attributes); bool _handle_end_metadata(); bool _create_object_instance(int object_id, const Transform3d& transform, unsigned int recur_counter); void _apply_transform(ModelInstance& instance, const Transform3d& transform); bool _handle_start_config(const char** attributes, unsigned int num_attributes); bool _handle_end_config(); bool _handle_start_config_object(const char** attributes, unsigned int num_attributes); bool _handle_end_config_object(); bool _handle_start_config_volume(const char** attributes, unsigned int num_attributes); bool _handle_end_config_volume(); bool _handle_start_config_metadata(const char** attributes, unsigned int num_attributes); bool _handle_end_config_metadata(); bool _generate_volumes(ModelObject& object, const Geometry& geometry, const ObjectMetadata::VolumeMetadataList& volumes); // callbacks to parse the .model file static void XMLCALL _handle_start_model_xml_element(void* userData, const char* name, const char** attributes); static void XMLCALL _handle_end_model_xml_element(void* userData, const char* name); static void XMLCALL _handle_model_xml_characters(void* userData, const XML_Char* s, int len); // callbacks to parse the MODEL_CONFIG_FILE file static void XMLCALL _handle_start_config_xml_element(void* userData, const char* name, const char** attributes); static void XMLCALL _handle_end_config_xml_element(void* userData, const char* name); }; _3MF_Importer::_3MF_Importer() : m_version(0) , m_xml_parser(nullptr) , m_model(nullptr) , m_unit_factor(1.0f) , m_curr_metadata_name("") , m_curr_characters("") , m_name("") { } _3MF_Importer::~_3MF_Importer() { _destroy_xml_parser(); } bool _3MF_Importer::load_model_from_file(const std::string& filename, Model& model, DynamicPrintConfig& config) { m_version = 0; m_model = &model; m_unit_factor = 1.0f; m_curr_object.reset(); m_objects.clear(); m_objects_aliases.clear(); m_instances.clear(); m_geometries.clear(); m_curr_config.object_id = -1; m_curr_config.volume_id = -1; m_objects_metadata.clear(); m_layer_heights_profiles.clear(); m_layer_config_ranges.clear(); m_sla_support_points.clear(); m_curr_metadata_name.clear(); m_curr_characters.clear(); clear_errors(); return _load_model_from_file(filename, model, config); } void _3MF_Importer::_destroy_xml_parser() { if (m_xml_parser != nullptr) { XML_ParserFree(m_xml_parser); m_xml_parser = nullptr; } } void _3MF_Importer::_stop_xml_parser() { if (m_xml_parser != nullptr) XML_StopParser(m_xml_parser, false); } bool _3MF_Importer::_load_model_from_file(const std::string& filename, Model& model, DynamicPrintConfig& config) { mz_zip_archive archive; mz_zip_zero_struct(&archive); if (!open_zip_reader(&archive, filename)) { add_error("Unable to open the file"); return false; } mz_uint num_entries = mz_zip_reader_get_num_files(&archive); mz_zip_archive_file_stat stat; m_name = boost::filesystem::path(filename).filename().stem().string(); // we first loop the entries to read from the archive the .model file only, in order to extract the version from it for (mz_uint i = 0; i < num_entries; ++i) { if (mz_zip_reader_file_stat(&archive, i, &stat)) { std::string name(stat.m_filename); std::replace(name.begin(), name.end(), '\\', '/'); if (boost::algorithm::istarts_with(name, MODEL_FOLDER) && boost::algorithm::iends_with(name, MODEL_EXTENSION)) { // valid model name -> extract model if (!_extract_model_from_archive(archive, stat)) { close_zip_reader(&archive); add_error("Archive does not contain a valid model"); return false; } } } } // we then loop again the entries to read other files stored in the archive for (mz_uint i = 0; i < num_entries; ++i) { if (mz_zip_reader_file_stat(&archive, i, &stat)) { std::string name(stat.m_filename); std::replace(name.begin(), name.end(), '\\', '/'); if (boost::algorithm::iequals(name, LAYER_HEIGHTS_PROFILE_FILE)) { // extract slic3r layer heights profile file _extract_layer_heights_profile_config_from_archive(archive, stat); } if (boost::algorithm::iequals(name, LAYER_CONFIG_RANGES_FILE)) { // extract slic3r layer config ranges file _extract_layer_config_ranges_from_archive(archive, stat); } else if (boost::algorithm::iequals(name, SLA_SUPPORT_POINTS_FILE)) { // extract sla support points file _extract_sla_support_points_from_archive(archive, stat); } else if (boost::algorithm::iequals(name, PRINT_CONFIG_FILE)) { // extract slic3r print config file _extract_print_config_from_archive(archive, stat, config, filename); } else if (boost::algorithm::iequals(name, MODEL_CONFIG_FILE)) { // extract slic3r model config file if (!_extract_model_config_from_archive(archive, stat, model)) { close_zip_reader(&archive); add_error("Archive does not contain a valid model config"); return false; } } } } close_zip_reader(&archive); for (const IdToModelObjectMap::value_type& object : m_objects) { ModelObject *model_object = m_model->objects[object.second]; ObjectMetadata::VolumeMetadataList volumes; ObjectMetadata::VolumeMetadataList* volumes_ptr = nullptr; IdToGeometryMap::const_iterator obj_geometry = m_geometries.find(object.first); if (obj_geometry == m_geometries.end()) { add_error("Unable to find object geometry"); return false; } // m_layer_heights_profiles are indexed by a 1 based model object index. IdToLayerHeightsProfileMap::iterator obj_layer_heights_profile = m_layer_heights_profiles.find(object.second + 1); if (obj_layer_heights_profile != m_layer_heights_profiles.end()) model_object->layer_height_profile = obj_layer_heights_profile->second; // m_layer_config_ranges are indexed by a 1 based model object index. IdToLayerConfigRangesMap::iterator obj_layer_config_ranges = m_layer_config_ranges.find(object.second + 1); if (obj_layer_config_ranges != m_layer_config_ranges.end()) model_object->layer_config_ranges = obj_layer_config_ranges->second; // m_sla_support_points are indexed by a 1 based model object index. IdToSlaSupportPointsMap::iterator obj_sla_support_points = m_sla_support_points.find(object.second + 1); if (obj_sla_support_points != m_sla_support_points.end() && !obj_sla_support_points->second.empty()) { model_object->sla_support_points = obj_sla_support_points->second; model_object->sla_points_status = sla::PointsStatus::UserModified; } IdToMetadataMap::iterator obj_metadata = m_objects_metadata.find(object.first); if (obj_metadata != m_objects_metadata.end()) { // config data has been found, this model was saved using slic3r pe // apply object's name and config data for (const Metadata& metadata : obj_metadata->second.metadata) { if (metadata.key == "name") model_object->name = metadata.value; else model_object->config.set_deserialize(metadata.key, metadata.value); } // select object's detected volumes volumes_ptr = &obj_metadata->second.volumes; } else { // config data not found, this model was not saved using slic3r pe // add the entire geometry as the single volume to generate volumes.emplace_back(0, (int)obj_geometry->second.triangles.size() / 3 - 1); // select as volumes volumes_ptr = &volumes; } if (!_generate_volumes(*model_object, obj_geometry->second, *volumes_ptr)) return false; } // fixes the min z of the model if negative model.adjust_min_z(); return true; } bool _3MF_Importer::_extract_model_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat) { if (stat.m_uncomp_size == 0) { add_error("Found invalid size"); return false; } _destroy_xml_parser(); m_xml_parser = XML_ParserCreate(nullptr); if (m_xml_parser == nullptr) { add_error("Unable to create parser"); return false; } XML_SetUserData(m_xml_parser, (void*)this); XML_SetElementHandler(m_xml_parser, _3MF_Importer::_handle_start_model_xml_element, _3MF_Importer::_handle_end_model_xml_element); XML_SetCharacterDataHandler(m_xml_parser, _3MF_Importer::_handle_model_xml_characters); void* parser_buffer = XML_GetBuffer(m_xml_parser, (int)stat.m_uncomp_size); if (parser_buffer == nullptr) { add_error("Unable to create buffer"); return false; } mz_bool res = mz_zip_reader_extract_file_to_mem(&archive, stat.m_filename, parser_buffer, (size_t)stat.m_uncomp_size, 0); if (res == 0) { add_error("Error while reading model data to buffer"); return false; } if (!XML_ParseBuffer(m_xml_parser, (int)stat.m_uncomp_size, 1)) { char error_buf[1024]; ::sprintf(error_buf, "Error (%s) while parsing xml file at line %d", XML_ErrorString(XML_GetErrorCode(m_xml_parser)), XML_GetCurrentLineNumber(m_xml_parser)); add_error(error_buf); return false; } return true; } void _3MF_Importer::_extract_print_config_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat, DynamicPrintConfig& config, const std::string& archive_filename) { if (stat.m_uncomp_size > 0) { std::string buffer((size_t)stat.m_uncomp_size, 0); mz_bool res = mz_zip_reader_extract_file_to_mem(&archive, stat.m_filename, (void*)buffer.data(), (size_t)stat.m_uncomp_size, 0); if (res == 0) { add_error("Error while reading config data to buffer"); return; } config.load_from_gcode_string(buffer.data()); } } void _3MF_Importer::_extract_layer_heights_profile_config_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat) { if (stat.m_uncomp_size > 0) { std::string buffer((size_t)stat.m_uncomp_size, 0); mz_bool res = mz_zip_reader_extract_file_to_mem(&archive, stat.m_filename, (void*)buffer.data(), (size_t)stat.m_uncomp_size, 0); if (res == 0) { add_error("Error while reading layer heights profile data to buffer"); return; } if (buffer.back() == '\n') buffer.pop_back(); std::vector objects; boost::split(objects, buffer, boost::is_any_of("\n"), boost::token_compress_off); for (const std::string& object : objects) { std::vector object_data; boost::split(object_data, object, boost::is_any_of("|"), boost::token_compress_off); if (object_data.size() != 2) { add_error("Error while reading object data"); continue; } std::vector object_data_id; boost::split(object_data_id, object_data[0], boost::is_any_of("="), boost::token_compress_off); if (object_data_id.size() != 2) { add_error("Error while reading object id"); continue; } int object_id = std::atoi(object_data_id[1].c_str()); if (object_id == 0) { add_error("Found invalid object id"); continue; } IdToLayerHeightsProfileMap::iterator object_item = m_layer_heights_profiles.find(object_id); if (object_item != m_layer_heights_profiles.end()) { add_error("Found duplicated layer heights profile"); continue; } std::vector object_data_profile; boost::split(object_data_profile, object_data[1], boost::is_any_of(";"), boost::token_compress_off); if ((object_data_profile.size() <= 4) || (object_data_profile.size() % 2 != 0)) { add_error("Found invalid layer heights profile"); continue; } std::vector profile; profile.reserve(object_data_profile.size()); for (const std::string& value : object_data_profile) { profile.push_back((coordf_t)std::atof(value.c_str())); } m_layer_heights_profiles.insert(IdToLayerHeightsProfileMap::value_type(object_id, profile)); } } } void _3MF_Importer::_extract_layer_config_ranges_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat) { if (stat.m_uncomp_size > 0) { std::string buffer((size_t)stat.m_uncomp_size, 0); mz_bool res = mz_zip_reader_extract_file_to_mem(&archive, stat.m_filename, (void*)buffer.data(), (size_t)stat.m_uncomp_size, 0); if (res == 0) { add_error("Error while reading layer config ranges data to buffer"); return; } std::istringstream iss(buffer); // wrap returned xml to istringstream pt::ptree objects_tree; pt::read_xml(iss, objects_tree); for (const auto& object : objects_tree.get_child("objects")) { pt::ptree object_tree = object.second; int obj_idx = object_tree.get(".id", -1); if (obj_idx <= 0) { add_error("Found invalid object id"); continue; } IdToLayerConfigRangesMap::iterator object_item = m_layer_config_ranges.find(obj_idx); if (object_item != m_layer_config_ranges.end()) { add_error("Found duplicated layer config range"); continue; } t_layer_config_ranges config_ranges; for (const auto& range : object_tree.get_child("ranges")) { pt::ptree range_tree = range.second; double min_z = range_tree.get(".min_z"); double max_z = range_tree.get(".max_z"); // get Z range information DynamicPrintConfig& config = config_ranges[{ min_z, max_z }]; for (const auto& option : range_tree.get_child("config")) { std::string opt_key = option.second.get(".opt_key"); std::string value = option.second.data(); config.set_deserialize(opt_key, value); } } if (!config_ranges.empty()) m_layer_config_ranges.insert(IdToLayerConfigRangesMap::value_type(obj_idx, config_ranges)); } } } void _3MF_Importer::_extract_sla_support_points_from_archive(mz_zip_archive& archive, const mz_zip_archive_file_stat& stat) { if (stat.m_uncomp_size > 0) { std::string buffer((size_t)stat.m_uncomp_size, 0); mz_bool res = mz_zip_reader_extract_file_to_mem(&archive, stat.m_filename, (void*)buffer.data(), (size_t)stat.m_uncomp_size, 0); if (res == 0) { add_error("Error while reading sla support points data to buffer"); return; } if (buffer.back() == '\n') buffer.pop_back(); std::vector objects; boost::split(objects, buffer, boost::is_any_of("\n"), boost::token_compress_off); // Info on format versioning - see 3mf.hpp int version = 0; if (!objects.empty() && objects[0].find("support_points_format_version=") != std::string::npos) { objects[0].erase(objects[0].begin(), objects[0].begin() + 30); // removes the string version = std::stoi(objects[0]); objects.erase(objects.begin()); // pop the header } for (const std::string& object : objects) { std::vector object_data; boost::split(object_data, object, boost::is_any_of("|"), boost::token_compress_off); if (object_data.size() != 2) { add_error("Error while reading object data"); continue; } std::vector object_data_id; boost::split(object_data_id, object_data[0], boost::is_any_of("="), boost::token_compress_off); if (object_data_id.size() != 2) { add_error("Error while reading object id"); continue; } int object_id = std::atoi(object_data_id[1].c_str()); if (object_id == 0) { add_error("Found invalid object id"); continue; } IdToSlaSupportPointsMap::iterator object_item = m_sla_support_points.find(object_id); if (object_item != m_sla_support_points.end()) { add_error("Found duplicated SLA support points"); continue; } std::vector object_data_points; boost::split(object_data_points, object_data[1], boost::is_any_of(" "), boost::token_compress_off); std::vector sla_support_points; if (version == 0) { for (unsigned int i=0; iobjects[object.second]; if ((model_object != nullptr) && (model_object->instances.size() == 0)) m_model->delete_object(model_object); } // applies instances' matrices for (Instance& instance : m_instances) { if (instance.instance != nullptr) { ModelObject* object = instance.instance->get_object(); if (object != nullptr) { // apply the transform to the instance _apply_transform(*instance.instance, instance.transform); } } } return true; } bool _3MF_Importer::_handle_start_resources(const char** attributes, unsigned int num_attributes) { // do nothing return true; } bool _3MF_Importer::_handle_end_resources() { // do nothing return true; } bool _3MF_Importer::_handle_start_object(const char** attributes, unsigned int num_attributes) { // reset current data m_curr_object.reset(); if (is_valid_object_type(get_attribute_value_string(attributes, num_attributes, TYPE_ATTR))) { // create new object (it may be removed later if no instances are generated from it) m_curr_object.model_object_idx = (int)m_model->objects.size(); m_curr_object.object = m_model->add_object(); if (m_curr_object.object == nullptr) { add_error("Unable to create object"); return false; } // set object data m_curr_object.object->name = get_attribute_value_string(attributes, num_attributes, NAME_ATTR); if (m_curr_object.object->name.empty()) m_curr_object.object->name = m_name + "_" + std::to_string(m_model->objects.size()); m_curr_object.id = get_attribute_value_int(attributes, num_attributes, ID_ATTR); } return true; } bool _3MF_Importer::_handle_end_object() { if (m_curr_object.object != nullptr) { if (m_curr_object.geometry.empty()) { // no geometry defined // remove the object from the model m_model->delete_object(m_curr_object.object); if (m_curr_object.components.empty()) { // no components defined -> invalid object, delete it IdToModelObjectMap::iterator object_item = m_objects.find(m_curr_object.id); if (object_item != m_objects.end()) m_objects.erase(object_item); IdToAliasesMap::iterator alias_item = m_objects_aliases.find(m_curr_object.id); if (alias_item != m_objects_aliases.end()) m_objects_aliases.erase(alias_item); } else // adds components to aliases m_objects_aliases.insert(IdToAliasesMap::value_type(m_curr_object.id, m_curr_object.components)); } else { // geometry defined, store it for later use m_geometries.insert(IdToGeometryMap::value_type(m_curr_object.id, std::move(m_curr_object.geometry))); // stores the object for later use if (m_objects.find(m_curr_object.id) == m_objects.end()) { m_objects.insert(IdToModelObjectMap::value_type(m_curr_object.id, m_curr_object.model_object_idx)); m_objects_aliases.insert(IdToAliasesMap::value_type(m_curr_object.id, ComponentsList(1, Component(m_curr_object.id)))); // aliases itself } else { add_error("Found object with duplicate id"); return false; } } } return true; } bool _3MF_Importer::_handle_start_mesh(const char** attributes, unsigned int num_attributes) { // reset current geometry m_curr_object.geometry.reset(); return true; } bool _3MF_Importer::_handle_end_mesh() { // do nothing return true; } bool _3MF_Importer::_handle_start_vertices(const char** attributes, unsigned int num_attributes) { // reset current vertices m_curr_object.geometry.vertices.clear(); return true; } bool _3MF_Importer::_handle_end_vertices() { // do nothing return true; } bool _3MF_Importer::_handle_start_vertex(const char** attributes, unsigned int num_attributes) { // appends the vertex coordinates // missing values are set equal to ZERO m_curr_object.geometry.vertices.push_back(m_unit_factor * get_attribute_value_float(attributes, num_attributes, X_ATTR)); m_curr_object.geometry.vertices.push_back(m_unit_factor * get_attribute_value_float(attributes, num_attributes, Y_ATTR)); m_curr_object.geometry.vertices.push_back(m_unit_factor * get_attribute_value_float(attributes, num_attributes, Z_ATTR)); return true; } bool _3MF_Importer::_handle_end_vertex() { // do nothing return true; } bool _3MF_Importer::_handle_start_triangles(const char** attributes, unsigned int num_attributes) { // reset current triangles m_curr_object.geometry.triangles.clear(); return true; } bool _3MF_Importer::_handle_end_triangles() { // do nothing return true; } bool _3MF_Importer::_handle_start_triangle(const char** attributes, unsigned int num_attributes) { // we are ignoring the following attributes: // p1 // p2 // p3 // pid // see specifications // appends the triangle's vertices indices // missing values are set equal to ZERO m_curr_object.geometry.triangles.push_back((unsigned int)get_attribute_value_int(attributes, num_attributes, V1_ATTR)); m_curr_object.geometry.triangles.push_back((unsigned int)get_attribute_value_int(attributes, num_attributes, V2_ATTR)); m_curr_object.geometry.triangles.push_back((unsigned int)get_attribute_value_int(attributes, num_attributes, V3_ATTR)); return true; } bool _3MF_Importer::_handle_end_triangle() { // do nothing return true; } bool _3MF_Importer::_handle_start_components(const char** attributes, unsigned int num_attributes) { // reset current components m_curr_object.components.clear(); return true; } bool _3MF_Importer::_handle_end_components() { // do nothing return true; } bool _3MF_Importer::_handle_start_component(const char** attributes, unsigned int num_attributes) { int object_id = get_attribute_value_int(attributes, num_attributes, OBJECTID_ATTR); Transform3d transform = get_transform_from_string(get_attribute_value_string(attributes, num_attributes, TRANSFORM_ATTR)); IdToModelObjectMap::iterator object_item = m_objects.find(object_id); if (object_item == m_objects.end()) { IdToAliasesMap::iterator alias_item = m_objects_aliases.find(object_id); if (alias_item == m_objects_aliases.end()) { add_error("Found component with invalid object id"); return false; } } m_curr_object.components.emplace_back(object_id, transform); return true; } bool _3MF_Importer::_handle_end_component() { // do nothing return true; } bool _3MF_Importer::_handle_start_build(const char** attributes, unsigned int num_attributes) { // do nothing return true; } bool _3MF_Importer::_handle_end_build() { // do nothing return true; } bool _3MF_Importer::_handle_start_item(const char** attributes, unsigned int num_attributes) { // we are ignoring the following attributes // thumbnail // partnumber // pid // pindex // see specifications int object_id = get_attribute_value_int(attributes, num_attributes, OBJECTID_ATTR); Transform3d transform = get_transform_from_string(get_attribute_value_string(attributes, num_attributes, TRANSFORM_ATTR)); return _create_object_instance(object_id, transform, 1); } bool _3MF_Importer::_handle_end_item() { // do nothing return true; } bool _3MF_Importer::_handle_start_metadata(const char** attributes, unsigned int num_attributes) { m_curr_characters.clear(); std::string name = get_attribute_value_string(attributes, num_attributes, NAME_ATTR); if (!name.empty()) m_curr_metadata_name = name; return true; } bool _3MF_Importer::_handle_end_metadata() { if (m_curr_metadata_name == SLIC3RPE_3MF_VERSION) m_version = (unsigned int)atoi(m_curr_characters.c_str()); return true; } bool _3MF_Importer::_create_object_instance(int object_id, const Transform3d& transform, unsigned int recur_counter) { static const unsigned int MAX_RECURSIONS = 10; // escape from circular aliasing if (recur_counter > MAX_RECURSIONS) { add_error("Too many recursions"); return false; } IdToAliasesMap::iterator it = m_objects_aliases.find(object_id); if (it == m_objects_aliases.end()) { add_error("Found item with invalid object id"); return false; } if ((it->second.size() == 1) && (it->second[0].object_id == object_id)) { // aliasing to itself IdToModelObjectMap::iterator object_item = m_objects.find(object_id); if ((object_item == m_objects.end()) || (object_item->second == -1)) { add_error("Found invalid object"); return false; } else { ModelInstance* instance = m_model->objects[object_item->second]->add_instance(); if (instance == nullptr) { add_error("Unable to add object instance"); return false; } m_instances.emplace_back(instance, transform); } } else { // recursively process nested components for (const Component& component : it->second) { if (!_create_object_instance(component.object_id, transform * component.transform, recur_counter + 1)) return false; } } return true; } void _3MF_Importer::_apply_transform(ModelInstance& instance, const Transform3d& transform) { Slic3r::Geometry::Transformation t(transform); // invalid scale value, return if (!t.get_scaling_factor().all()) return; instance.set_transformation(t); } bool _3MF_Importer::_handle_start_config(const char** attributes, unsigned int num_attributes) { // do nothing return true; } bool _3MF_Importer::_handle_end_config() { // do nothing return true; } bool _3MF_Importer::_handle_start_config_object(const char** attributes, unsigned int num_attributes) { int object_id = get_attribute_value_int(attributes, num_attributes, ID_ATTR); IdToMetadataMap::iterator object_item = m_objects_metadata.find(object_id); if (object_item != m_objects_metadata.end()) { add_error("Found duplicated object id"); return false; } m_objects_metadata.insert(IdToMetadataMap::value_type(object_id, ObjectMetadata())); m_curr_config.object_id = object_id; return true; } bool _3MF_Importer::_handle_end_config_object() { // do nothing return true; } bool _3MF_Importer::_handle_start_config_volume(const char** attributes, unsigned int num_attributes) { IdToMetadataMap::iterator object = m_objects_metadata.find(m_curr_config.object_id); if (object == m_objects_metadata.end()) { add_error("Cannot assign volume to a valid object"); return false; } m_curr_config.volume_id = (int)object->second.volumes.size(); unsigned int first_triangle_id = (unsigned int)get_attribute_value_int(attributes, num_attributes, FIRST_TRIANGLE_ID_ATTR); unsigned int last_triangle_id = (unsigned int)get_attribute_value_int(attributes, num_attributes, LAST_TRIANGLE_ID_ATTR); object->second.volumes.emplace_back(first_triangle_id, last_triangle_id); return true; } bool _3MF_Importer::_handle_end_config_volume() { // do nothing return true; } bool _3MF_Importer::_handle_start_config_metadata(const char** attributes, unsigned int num_attributes) { IdToMetadataMap::iterator object = m_objects_metadata.find(m_curr_config.object_id); if (object == m_objects_metadata.end()) { add_error("Cannot assign metadata to valid object id"); return false; } std::string type = get_attribute_value_string(attributes, num_attributes, TYPE_ATTR); std::string key = get_attribute_value_string(attributes, num_attributes, KEY_ATTR); std::string value = get_attribute_value_string(attributes, num_attributes, VALUE_ATTR); if (type == OBJECT_TYPE) object->second.metadata.emplace_back(key, value); else if (type == VOLUME_TYPE) { if (m_curr_config.volume_id < object->second.volumes.size()) object->second.volumes[m_curr_config.volume_id].metadata.emplace_back(key, value); } else { add_error("Found invalid metadata type"); return false; } return true; } bool _3MF_Importer::_handle_end_config_metadata() { // do nothing return true; } bool _3MF_Importer::_generate_volumes(ModelObject& object, const Geometry& geometry, const ObjectMetadata::VolumeMetadataList& volumes) { if (!object.volumes.empty()) { add_error("Found invalid volumes count"); return false; } unsigned int geo_tri_count = (unsigned int)geometry.triangles.size() / 3; for (const ObjectMetadata::VolumeMetadata& volume_data : volumes) { if ((geo_tri_count <= volume_data.first_triangle_id) || (geo_tri_count <= volume_data.last_triangle_id) || (volume_data.last_triangle_id < volume_data.first_triangle_id)) { add_error("Found invalid triangle id"); return false; } // splits volume out of imported geometry TriangleMesh triangle_mesh; stl_file &stl = triangle_mesh.stl; unsigned int triangles_count = volume_data.last_triangle_id - volume_data.first_triangle_id + 1; stl.stats.type = inmemory; stl.stats.number_of_facets = (uint32_t)triangles_count; stl.stats.original_num_facets = (int)stl.stats.number_of_facets; stl_allocate(&stl); unsigned int src_start_id = volume_data.first_triangle_id * 3; for (unsigned int i = 0; i < triangles_count; ++i) { unsigned int ii = i * 3; stl_facet& facet = stl.facet_start[i]; for (unsigned int v = 0; v < 3; ++v) { ::memcpy(facet.vertex[v].data(), (const void*)&geometry.vertices[geometry.triangles[src_start_id + ii + v] * 3], 3 * sizeof(float)); } } stl_get_size(&stl); triangle_mesh.repair(); ModelVolume* volume = object.add_volume(std::move(triangle_mesh)); volume->center_geometry_after_creation(); volume->calculate_convex_hull(); // apply volume's name and config data for (const Metadata& metadata : volume_data.metadata) { if (metadata.key == NAME_KEY) volume->name = metadata.value; else if ((metadata.key == MODIFIER_KEY) && (metadata.value == "1")) volume->set_type(ModelVolumeType::PARAMETER_MODIFIER); else if (metadata.key == VOLUME_TYPE_KEY) volume->set_type(ModelVolume::type_from_string(metadata.value)); else volume->config.set_deserialize(metadata.key, metadata.value); } } return true; } void XMLCALL _3MF_Importer::_handle_start_model_xml_element(void* userData, const char* name, const char** attributes) { _3MF_Importer* importer = (_3MF_Importer*)userData; if (importer != nullptr) importer->_handle_start_model_xml_element(name, attributes); } void XMLCALL _3MF_Importer::_handle_end_model_xml_element(void* userData, const char* name) { _3MF_Importer* importer = (_3MF_Importer*)userData; if (importer != nullptr) importer->_handle_end_model_xml_element(name); } void XMLCALL _3MF_Importer::_handle_model_xml_characters(void* userData, const XML_Char* s, int len) { _3MF_Importer* importer = (_3MF_Importer*)userData; if (importer != nullptr) importer->_handle_model_xml_characters(s, len); } void XMLCALL _3MF_Importer::_handle_start_config_xml_element(void* userData, const char* name, const char** attributes) { _3MF_Importer* importer = (_3MF_Importer*)userData; if (importer != nullptr) importer->_handle_start_config_xml_element(name, attributes); } void XMLCALL _3MF_Importer::_handle_end_config_xml_element(void* userData, const char* name) { _3MF_Importer* importer = (_3MF_Importer*)userData; if (importer != nullptr) importer->_handle_end_config_xml_element(name); } class _3MF_Exporter : public _3MF_Base { struct BuildItem { unsigned int id; Transform3d transform; BuildItem(unsigned int id, const Transform3d& transform) : id(id) , transform(transform) { } }; struct Offsets { unsigned int first_vertex_id; unsigned int first_triangle_id; unsigned int last_triangle_id; Offsets(unsigned int first_vertex_id) : first_vertex_id(first_vertex_id) , first_triangle_id(-1) , last_triangle_id(-1) { } }; typedef std::map VolumeToOffsetsMap; struct ObjectData { ModelObject* object; VolumeToOffsetsMap volumes_offsets; explicit ObjectData(ModelObject* object) : object(object) { } }; typedef std::vector BuildItemsList; typedef std::map IdToObjectDataMap; public: bool save_model_to_file(const std::string& filename, Model& model, const DynamicPrintConfig* config); private: bool _save_model_to_file(const std::string& filename, Model& model, const DynamicPrintConfig* config); bool _add_content_types_file_to_archive(mz_zip_archive& archive); bool _add_relationships_file_to_archive(mz_zip_archive& archive); bool _add_model_file_to_archive(mz_zip_archive& archive, const Model& model, IdToObjectDataMap &objects_data); bool _add_object_to_model_stream(std::stringstream& stream, unsigned int& object_id, ModelObject& object, BuildItemsList& build_items, VolumeToOffsetsMap& volumes_offsets); bool _add_mesh_to_object_stream(std::stringstream& stream, ModelObject& object, VolumeToOffsetsMap& volumes_offsets); bool _add_build_to_model_stream(std::stringstream& stream, const BuildItemsList& build_items); bool _add_layer_height_profile_file_to_archive(mz_zip_archive& archive, Model& model); bool _add_layer_config_ranges_file_to_archive(mz_zip_archive& archive, Model& model); bool _add_sla_support_points_file_to_archive(mz_zip_archive& archive, Model& model); bool _add_print_config_file_to_archive(mz_zip_archive& archive, const DynamicPrintConfig &config); bool _add_model_config_file_to_archive(mz_zip_archive& archive, const Model& model, const IdToObjectDataMap &objects_data); }; bool _3MF_Exporter::save_model_to_file(const std::string& filename, Model& model, const DynamicPrintConfig* config) { clear_errors(); return _save_model_to_file(filename, model, config); } bool _3MF_Exporter::_save_model_to_file(const std::string& filename, Model& model, const DynamicPrintConfig* config) { mz_zip_archive archive; mz_zip_zero_struct(&archive); if (!open_zip_writer(&archive, filename)) { add_error("Unable to open the file"); return false; } // Adds content types file ("[Content_Types].xml";). // The content of this file is the same for each PrusaSlicer 3mf. if (!_add_content_types_file_to_archive(archive)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } // Adds relationships file ("_rels/.rels"). // The content of this file is the same for each PrusaSlicer 3mf. // The relationshis file contains a reference to the geometry file "3D/3dmodel.model", the name was chosen to be compatible with CURA. if (!_add_relationships_file_to_archive(archive)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } // Adds model file ("3D/3dmodel.model"). // This is the one and only file that contains all the geometry (vertices and triangles) of all ModelVolumes. IdToObjectDataMap objects_data; if (!_add_model_file_to_archive(archive, model, objects_data)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } // Adds layer height profile file ("Metadata/Slic3r_PE_layer_heights_profile.txt"). // All layer height profiles of all ModelObjects are stored here, indexed by 1 based index of the ModelObject in Model. // The index differes from the index of an object ID of an object instance of a 3MF file! if (!_add_layer_height_profile_file_to_archive(archive, model)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } // Adds layer config ranges file ("Metadata/Slic3r_PE_layer_config_ranges.txt"). // All layer height profiles of all ModelObjects are stored here, indexed by 1 based index of the ModelObject in Model. // The index differes from the index of an object ID of an object instance of a 3MF file! if (!_add_layer_config_ranges_file_to_archive(archive, model)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } // Adds sla support points file ("Metadata/Slic3r_PE_sla_support_points.txt"). // All sla support points of all ModelObjects are stored here, indexed by 1 based index of the ModelObject in Model. // The index differes from the index of an object ID of an object instance of a 3MF file! if (!_add_sla_support_points_file_to_archive(archive, model)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } // Adds slic3r print config file ("Metadata/Slic3r_PE.config"). // This file contains the content of FullPrintConfing / SLAFullPrintConfig. if (config != nullptr) { if (!_add_print_config_file_to_archive(archive, *config)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } } // Adds slic3r model config file ("Metadata/Slic3r_PE_model.config"). // This file contains all the attributes of all ModelObjects and their ModelVolumes (names, parameter overrides). // As there is just a single Indexed Triangle Set data stored per ModelObject, offsets of volumes into their respective Indexed Triangle Set data // is stored here as well. if (!_add_model_config_file_to_archive(archive, model, objects_data)) { close_zip_writer(&archive); boost::filesystem::remove(filename); return false; } if (!mz_zip_writer_finalize_archive(&archive)) { close_zip_writer(&archive); boost::filesystem::remove(filename); add_error("Unable to finalize the archive"); return false; } close_zip_writer(&archive); return true; } bool _3MF_Exporter::_add_content_types_file_to_archive(mz_zip_archive& archive) { std::stringstream stream; stream << "\n"; stream << "\n"; stream << " \n"; stream << " \n"; stream << ""; std::string out = stream.str(); if (!mz_zip_writer_add_mem(&archive, CONTENT_TYPES_FILE.c_str(), (const void*)out.data(), out.length(), MZ_DEFAULT_COMPRESSION)) { add_error("Unable to add content types file to archive"); return false; } return true; } bool _3MF_Exporter::_add_relationships_file_to_archive(mz_zip_archive& archive) { std::stringstream stream; stream << "\n"; stream << "\n"; stream << " \n"; stream << ""; std::string out = stream.str(); if (!mz_zip_writer_add_mem(&archive, RELATIONSHIPS_FILE.c_str(), (const void*)out.data(), out.length(), MZ_DEFAULT_COMPRESSION)) { add_error("Unable to add relationships file to archive"); return false; } return true; } bool _3MF_Exporter::_add_model_file_to_archive(mz_zip_archive& archive, const Model& model, IdToObjectDataMap &objects_data) { std::stringstream stream; // https://en.cppreference.com/w/cpp/types/numeric_limits/max_digits10 // Conversion of a floating-point value to text and back is exact as long as at least max_digits10 were used (9 for float, 17 for double). // It is guaranteed to produce the same floating-point value, even though the intermediate text representation is not exact. // The default value of std::stream precision is 6 digits only! stream << std::setprecision(std::numeric_limits::max_digits10); stream << "\n"; stream << "<" << MODEL_TAG << " unit=\"millimeter\" xml:lang=\"en-US\" xmlns=\"http://schemas.microsoft.com/3dmanufacturing/core/2015/02\" xmlns:slic3rpe=\"http://schemas.slic3r.org/3mf/2017/06\">\n"; stream << " <" << METADATA_TAG << " name=\"" << SLIC3RPE_3MF_VERSION << "\">" << VERSION_3MF << "\n"; stream << " <" << RESOURCES_TAG << ">\n"; // Instance transformations, indexed by the 3MF object ID (which is a linear serialization of all instances of all ModelObjects). BuildItemsList build_items; // The object_id here is a one based identifier of the first instance of a ModelObject in the 3MF file, where // all the object instances of all ModelObjects are stored and indexed in a 1 based linear fashion. // Therefore the list of object_ids here may not be continuous. unsigned int object_id = 1; for (ModelObject* obj : model.objects) { if (obj == nullptr) continue; // Index of an object in the 3MF file corresponding to the 1st instance of a ModelObject. unsigned int curr_id = object_id; IdToObjectDataMap::iterator object_it = objects_data.insert(IdToObjectDataMap::value_type(curr_id, ObjectData(obj))).first; // Store geometry of all ModelVolumes contained in a single ModelObject into a single 3MF indexed triangle set object. // object_it->second.volumes_offsets will contain the offsets of the ModelVolumes in that single indexed triangle set. // object_id will be increased to point to the 1st instance of the next ModelObject. if (!_add_object_to_model_stream(stream, object_id, *obj, build_items, object_it->second.volumes_offsets)) { add_error("Unable to add object to archive"); return false; } } stream << " \n"; // Store the transformations of all the ModelInstances of all ModelObjects, indexed in a linear fashion. if (!_add_build_to_model_stream(stream, build_items)) { add_error("Unable to add build to archive"); return false; } stream << "\n"; std::string out = stream.str(); if (!mz_zip_writer_add_mem(&archive, MODEL_FILE.c_str(), (const void*)out.data(), out.length(), MZ_DEFAULT_COMPRESSION)) { add_error("Unable to add model file to archive"); return false; } return true; } bool _3MF_Exporter::_add_object_to_model_stream(std::stringstream& stream, unsigned int& object_id, ModelObject& object, BuildItemsList& build_items, VolumeToOffsetsMap& volumes_offsets) { unsigned int id = 0; for (const ModelInstance* instance : object.instances) { assert(instance != nullptr); if (instance == nullptr) continue; unsigned int instance_id = object_id + id; stream << " <" << OBJECT_TAG << " id=\"" << instance_id << "\" type=\"model\">\n"; if (id == 0) { if (!_add_mesh_to_object_stream(stream, object, volumes_offsets)) { add_error("Unable to add mesh to archive"); return false; } } else { stream << " <" << COMPONENTS_TAG << ">\n"; stream << " <" << COMPONENT_TAG << " objectid=\"" << object_id << "\" />\n"; stream << " \n"; } Transform3d t = instance->get_matrix(); // instance_id is just a 1 indexed index in build_items. assert(instance_id == build_items.size() + 1); build_items.emplace_back(instance_id, t); stream << " \n"; ++id; } object_id += id; return true; } bool _3MF_Exporter::_add_mesh_to_object_stream(std::stringstream& stream, ModelObject& object, VolumeToOffsetsMap& volumes_offsets) { stream << " <" << MESH_TAG << ">\n"; stream << " <" << VERTICES_TAG << ">\n"; unsigned int vertices_count = 0; for (ModelVolume* volume : object.volumes) { if (volume == nullptr) continue; if (!volume->mesh().repaired) throw std::runtime_error("store_3mf() requires repair()"); if (!volume->mesh().has_shared_vertices()) throw std::runtime_error("store_3mf() requires shared vertices"); volumes_offsets.insert(VolumeToOffsetsMap::value_type(volume, Offsets(vertices_count))).first; const indexed_triangle_set &its = volume->mesh().its; if (its.vertices.empty()) { add_error("Found invalid mesh"); return false; } vertices_count += (int)its.vertices.size(); const Transform3d& matrix = volume->get_matrix(); for (size_t i = 0; i < its.vertices.size(); ++i) { stream << " <" << VERTEX_TAG << " "; Vec3f v = (matrix * its.vertices[i].cast()).cast(); stream << "x=\"" << v(0) << "\" "; stream << "y=\"" << v(1) << "\" "; stream << "z=\"" << v(2) << "\" />\n"; } } stream << " \n"; stream << " <" << TRIANGLES_TAG << ">\n"; unsigned int triangles_count = 0; for (ModelVolume* volume : object.volumes) { if (volume == nullptr) continue; VolumeToOffsetsMap::iterator volume_it = volumes_offsets.find(volume); assert(volume_it != volumes_offsets.end()); const indexed_triangle_set &its = volume->mesh().its; // updates triangle offsets volume_it->second.first_triangle_id = triangles_count; triangles_count += (int)its.indices.size(); volume_it->second.last_triangle_id = triangles_count - 1; for (size_t i = 0; i < its.indices.size(); ++ i) { stream << " <" << TRIANGLE_TAG << " "; for (int j = 0; j < 3; ++j) { stream << "v" << j + 1 << "=\"" << its.indices[i][j] + volume_it->second.first_vertex_id << "\" "; } stream << "/>\n"; } } stream << " \n"; stream << " \n"; return true; } bool _3MF_Exporter::_add_build_to_model_stream(std::stringstream& stream, const BuildItemsList& build_items) { if (build_items.size() == 0) { add_error("No build item found"); return false; } stream << " <" << BUILD_TAG << ">\n"; for (const BuildItem& item : build_items) { stream << " <" << ITEM_TAG << " objectid=\"" << item.id << "\" transform =\""; for (unsigned c = 0; c < 4; ++c) { for (unsigned r = 0; r < 3; ++r) { stream << item.transform(r, c); if ((r != 2) || (c != 3)) stream << " "; } } stream << "\" />\n"; } stream << " \n"; return true; } bool _3MF_Exporter::_add_layer_height_profile_file_to_archive(mz_zip_archive& archive, Model& model) { std::string out = ""; char buffer[1024]; unsigned int count = 0; for (const ModelObject* object : model.objects) { ++count; const std::vector &layer_height_profile = object->layer_height_profile; if ((layer_height_profile.size() >= 4) && ((layer_height_profile.size() % 2) == 0)) { sprintf(buffer, "object_id=%d|", count); out += buffer; // Store the layer height profile as a single semicolon separated list. for (size_t i = 0; i < layer_height_profile.size(); ++i) { sprintf(buffer, (i == 0) ? "%f" : ";%f", layer_height_profile[i]); out += buffer; } out += "\n"; } } if (!out.empty()) { if (!mz_zip_writer_add_mem(&archive, LAYER_HEIGHTS_PROFILE_FILE.c_str(), (const void*)out.data(), out.length(), MZ_DEFAULT_COMPRESSION)) { add_error("Unable to add layer heights profile file to archive"); return false; } } return true; } bool _3MF_Exporter::_add_layer_config_ranges_file_to_archive(mz_zip_archive& archive, Model& model) { std::string out = ""; pt::ptree tree; unsigned int object_cnt = 0; for (const ModelObject* object : model.objects) { object_cnt++; const t_layer_config_ranges& ranges = object->layer_config_ranges; if (!ranges.empty()) { pt::ptree& obj_tree = tree.add("objects.object",""); obj_tree.put(".id", object_cnt); obj_tree.add("ranges", ""); // Store the layer config ranges. for (const auto& range : ranges) { pt::ptree& range_tree = obj_tree.add("ranges.range", ""); // store minX and maxZ range_tree.put(".min_z", range.first.first); range_tree.put(".max_z", range.first.second); range_tree.add("config",""); // store range configuration const DynamicPrintConfig& config = range.second; for (const std::string& opt_key : config.keys()) { pt::ptree& opt_tree = range_tree.add("config.option", config.serialize(opt_key)); opt_tree.put(".opt_key", opt_key); } } } } if (!tree.empty()) { std::ostringstream oss; boost::property_tree::write_xml(oss, tree); out = oss.str(); // Post processing of the output string for a better preview // JUST // boost::replace_all(out, "><", ">\n<"); // OR more "beautification" boost::replace_all(out, ">\n \n \n \n \n \n ", ">\n "); boost::replace_all(out, ">\n \n & sla_support_points = object->sla_support_points; if (!sla_support_points.empty()) { sprintf(buffer, "object_id=%d|", count); out += buffer; // Store the layer height profile as a single space separated list. for (size_t i = 0; i < sla_support_points.size(); ++i) { sprintf(buffer, (i==0 ? "%f %f %f %f %f" : " %f %f %f %f %f"), sla_support_points[i].pos(0), sla_support_points[i].pos(1), sla_support_points[i].pos(2), sla_support_points[i].head_front_radius, (float)sla_support_points[i].is_new_island); out += buffer; } out += "\n"; } } if (!out.empty()) { // Adds version header at the beginning: out = std::string("support_points_format_version=") + std::to_string(support_points_format_version) + std::string("\n") + out; if (!mz_zip_writer_add_mem(&archive, SLA_SUPPORT_POINTS_FILE.c_str(), (const void*)out.data(), out.length(), MZ_DEFAULT_COMPRESSION)) { add_error("Unable to add sla support points file to archive"); return false; } } return true; } bool _3MF_Exporter::_add_print_config_file_to_archive(mz_zip_archive& archive, const DynamicPrintConfig &config) { char buffer[1024]; sprintf(buffer, "; %s\n\n", header_slic3r_generated().c_str()); std::string out = buffer; for (const std::string &key : config.keys()) if (key != "compatible_printers") out += "; " + key + " = " + config.serialize(key) + "\n"; if (!out.empty()) { if (!mz_zip_writer_add_mem(&archive, PRINT_CONFIG_FILE.c_str(), (const void*)out.data(), out.length(), MZ_DEFAULT_COMPRESSION)) { add_error("Unable to add print config file to archive"); return false; } } return true; } bool _3MF_Exporter::_add_model_config_file_to_archive(mz_zip_archive& archive, const Model& model, const IdToObjectDataMap &objects_data) { std::stringstream stream; stream << "\n"; stream << "<" << CONFIG_TAG << ">\n"; for (const IdToObjectDataMap::value_type& obj_metadata : objects_data) { const ModelObject* obj = obj_metadata.second.object; if (obj != nullptr) { stream << " <" << OBJECT_TAG << " id=\"" << obj_metadata.first << "\">\n"; // stores object's name if (!obj->name.empty()) stream << " <" << METADATA_TAG << " " << TYPE_ATTR << "=\"" << OBJECT_TYPE << "\" " << KEY_ATTR << "=\"name\" " << VALUE_ATTR << "=\"" << xml_escape(obj->name) << "\"/>\n"; // stores object's config data for (const std::string& key : obj->config.keys()) { stream << " <" << METADATA_TAG << " " << TYPE_ATTR << "=\"" << OBJECT_TYPE << "\" " << KEY_ATTR << "=\"" << key << "\" " << VALUE_ATTR << "=\"" << obj->config.serialize(key) << "\"/>\n"; } for (const ModelVolume* volume : obj_metadata.second.object->volumes) { if (volume != nullptr) { const VolumeToOffsetsMap& offsets = obj_metadata.second.volumes_offsets; VolumeToOffsetsMap::const_iterator it = offsets.find(volume); if (it != offsets.end()) { // stores volume's offsets stream << " <" << VOLUME_TAG << " "; stream << FIRST_TRIANGLE_ID_ATTR << "=\"" << it->second.first_triangle_id << "\" "; stream << LAST_TRIANGLE_ID_ATTR << "=\"" << it->second.last_triangle_id << "\">\n"; // stores volume's name if (!volume->name.empty()) stream << " <" << METADATA_TAG << " " << TYPE_ATTR << "=\"" << VOLUME_TYPE << "\" " << KEY_ATTR << "=\"" << NAME_KEY << "\" " << VALUE_ATTR << "=\"" << xml_escape(volume->name) << "\"/>\n"; // stores volume's modifier field (legacy, to support old slicers) if (volume->is_modifier()) stream << " <" << METADATA_TAG << " " << TYPE_ATTR << "=\"" << VOLUME_TYPE << "\" " << KEY_ATTR << "=\"" << MODIFIER_KEY << "\" " << VALUE_ATTR << "=\"1\"/>\n"; // stores volume's type (overrides the modifier field above) stream << " <" << METADATA_TAG << " " << TYPE_ATTR << "=\"" << VOLUME_TYPE << "\" " << KEY_ATTR << "=\"" << VOLUME_TYPE_KEY << "\" " << VALUE_ATTR << "=\"" << ModelVolume::type_to_string(volume->type()) << "\"/>\n"; // stores volume's config data for (const std::string& key : volume->config.keys()) { stream << " <" << METADATA_TAG << " " << TYPE_ATTR << "=\"" << VOLUME_TYPE << "\" " << KEY_ATTR << "=\"" << key << "\" " << VALUE_ATTR << "=\"" << volume->config.serialize(key) << "\"/>\n"; } stream << " \n"; } } } stream << " \n"; } } stream << "\n"; std::string out = stream.str(); if (!mz_zip_writer_add_mem(&archive, MODEL_CONFIG_FILE.c_str(), (const void*)out.data(), out.length(), MZ_DEFAULT_COMPRESSION)) { add_error("Unable to add model config file to archive"); return false; } return true; } bool load_3mf(const char* path, DynamicPrintConfig* config, Model* model) { if ((path == nullptr) || (config == nullptr) || (model == nullptr)) return false; _3MF_Importer importer; bool res = importer.load_model_from_file(path, *model, *config); importer.log_errors(); return res; } bool store_3mf(const char* path, Model* model, const DynamicPrintConfig* config) { if ((path == nullptr) || (model == nullptr)) return false; _3MF_Exporter exporter; bool res = exporter.save_model_to_file(path, *model, config); if (!res) exporter.log_errors(); return res; } } // namespace Slic3r