#ifdef SLIC3RXS #include namespace Slic3r { REGISTER_CLASS(ExPolygon, "ExPolygon"); REGISTER_CLASS(ExPolygonCollection, "ExPolygon::Collection"); REGISTER_CLASS(Extruder, "Extruder"); REGISTER_CLASS(ExtrusionPath, "ExtrusionPath"); REGISTER_CLASS(ExtrusionLoop, "ExtrusionLoop"); // there is no ExtrusionLoop::Collection or ExtrusionEntity::Collection REGISTER_CLASS(ExtrusionEntityCollection, "ExtrusionPath::Collection"); REGISTER_CLASS(Flow, "Flow"); REGISTER_CLASS(AvoidCrossingPerimeters, "GCode::AvoidCrossingPerimeters"); REGISTER_CLASS(OozePrevention, "GCode::OozePrevention"); REGISTER_CLASS(Wipe, "GCode::Wipe"); REGISTER_CLASS(GCode, "GCode"); REGISTER_CLASS(GCodeSender, "GCode::Sender"); REGISTER_CLASS(GCodeWriter, "GCode::Writer"); REGISTER_CLASS(Layer, "Layer"); REGISTER_CLASS(SupportLayer, "Layer::Support"); REGISTER_CLASS(LayerRegion, "Layer::Region"); REGISTER_CLASS(Line, "Line"); REGISTER_CLASS(Linef3, "Linef3"); REGISTER_CLASS(PerimeterGenerator, "Layer::PerimeterGenerator"); REGISTER_CLASS(PlaceholderParser, "GCode::PlaceholderParser"); REGISTER_CLASS(Polygon, "Polygon"); REGISTER_CLASS(Polyline, "Polyline"); REGISTER_CLASS(PolylineCollection, "Polyline::Collection"); REGISTER_CLASS(Print, "Print"); REGISTER_CLASS(PrintObject, "Print::Object"); REGISTER_CLASS(PrintRegion, "Print::Region"); REGISTER_CLASS(Model, "Model"); REGISTER_CLASS(ModelMaterial, "Model::Material"); REGISTER_CLASS(ModelObject, "Model::Object"); REGISTER_CLASS(ModelVolume, "Model::Volume"); REGISTER_CLASS(ModelInstance, "Model::Instance"); REGISTER_CLASS(MotionPlanner, "MotionPlanner"); REGISTER_CLASS(BoundingBox, "Geometry::BoundingBox"); REGISTER_CLASS(BoundingBoxf, "Geometry::BoundingBoxf"); REGISTER_CLASS(BoundingBoxf3, "Geometry::BoundingBoxf3"); REGISTER_CLASS(BridgeDetector, "BridgeDetector"); REGISTER_CLASS(Point, "Point"); REGISTER_CLASS(Point3, "Point3"); REGISTER_CLASS(Pointf, "Pointf"); REGISTER_CLASS(Pointf3, "Pointf3"); REGISTER_CLASS(DynamicPrintConfig, "Config"); REGISTER_CLASS(PrintObjectConfig, "Config::PrintObject"); REGISTER_CLASS(PrintRegionConfig, "Config::PrintRegion"); REGISTER_CLASS(GCodeConfig, "Config::GCode"); REGISTER_CLASS(PrintConfig, "Config::Print"); REGISTER_CLASS(FullPrintConfig, "Config::Full"); REGISTER_CLASS(Surface, "Surface"); REGISTER_CLASS(SurfaceCollection, "Surface::Collection"); REGISTER_CLASS(TriangleMesh, "TriangleMesh"); REGISTER_CLASS(GLVertexArray, "GUI::_3DScene::GLVertexArray"); SV* ConfigBase__as_hash(ConfigBase* THIS) { HV* hv = newHV(); t_config_option_keys opt_keys = THIS->keys(); for (t_config_option_keys::const_iterator it = opt_keys.begin(); it != opt_keys.end(); ++it) (void)hv_store( hv, it->c_str(), it->length(), ConfigBase__get(THIS, *it), 0 ); return newRV_noinc((SV*)hv); } SV* ConfigBase__get(ConfigBase* THIS, const t_config_option_key &opt_key) { ConfigOption* opt = THIS->option(opt_key); if (opt == NULL) return &PL_sv_undef; const ConfigOptionDef* def = THIS->def->get(opt_key); if (def->type == coFloat) { ConfigOptionFloat* optv = dynamic_cast(opt); return newSVnv(optv->value); } else if (def->type == coFloats) { ConfigOptionFloats* optv = dynamic_cast(opt); AV* av = newAV(); av_fill(av, optv->values.size()-1); for (std::vector::iterator it = optv->values.begin(); it != optv->values.end(); ++it) av_store(av, it - optv->values.begin(), newSVnv(*it)); return newRV_noinc((SV*)av); } else if (def->type == coPercent) { ConfigOptionPercent* optv = dynamic_cast(opt); return newSVnv(optv->value); } else if (def->type == coInt) { ConfigOptionInt* optv = dynamic_cast(opt); return newSViv(optv->value); } else if (def->type == coInts) { ConfigOptionInts* optv = dynamic_cast(opt); AV* av = newAV(); av_fill(av, optv->values.size()-1); for (std::vector::iterator it = optv->values.begin(); it != optv->values.end(); ++it) av_store(av, it - optv->values.begin(), newSViv(*it)); return newRV_noinc((SV*)av); } else if (def->type == coString) { ConfigOptionString* optv = dynamic_cast(opt); // we don't serialize() because that would escape newlines return newSVpvn_utf8(optv->value.c_str(), optv->value.length(), true); } else if (def->type == coStrings) { ConfigOptionStrings* optv = dynamic_cast(opt); AV* av = newAV(); av_fill(av, optv->values.size()-1); for (std::vector::iterator it = optv->values.begin(); it != optv->values.end(); ++it) av_store(av, it - optv->values.begin(), newSVpvn_utf8(it->c_str(), it->length(), true)); return newRV_noinc((SV*)av); } else if (def->type == coPoint) { ConfigOptionPoint* optv = dynamic_cast(opt); return perl_to_SV_clone_ref(optv->value); } else if (def->type == coPoints) { ConfigOptionPoints* optv = dynamic_cast(opt); AV* av = newAV(); av_fill(av, optv->values.size()-1); for (Pointfs::iterator it = optv->values.begin(); it != optv->values.end(); ++it) av_store(av, it - optv->values.begin(), perl_to_SV_clone_ref(*it)); return newRV_noinc((SV*)av); } else if (def->type == coBool) { ConfigOptionBool* optv = dynamic_cast(opt); return newSViv(optv->value ? 1 : 0); } else if (def->type == coBools) { ConfigOptionBools* optv = dynamic_cast(opt); AV* av = newAV(); av_fill(av, optv->values.size()-1); for (std::vector::iterator it = optv->values.begin(); it != optv->values.end(); ++it) av_store(av, it - optv->values.begin(), newSViv(*it ? 1 : 0)); return newRV_noinc((SV*)av); } else { std::string serialized = opt->serialize(); return newSVpvn_utf8(serialized.c_str(), serialized.length(), true); } } SV* ConfigBase__get_at(ConfigBase* THIS, const t_config_option_key &opt_key, size_t i) { ConfigOption* opt = THIS->option(opt_key); if (opt == NULL) return &PL_sv_undef; const ConfigOptionDef* def = THIS->def->get(opt_key); if (def->type == coFloats) { ConfigOptionFloats* optv = dynamic_cast(opt); return newSVnv(optv->get_at(i)); } else if (def->type == coInts) { ConfigOptionInts* optv = dynamic_cast(opt); return newSViv(optv->get_at(i)); } else if (def->type == coStrings) { ConfigOptionStrings* optv = dynamic_cast(opt); // we don't serialize() because that would escape newlines std::string val = optv->get_at(i); return newSVpvn_utf8(val.c_str(), val.length(), true); } else if (def->type == coPoints) { ConfigOptionPoints* optv = dynamic_cast(opt); return perl_to_SV_clone_ref(optv->get_at(i)); } else if (def->type == coBools) { ConfigOptionBools* optv = dynamic_cast(opt); return newSViv(optv->get_at(i) ? 1 : 0); } else { return &PL_sv_undef; } } bool ConfigBase__set(ConfigBase* THIS, const t_config_option_key &opt_key, SV* value) { ConfigOption* opt = THIS->option(opt_key, true); if (opt == NULL) CONFESS("Trying to set non-existing option"); const ConfigOptionDef* def = THIS->def->get(opt_key); if (def->type == coFloat) { if (!looks_like_number(value)) return false; ConfigOptionFloat* optv = dynamic_cast(opt); optv->value = SvNV(value); } else if (def->type == coFloats) { ConfigOptionFloats* optv = dynamic_cast(opt); std::vector values; AV* av = (AV*)SvRV(value); const size_t len = av_len(av)+1; for (size_t i = 0; i < len; i++) { SV** elem = av_fetch(av, i, 0); if (elem == NULL || !looks_like_number(*elem)) return false; values.push_back(SvNV(*elem)); } optv->values = values; } else if (def->type == coInt) { if (!looks_like_number(value)) return false; ConfigOptionInt* optv = dynamic_cast(opt); optv->value = SvIV(value); } else if (def->type == coInts) { ConfigOptionInts* optv = dynamic_cast(opt); std::vector values; AV* av = (AV*)SvRV(value); const size_t len = av_len(av)+1; for (size_t i = 0; i < len; i++) { SV** elem = av_fetch(av, i, 0); if (elem == NULL || !looks_like_number(*elem)) return false; values.push_back(SvIV(*elem)); } optv->values = values; } else if (def->type == coString) { ConfigOptionString* optv = dynamic_cast(opt); optv->value = std::string(SvPV_nolen(value), SvCUR(value)); } else if (def->type == coStrings) { ConfigOptionStrings* optv = dynamic_cast(opt); optv->values.clear(); AV* av = (AV*)SvRV(value); const size_t len = av_len(av)+1; for (size_t i = 0; i < len; i++) { SV** elem = av_fetch(av, i, 0); if (elem == NULL) return false; optv->values.push_back(std::string(SvPV_nolen(*elem), SvCUR(*elem))); } } else if (def->type == coPoint) { ConfigOptionPoint* optv = dynamic_cast(opt); return from_SV_check(value, &optv->value); } else if (def->type == coPoints) { ConfigOptionPoints* optv = dynamic_cast(opt); std::vector values; AV* av = (AV*)SvRV(value); const size_t len = av_len(av)+1; for (size_t i = 0; i < len; i++) { SV** elem = av_fetch(av, i, 0); Pointf point; if (elem == NULL || !from_SV_check(*elem, &point)) return false; values.push_back(point); } optv->values = values; } else if (def->type == coBool) { ConfigOptionBool* optv = dynamic_cast(opt); optv->value = SvTRUE(value); } else if (def->type == coBools) { ConfigOptionBools* optv = dynamic_cast(opt); optv->values.clear(); AV* av = (AV*)SvRV(value); const size_t len = av_len(av)+1; for (size_t i = 0; i < len; i++) { SV** elem = av_fetch(av, i, 0); if (elem == NULL) return false; optv->values.push_back(SvTRUE(*elem)); } } else { if (!opt->deserialize( std::string(SvPV_nolen(value)) )) return false; } return true; } /* This method is implemented as a workaround for this typemap bug: https://rt.cpan.org/Public/Bug/Display.html?id=94110 */ bool ConfigBase__set_deserialize(ConfigBase* THIS, const t_config_option_key &opt_key, SV* str) { size_t len; const char * c = SvPV(str, len); std::string value(c, len); return THIS->set_deserialize(opt_key, value); } void ConfigBase__set_ifndef(ConfigBase* THIS, const t_config_option_key &opt_key, SV* value, bool deserialize) { if (!THIS->has(opt_key)) { if (deserialize) { ConfigBase__set_deserialize(THIS, opt_key, value); } else { ConfigBase__set(THIS, opt_key, value); } } } bool StaticConfig__set(StaticConfig* THIS, const t_config_option_key &opt_key, SV* value) { const ConfigOptionDef* optdef = THIS->def->get(opt_key); if (!optdef->shortcut.empty()) { for (std::vector::const_iterator it = optdef->shortcut.begin(); it != optdef->shortcut.end(); ++it) { if (!StaticConfig__set(THIS, *it, value)) return false; } return true; } return ConfigBase__set(THIS, opt_key, value); } SV* to_AV(ExPolygon* expolygon) { const unsigned int num_holes = expolygon->holes.size(); AV* av = newAV(); av_extend(av, num_holes); // -1 +1 av_store(av, 0, perl_to_SV_ref(expolygon->contour)); for (unsigned int i = 0; i < num_holes; i++) { av_store(av, i+1, perl_to_SV_ref(expolygon->holes[i])); } return newRV_noinc((SV*)av); } SV* to_SV_pureperl(const ExPolygon* expolygon) { const unsigned int num_holes = expolygon->holes.size(); AV* av = newAV(); av_extend(av, num_holes); // -1 +1 av_store(av, 0, to_SV_pureperl(&expolygon->contour)); for (unsigned int i = 0; i < num_holes; i++) { av_store(av, i+1, to_SV_pureperl(&expolygon->holes[i])); } return newRV_noinc((SV*)av); } void from_SV(SV* expoly_sv, ExPolygon* expolygon) { AV* expoly_av = (AV*)SvRV(expoly_sv); const unsigned int num_polygons = av_len(expoly_av)+1; expolygon->holes.resize(num_polygons-1); SV** polygon_sv = av_fetch(expoly_av, 0, 0); from_SV(*polygon_sv, &expolygon->contour); for (unsigned int i = 0; i < num_polygons-1; i++) { polygon_sv = av_fetch(expoly_av, i+1, 0); from_SV(*polygon_sv, &expolygon->holes[i]); } } void from_SV_check(SV* expoly_sv, ExPolygon* expolygon) { if (sv_isobject(expoly_sv) && (SvTYPE(SvRV(expoly_sv)) == SVt_PVMG)) { if (!sv_isa(expoly_sv, perl_class_name(expolygon)) && !sv_isa(expoly_sv, perl_class_name_ref(expolygon))) CONFESS("Not a valid %s object", perl_class_name(expolygon)); // a XS ExPolygon was supplied *expolygon = *(ExPolygon *)SvIV((SV*)SvRV( expoly_sv )); } else { // a Perl arrayref was supplied from_SV(expoly_sv, expolygon); } } void from_SV(SV* line_sv, Line* THIS) { AV* line_av = (AV*)SvRV(line_sv); from_SV_check(*av_fetch(line_av, 0, 0), &THIS->a); from_SV_check(*av_fetch(line_av, 1, 0), &THIS->b); } void from_SV_check(SV* line_sv, Line* THIS) { if (sv_isobject(line_sv) && (SvTYPE(SvRV(line_sv)) == SVt_PVMG)) { if (!sv_isa(line_sv, perl_class_name(THIS)) && !sv_isa(line_sv, perl_class_name_ref(THIS))) CONFESS("Not a valid %s object", perl_class_name(THIS)); *THIS = *(Line*)SvIV((SV*)SvRV( line_sv )); } else { from_SV(line_sv, THIS); } } SV* to_AV(Line* THIS) { AV* av = newAV(); av_extend(av, 1); av_store(av, 0, perl_to_SV_ref(THIS->a)); av_store(av, 1, perl_to_SV_ref(THIS->b)); return newRV_noinc((SV*)av); } SV* to_SV_pureperl(const Line* THIS) { AV* av = newAV(); av_extend(av, 1); av_store(av, 0, to_SV_pureperl(&THIS->a)); av_store(av, 1, to_SV_pureperl(&THIS->b)); return newRV_noinc((SV*)av); } void from_SV(SV* poly_sv, MultiPoint* THIS) { AV* poly_av = (AV*)SvRV(poly_sv); const unsigned int num_points = av_len(poly_av)+1; THIS->points.resize(num_points); for (unsigned int i = 0; i < num_points; i++) { SV** point_sv = av_fetch(poly_av, i, 0); from_SV_check(*point_sv, &THIS->points[i]); } } void from_SV_check(SV* poly_sv, MultiPoint* THIS) { if (sv_isobject(poly_sv) && (SvTYPE(SvRV(poly_sv)) == SVt_PVMG)) { *THIS = *(MultiPoint*)SvIV((SV*)SvRV( poly_sv )); } else { from_SV(poly_sv, THIS); } } SV* to_AV(MultiPoint* THIS) { const unsigned int num_points = THIS->points.size(); AV* av = newAV(); if (num_points > 0) av_extend(av, num_points-1); for (unsigned int i = 0; i < num_points; i++) { av_store(av, i, perl_to_SV_ref(THIS->points[i])); } return newRV_noinc((SV*)av); } SV* to_SV_pureperl(const MultiPoint* THIS) { const unsigned int num_points = THIS->points.size(); AV* av = newAV(); if (num_points > 0) av_extend(av, num_points-1); for (unsigned int i = 0; i < num_points; i++) { av_store(av, i, to_SV_pureperl(&THIS->points[i])); } return newRV_noinc((SV*)av); } void from_SV_check(SV* poly_sv, Polygon* THIS) { if (sv_isobject(poly_sv) && !sv_isa(poly_sv, perl_class_name(THIS)) && !sv_isa(poly_sv, perl_class_name_ref(THIS))) CONFESS("Not a valid %s object", perl_class_name(THIS)); from_SV_check(poly_sv, (MultiPoint*)THIS); } void from_SV_check(SV* poly_sv, Polyline* THIS) { if (!sv_isa(poly_sv, perl_class_name(THIS)) && !sv_isa(poly_sv, perl_class_name_ref(THIS))) CONFESS("Not a valid %s object", perl_class_name(THIS)); from_SV_check(poly_sv, (MultiPoint*)THIS); } SV* to_SV_pureperl(const Point* THIS) { AV* av = newAV(); av_fill(av, 1); av_store(av, 0, newSViv(THIS->x)); av_store(av, 1, newSViv(THIS->y)); return newRV_noinc((SV*)av); } void from_SV(SV* point_sv, Point* point) { AV* point_av = (AV*)SvRV(point_sv); // get a double from Perl and round it, otherwise // it would get truncated point->x = lrint(SvNV(*av_fetch(point_av, 0, 0))); point->y = lrint(SvNV(*av_fetch(point_av, 1, 0))); } void from_SV_check(SV* point_sv, Point* point) { if (sv_isobject(point_sv) && (SvTYPE(SvRV(point_sv)) == SVt_PVMG)) { if (!sv_isa(point_sv, perl_class_name(point)) && !sv_isa(point_sv, perl_class_name_ref(point))) CONFESS("Not a valid %s object (got %s)", perl_class_name(point), HvNAME(SvSTASH(SvRV(point_sv)))); *point = *(Point*)SvIV((SV*)SvRV( point_sv )); } else { from_SV(point_sv, point); } } SV* to_SV_pureperl(const Pointf* point) { AV* av = newAV(); av_fill(av, 1); av_store(av, 0, newSVnv(point->x)); av_store(av, 1, newSVnv(point->y)); return newRV_noinc((SV*)av); } bool from_SV(SV* point_sv, Pointf* point) { AV* point_av = (AV*)SvRV(point_sv); SV* sv_x = *av_fetch(point_av, 0, 0); SV* sv_y = *av_fetch(point_av, 1, 0); if (!looks_like_number(sv_x) || !looks_like_number(sv_y)) return false; point->x = SvNV(sv_x); point->y = SvNV(sv_y); return true; } bool from_SV_check(SV* point_sv, Pointf* point) { if (sv_isobject(point_sv) && (SvTYPE(SvRV(point_sv)) == SVt_PVMG)) { if (!sv_isa(point_sv, perl_class_name(point)) && !sv_isa(point_sv, perl_class_name_ref(point))) CONFESS("Not a valid %s object (got %s)", perl_class_name(point), HvNAME(SvSTASH(SvRV(point_sv)))); *point = *(Pointf*)SvIV((SV*)SvRV( point_sv )); return true; } else { return from_SV(point_sv, point); } } void from_SV_check(SV* surface_sv, Surface* THIS) { if (!sv_isa(surface_sv, perl_class_name(THIS)) && !sv_isa(surface_sv, perl_class_name_ref(THIS))) CONFESS("Not a valid %s object", perl_class_name(THIS)); // a XS Surface was supplied *THIS = *(Surface *)SvIV((SV*)SvRV( surface_sv )); } SV* to_SV(TriangleMesh* THIS) { SV* sv = newSV(0); sv_setref_pv( sv, perl_class_name(THIS), (void*)THIS ); return sv; } SV* polynode_children_2_perl(const ClipperLib::PolyNode& node) { AV* av = newAV(); const int len = node.ChildCount(); if (len > 0) av_extend(av, len-1); for (int i = 0; i < len; ++i) { av_store(av, i, polynode2perl(*node.Childs[i])); } return (SV*)newRV_noinc((SV*)av); } SV* polynode2perl(const ClipperLib::PolyNode& node) { HV* hv = newHV(); Slic3r::Polygon p; ClipperPath_to_Slic3rMultiPoint(node.Contour, &p); if (node.IsHole()) { (void)hv_stores( hv, "hole", Slic3r::perl_to_SV_clone_ref(p) ); } else { (void)hv_stores( hv, "outer", Slic3r::perl_to_SV_clone_ref(p) ); } (void)hv_stores( hv, "children", polynode_children_2_perl(node) ); return (SV*)newRV_noinc((SV*)hv); } } #endif