487 lines
16 KiB
C++
487 lines
16 KiB
C++
#include "sla_test_utils.hpp"
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#include "libslic3r/TriangleMeshSlicer.hpp"
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#include "libslic3r/SLA/AGGRaster.hpp"
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#include <iomanip>
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void test_support_model_collision(const std::string &obj_filename,
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const sla::SupportTreeConfig &input_supportcfg,
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const sla::HollowingConfig &hollowingcfg,
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const sla::DrainHoles &drainholes)
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{
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SupportByproducts byproducts;
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sla::SupportTreeConfig supportcfg = input_supportcfg;
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// Set head penetration to a small negative value which should ensure that
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// the supports will not touch the model body.
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supportcfg.head_penetration_mm = -0.15;
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test_supports(obj_filename, supportcfg, hollowingcfg, drainholes, byproducts);
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// Slice the support mesh given the slice grid of the model.
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std::vector<ExPolygons> support_slices =
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byproducts.supporttree.slice(byproducts.slicegrid, CLOSING_RADIUS);
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// The slices originate from the same slice grid so the numbers must match
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bool support_mesh_is_empty =
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byproducts.supporttree.retrieve_mesh(sla::MeshType::Pad).empty() &&
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byproducts.supporttree.retrieve_mesh(sla::MeshType::Support).empty();
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if (support_mesh_is_empty)
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REQUIRE(support_slices.empty());
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else
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REQUIRE(support_slices.size() == byproducts.model_slices.size());
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bool notouch = true;
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for (size_t n = 0; notouch && n < support_slices.size(); ++n) {
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const ExPolygons &sup_slice = support_slices[n];
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const ExPolygons &mod_slice = byproducts.model_slices[n];
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Polygons intersections = intersection(sup_slice, mod_slice);
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double pinhead_r = scaled(input_supportcfg.head_front_radius_mm);
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// TODO:: make it strict without a threshold of PI * pihead_radius ^ 2
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notouch = notouch && area(intersections) < PI * pinhead_r * pinhead_r;
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}
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/*if (!notouch) */export_failed_case(support_slices, byproducts);
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REQUIRE(notouch);
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}
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void export_failed_case(const std::vector<ExPolygons> &support_slices, const SupportByproducts &byproducts)
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{
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for (size_t n = 0; n < support_slices.size(); ++n) {
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const ExPolygons &sup_slice = support_slices[n];
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const ExPolygons &mod_slice = byproducts.model_slices[n];
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Polygons intersections = intersection(sup_slice, mod_slice);
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std::stringstream ss;
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if (!intersections.empty()) {
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ss << byproducts.obj_fname << std::setprecision(4) << n << ".svg";
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SVG svg(ss.str());
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svg.draw(sup_slice, "green");
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svg.draw(mod_slice, "blue");
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svg.draw(intersections, "red");
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svg.Close();
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}
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}
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TriangleMesh m;
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byproducts.supporttree.retrieve_full_mesh(m);
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m.merge(byproducts.input_mesh);
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m.repair();
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m.require_shared_vertices();
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m.WriteOBJFile((Catch::getResultCapture().getCurrentTestName() + "_" +
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byproducts.obj_fname).c_str());
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}
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void test_supports(const std::string &obj_filename,
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const sla::SupportTreeConfig &supportcfg,
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const sla::HollowingConfig &hollowingcfg,
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const sla::DrainHoles &drainholes,
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SupportByproducts &out)
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{
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using namespace Slic3r;
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TriangleMesh mesh = load_model(obj_filename);
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REQUIRE_FALSE(mesh.empty());
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if (hollowingcfg.enabled) {
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sla::InteriorPtr interior = sla::generate_interior(mesh, hollowingcfg);
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REQUIRE(interior);
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mesh.merge(sla::get_mesh(*interior));
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mesh.require_shared_vertices();
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}
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auto bb = mesh.bounding_box();
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double zmin = bb.min.z();
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double zmax = bb.max.z();
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double gnd = zmin - supportcfg.object_elevation_mm;
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auto layer_h = 0.05f;
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out.slicegrid = grid(float(gnd), float(zmax), layer_h);
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assert(mesh.has_shared_vertices());
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out.model_slices = slice_mesh_ex(mesh.its, out.slicegrid, CLOSING_RADIUS);
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sla::cut_drainholes(out.model_slices, out.slicegrid, CLOSING_RADIUS, drainholes, []{});
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// Create the special index-triangle mesh with spatial indexing which
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// is the input of the support point and support mesh generators
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sla::IndexedMesh emesh{mesh};
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#ifdef SLIC3R_HOLE_RAYCASTER
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if (hollowingcfg.enabled)
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emesh.load_holes(drainholes);
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#endif
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// TODO: do the cgal hole cutting...
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// Create the support point generator
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sla::SupportPointGenerator::Config autogencfg;
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autogencfg.head_diameter = float(2 * supportcfg.head_front_radius_mm);
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sla::SupportPointGenerator point_gen{emesh, autogencfg, [] {}, [](int) {}};
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point_gen.seed(0); // Make the test repeatable
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point_gen.execute(out.model_slices, out.slicegrid);
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// Get the calculated support points.
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std::vector<sla::SupportPoint> support_points = point_gen.output();
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int validityflags = ASSUME_NO_REPAIR;
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// If there is no elevation, support points shall be removed from the
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// bottom of the object.
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if (std::abs(supportcfg.object_elevation_mm) < EPSILON) {
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sla::remove_bottom_points(support_points, zmin + supportcfg.base_height_mm);
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} else {
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// Should be support points at least on the bottom of the model
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REQUIRE_FALSE(support_points.empty());
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// Also the support mesh should not be empty.
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validityflags |= ASSUME_NO_EMPTY;
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}
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// Generate the actual support tree
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sla::SupportTreeBuilder treebuilder;
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sla::SupportableMesh sm{emesh, support_points, supportcfg};
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sla::SupportTreeBuildsteps::execute(treebuilder, sm);
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check_support_tree_integrity(treebuilder, supportcfg);
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const TriangleMesh &output_mesh = treebuilder.retrieve_mesh();
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check_validity(output_mesh, validityflags);
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// Quick check if the dimensions and placement of supports are correct
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auto obb = output_mesh.bounding_box();
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double allowed_zmin = zmin - supportcfg.object_elevation_mm;
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if (std::abs(supportcfg.object_elevation_mm) < EPSILON)
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allowed_zmin = zmin - 2 * supportcfg.head_back_radius_mm;
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REQUIRE(obb.min.z() >= Approx(allowed_zmin));
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REQUIRE(obb.max.z() <= Approx(zmax));
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// Move out the support tree into the byproducts, we can examine it further
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// in various tests.
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out.obj_fname = std::move(obj_filename);
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out.supporttree = std::move(treebuilder);
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out.input_mesh = std::move(mesh);
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}
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void check_support_tree_integrity(const sla::SupportTreeBuilder &stree,
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const sla::SupportTreeConfig &cfg)
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{
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double gnd = stree.ground_level;
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double H1 = cfg.max_solo_pillar_height_mm;
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double H2 = cfg.max_dual_pillar_height_mm;
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for (const sla::Head &head : stree.heads()) {
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REQUIRE((!head.is_valid() || head.pillar_id != sla::SupportTreeNode::ID_UNSET ||
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head.bridge_id != sla::SupportTreeNode::ID_UNSET));
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}
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for (const sla::Pillar &pillar : stree.pillars()) {
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if (std::abs(pillar.endpoint().z() - gnd) < EPSILON) {
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double h = pillar.height;
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if (h > H1) REQUIRE(pillar.links >= 1);
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else if(h > H2) { REQUIRE(pillar.links >= 2); }
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}
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REQUIRE(pillar.links <= cfg.pillar_cascade_neighbors);
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REQUIRE(pillar.bridges <= cfg.max_bridges_on_pillar);
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}
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double max_bridgelen = 0.;
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auto chck_bridge = [&cfg](const sla::Bridge &bridge, double &max_brlen) {
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Vec3d n = bridge.endp - bridge.startp;
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double d = sla::distance(n);
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max_brlen = std::max(d, max_brlen);
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double z = n.z();
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double polar = std::acos(z / d);
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double slope = -polar + PI / 2.;
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REQUIRE(std::abs(slope) >= cfg.bridge_slope - EPSILON);
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};
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for (auto &bridge : stree.bridges()) chck_bridge(bridge, max_bridgelen);
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REQUIRE(max_bridgelen <= Approx(cfg.max_bridge_length_mm));
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max_bridgelen = 0;
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for (auto &bridge : stree.crossbridges()) chck_bridge(bridge, max_bridgelen);
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double md = cfg.max_pillar_link_distance_mm / std::cos(-cfg.bridge_slope);
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REQUIRE(max_bridgelen <= md);
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}
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void test_pad(const std::string &obj_filename, const sla::PadConfig &padcfg, PadByproducts &out)
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{
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REQUIRE(padcfg.validate().empty());
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TriangleMesh mesh = load_model(obj_filename);
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REQUIRE_FALSE(mesh.empty());
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// Create pad skeleton only from the model
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Slic3r::sla::pad_blueprint(mesh, out.model_contours);
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test_concave_hull(out.model_contours);
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REQUIRE_FALSE(out.model_contours.empty());
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// Create the pad geometry for the model contours only
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Slic3r::sla::create_pad({}, out.model_contours, out.mesh, padcfg);
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check_validity(out.mesh);
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auto bb = out.mesh.bounding_box();
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REQUIRE(bb.max.z() - bb.min.z() == Approx(padcfg.full_height()));
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}
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static void _test_concave_hull(const Polygons &hull, const ExPolygons &polys)
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{
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REQUIRE(polys.size() >=hull.size());
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double polys_area = 0;
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for (const ExPolygon &p : polys) polys_area += p.area();
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double cchull_area = 0;
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for (const Slic3r::Polygon &p : hull) cchull_area += p.area();
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REQUIRE(cchull_area >= Approx(polys_area));
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size_t cchull_holes = 0;
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for (const Slic3r::Polygon &p : hull)
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cchull_holes += p.is_clockwise() ? 1 : 0;
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REQUIRE(cchull_holes == 0);
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Polygons intr = diff(to_polygons(polys), hull);
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REQUIRE(intr.empty());
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}
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void test_concave_hull(const ExPolygons &polys) {
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sla::PadConfig pcfg;
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Slic3r::sla::ConcaveHull cchull{polys, pcfg.max_merge_dist_mm, []{}};
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_test_concave_hull(cchull.polygons(), polys);
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coord_t delta = scaled(pcfg.brim_size_mm + pcfg.wing_distance());
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ExPolygons wafflex = sla::offset_waffle_style_ex(cchull, delta);
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Polygons waffl = sla::offset_waffle_style(cchull, delta);
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_test_concave_hull(to_polygons(wafflex), polys);
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_test_concave_hull(waffl, polys);
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}
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void check_validity(const TriangleMesh &input_mesh, int flags)
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{
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TriangleMesh mesh{input_mesh};
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if (flags & ASSUME_NO_EMPTY) {
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REQUIRE_FALSE(mesh.empty());
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} else if (mesh.empty())
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return; // If it can be empty and it is, there is nothing left to do.
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REQUIRE(stl_validate(&mesh.stl));
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bool do_update_shared_vertices = false;
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mesh.repair(do_update_shared_vertices);
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if (flags & ASSUME_NO_REPAIR) {
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REQUIRE_FALSE(mesh.needed_repair());
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}
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if (flags & ASSUME_MANIFOLD) {
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mesh.require_shared_vertices();
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if (!mesh.is_manifold()) mesh.WriteOBJFile("non_manifold.obj");
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REQUIRE(mesh.is_manifold());
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}
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}
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void check_raster_transformations(sla::RasterBase::Orientation o, sla::RasterBase::TMirroring mirroring)
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{
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double disp_w = 120., disp_h = 68.;
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sla::RasterBase::Resolution res{2560, 1440};
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sla::RasterBase::PixelDim pixdim{disp_w / res.width_px, disp_h / res.height_px};
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auto bb = BoundingBox({0, 0}, {scaled(disp_w), scaled(disp_h)});
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sla::RasterBase::Trafo trafo{o, mirroring};
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trafo.center_x = bb.center().x();
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trafo.center_y = bb.center().y();
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double gamma = 1.;
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sla::RasterGrayscaleAAGammaPower raster{res, pixdim, trafo, gamma};
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// create box of size 32x32 pixels (not 1x1 to avoid antialiasing errors)
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coord_t pw = 32 * coord_t(std::ceil(scaled<double>(pixdim.w_mm)));
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coord_t ph = 32 * coord_t(std::ceil(scaled<double>(pixdim.h_mm)));
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ExPolygon box;
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box.contour.points = {{-pw, -ph}, {pw, -ph}, {pw, ph}, {-pw, ph}};
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double tr_x = scaled<double>(20.), tr_y = tr_x;
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box.translate(tr_x, tr_y);
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ExPolygon expected_box = box;
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// Now calculate the position of the translated box according to output
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// trafo.
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if (o == sla::RasterBase::Orientation::roPortrait) expected_box.rotate(PI / 2.);
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if (mirroring[X])
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for (auto &p : expected_box.contour.points) p.x() = -p.x();
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if (mirroring[Y])
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for (auto &p : expected_box.contour.points) p.y() = -p.y();
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raster.draw(box);
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Point expected_coords = expected_box.contour.bounding_box().center();
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double rx = unscaled(expected_coords.x() + bb.center().x()) / pixdim.w_mm;
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double ry = unscaled(expected_coords.y() + bb.center().y()) / pixdim.h_mm;
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auto w = size_t(std::floor(rx));
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auto h = res.height_px - size_t(std::floor(ry));
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REQUIRE((w < res.width_px && h < res.height_px));
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auto px = raster.read_pixel(w, h);
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if (px != FullWhite) {
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std::fstream outf("out.png", std::ios::out);
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outf << raster.encode(sla::PNGRasterEncoder());
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}
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REQUIRE(px == FullWhite);
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}
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ExPolygon square_with_hole(double v)
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{
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ExPolygon poly;
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coord_t V = scaled(v / 2.);
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poly.contour.points = {{-V, -V}, {V, -V}, {V, V}, {-V, V}};
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poly.holes.emplace_back();
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V = V / 2;
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poly.holes.front().points = {{-V, V}, {V, V}, {V, -V}, {-V, -V}};
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return poly;
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}
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long raster_pxsum(const sla::RasterGrayscaleAA &raster)
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{
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auto res = raster.resolution();
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long a = 0;
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for (size_t x = 0; x < res.width_px; ++x)
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for (size_t y = 0; y < res.height_px; ++y)
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a += raster.read_pixel(x, y);
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return a;
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}
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double raster_white_area(const sla::RasterGrayscaleAA &raster)
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{
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if (raster.resolution().pixels() == 0) return std::nan("");
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auto res = raster.resolution();
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double a = 0;
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for (size_t x = 0; x < res.width_px; ++x)
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for (size_t y = 0; y < res.height_px; ++y) {
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auto px = raster.read_pixel(x, y);
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a += pixel_area(px, raster.pixel_dimensions());
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}
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return a;
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}
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double predict_error(const ExPolygon &p, const sla::RasterBase::PixelDim &pd)
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{
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auto lines = p.lines();
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double pix_err = pixel_area(FullWhite, pd) / 2.;
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// Worst case is when a line is parallel to the shorter axis of one pixel,
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// when the line will be composed of the max number of pixels
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double pix_l = std::min(pd.h_mm, pd.w_mm);
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double error = 0.;
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for (auto &l : lines)
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error += (unscaled(l.length()) / pix_l) * pix_err;
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return error;
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}
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// Make a 3D pyramid
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TriangleMesh make_pyramid(float base, float height)
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{
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float a = base / 2.f;
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TriangleMesh mesh(
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{
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{-a, -a, 0}, {a, -a, 0}, {a, a, 0},
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{-a, a, 0}, {0.f, 0.f, height}
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},
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{
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{0, 1, 2},
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{0, 2, 3},
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{0, 1, 4},
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{1, 2, 4},
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{2, 3, 4},
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{3, 0, 4}
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});
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mesh.repair();
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return mesh;
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}
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TriangleMesh make_prism(double width, double length, double height)
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{
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// We need two upward facing triangles
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double x = width / 2., y = length / 2.;
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TriangleMesh mesh(
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{
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{-x, -y, 0.}, {x, -y, 0.}, {0., -y, height},
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{-x, y, 0.}, {x, y, 0.}, {0., y, height},
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},
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{
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{0, 1, 2}, // side 1
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{4, 3, 5}, // side 2
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{1, 4, 2}, {2, 4, 5}, // roof 1
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{0, 2, 5}, {0, 5, 3}, // roof 2
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{3, 4, 1}, {3, 1, 0} // bottom
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});
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return mesh;
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}
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sla::SupportPoints calc_support_pts(
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const TriangleMesh & mesh,
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const sla::SupportPointGenerator::Config &cfg)
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{
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// Prepare the slice grid and the slices
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auto bb = cast<float>(mesh.bounding_box());
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std::vector<float> heights = grid(bb.min.z(), bb.max.z(), 0.1f);
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assert(mesh.has_shared_vertices());
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std::vector<ExPolygons> slices = slice_mesh_ex(mesh.its, heights, CLOSING_RADIUS);
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// Prepare the support point calculator
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sla::IndexedMesh emesh{mesh};
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sla::SupportPointGenerator spgen{emesh, cfg, []{}, [](int){}};
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// Calculate the support points
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spgen.seed(0);
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spgen.execute(slices, heights);
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return spgen.output();
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}
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