Organic supports: Speed up by slicing branches and merging polygons
at the same time, thus reducing memory consumption.
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4a05973ea8
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@ -1464,17 +1464,21 @@ static void generate_initial_areas(
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const size_t num_support_roof_layers = mesh_group_settings.support_roof_enable ? (mesh_group_settings.support_roof_height + config.layer_height / 2) / config.layer_height : 0;
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const size_t num_support_roof_layers = mesh_group_settings.support_roof_enable ? (mesh_group_settings.support_roof_height + config.layer_height / 2) / config.layer_height : 0;
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const bool roof_enabled = num_support_roof_layers > 0;
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const bool roof_enabled = num_support_roof_layers > 0;
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const bool force_tip_to_roof = sqr<double>(config.min_radius) * M_PI > mesh_group_settings.minimum_roof_area && roof_enabled;
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const bool force_tip_to_roof = sqr<double>(config.min_radius) * M_PI > mesh_group_settings.minimum_roof_area && roof_enabled;
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//FIXME mesh_group_settings.support_angle does not apply to enforcers and also it does not apply to automatic support angle (by half the external perimeter width).
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//used by max_overhang_insert_lag, only if not min_xy_dist.
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const coord_t max_overhang_speed = mesh_group_settings.support_angle < 0.5 * M_PI ? coord_t(tan(mesh_group_settings.support_angle) * config.layer_height) : std::numeric_limits<coord_t>::max();
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// cap for how much layer below the overhang a new support point may be added, as other than with regular support every new inserted point
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// cap for how much layer below the overhang a new support point may be added, as other than with regular support every new inserted point
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// may cause extra material and time cost. Could also be an user setting or differently calculated. Idea is that if an overhang
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// may cause extra material and time cost. Could also be an user setting or differently calculated. Idea is that if an overhang
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// does not turn valid in double the amount of layers a slope of support angle would take to travel xy_distance, nothing reasonable will come from it.
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// does not turn valid in double the amount of layers a slope of support angle would take to travel xy_distance, nothing reasonable will come from it.
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// The 2*z_distance_delta is only a catch for when the support angle is very high.
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// The 2*z_distance_delta is only a catch for when the support angle is very high.
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// Used only if not min_xy_dist.
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// Used only if not min_xy_dist.
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const coord_t max_overhang_insert_lag = config.z_distance_top_layers > 0 ?
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coord_t max_overhang_insert_lag = 0;
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std::max<coord_t>(round_up_divide(config.xy_distance, max_overhang_speed / 2), 2 * config.z_distance_top_layers) :
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if (config.z_distance_top_layers > 0) {
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0;
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max_overhang_insert_lag = 2 * config.z_distance_top_layers;
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if (mesh_group_settings.support_angle > EPSILON && mesh_group_settings.support_angle < 0.5 * M_PI - EPSILON) {
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//FIXME mesh_group_settings.support_angle does not apply to enforcers and also it does not apply to automatic support angle (by half the external perimeter width).
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//used by max_overhang_insert_lag, only if not min_xy_dist.
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const auto max_overhang_speed = coord_t(tan(mesh_group_settings.support_angle) * config.layer_height);
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max_overhang_insert_lag = std::max(max_overhang_insert_lag, round_up_divide(config.xy_distance, max_overhang_speed / 2));
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}
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}
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size_t num_support_layers;
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size_t num_support_layers;
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int raft_contact_layer_idx;
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int raft_contact_layer_idx;
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@ -3709,8 +3713,9 @@ static std::pair<int, int> discretize_circle(const Vec3f ¢er, const Vec3f &n
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return { begin, int(pts.size()) };
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return { begin, int(pts.size()) };
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}
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}
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static void extrude_branch(
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// Returns Z span of the generated mesh.
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const std::vector<SupportElement*> &path,
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static std::pair<float, float> extrude_branch(
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const std::vector<const SupportElement*> &path,
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const TreeSupportSettings &config,
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const TreeSupportSettings &config,
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const SlicingParameters &slicing_params,
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const SlicingParameters &slicing_params,
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const std::vector<SupportElements> &move_bounds,
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const std::vector<SupportElements> &move_bounds,
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@ -3727,6 +3732,8 @@ static void extrude_branch(
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// char fname[2048];
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// char fname[2048];
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// static int irun = 0;
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// static int irun = 0;
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float zmin, zmax;
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for (size_t ipath = 1; ipath < path.size(); ++ ipath) {
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for (size_t ipath = 1; ipath < path.size(); ++ ipath) {
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const SupportElement &prev = *path[ipath - 1];
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const SupportElement &prev = *path[ipath - 1];
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const SupportElement ¤t = *path[ipath];
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const SupportElement ¤t = *path[ipath];
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@ -3743,6 +3750,7 @@ static void extrude_branch(
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angle_step = M_PI / (2. * nsteps);
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angle_step = M_PI / (2. * nsteps);
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int ifan = int(result.vertices.size());
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int ifan = int(result.vertices.size());
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result.vertices.emplace_back((p1 - nprev * radius).cast<float>());
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result.vertices.emplace_back((p1 - nprev * radius).cast<float>());
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zmin = result.vertices.back().z();
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float angle = angle_step;
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float angle = angle_step;
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for (int i = 1; i < nsteps; ++ i, angle += angle_step) {
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for (int i = 1; i < nsteps; ++ i, angle += angle_step) {
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std::pair<int, int> strip = discretize_circle((p1 - nprev * radius * cos(angle)).cast<float>(), nprev.cast<float>(), radius * sin(angle), eps, result.vertices);
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std::pair<int, int> strip = discretize_circle((p1 - nprev * radius * cos(angle)).cast<float>(), nprev.cast<float>(), radius * sin(angle), eps, result.vertices);
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@ -3773,6 +3781,7 @@ static void extrude_branch(
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}
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}
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int ifan = int(result.vertices.size());
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int ifan = int(result.vertices.size());
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result.vertices.emplace_back((p2 + ncurrent * radius).cast<float>());
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result.vertices.emplace_back((p2 + ncurrent * radius).cast<float>());
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zmax = result.vertices.back().z();
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triangulate_fan<true>(result, ifan, prev_strip.first, prev_strip.second);
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triangulate_fan<true>(result, ifan, prev_strip.first, prev_strip.second);
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// sprintf(fname, "d:\\temp\\meshes\\tree-partial-%d.obj", ++ irun);
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// sprintf(fname, "d:\\temp\\meshes\\tree-partial-%d.obj", ++ irun);
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// its_write_obj(result, fname);
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// its_write_obj(result, fname);
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@ -3800,6 +3809,8 @@ static void extrude_branch(
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}
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}
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#endif
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#endif
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}
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}
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return std::make_pair(zmin, zmax);
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}
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}
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#endif
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#endif
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@ -4121,15 +4132,13 @@ static void organic_smooth_branches_avoid_collisions(
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#endif // TREE_SUPPORT_ORGANIC_NUDGE_NEW
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#endif // TREE_SUPPORT_ORGANIC_NUDGE_NEW
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// Organic specific: Smooth branches and produce one cummulative mesh to be sliced.
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// Organic specific: Smooth branches and produce one cummulative mesh to be sliced.
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static indexed_triangle_set draw_branches(
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static std::vector<Polygons> draw_branches(
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PrintObject &print_object,
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PrintObject &print_object,
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const TreeModelVolumes &volumes,
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TreeModelVolumes &volumes,
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const TreeSupportSettings &config,
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const TreeSupportSettings &config,
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std::vector<SupportElements> &move_bounds,
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std::vector<SupportElements> &move_bounds,
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std::function<void()> throw_on_cancel)
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std::function<void()> throw_on_cancel)
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{
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{
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static int irun = 0;
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// All SupportElements are put into a layer independent storage to improve parallelization.
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// All SupportElements are put into a layer independent storage to improve parallelization.
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std::vector<std::pair<SupportElement*, int>> elements_with_link_down;
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std::vector<std::pair<SupportElement*, int>> elements_with_link_down;
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std::vector<size_t> linear_data_layers;
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std::vector<size_t> linear_data_layers;
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@ -4176,127 +4185,188 @@ static indexed_triangle_set draw_branches(
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organic_smooth_branches_avoid_collisions(print_object, volumes, config, move_bounds, elements_with_link_down, linear_data_layers, throw_on_cancel);
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organic_smooth_branches_avoid_collisions(print_object, volumes, config, move_bounds, elements_with_link_down, linear_data_layers, throw_on_cancel);
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// Reduce memory footprint. After this point only finalize_interface_and_support_areas() will use volumes and from that only collisions with zero radius will be used.
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volumes.clear_all_but_object_collision();
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// Unmark all nodes.
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// Unmark all nodes.
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for (SupportElements &elements : move_bounds)
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for (SupportElements &elements : move_bounds)
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for (SupportElement &element : elements)
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for (SupportElement &element : elements)
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element.state.marked = false;
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element.state.marked = false;
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// Traverse all nodes, generate tubes.
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// Traverse all nodes, generate tubes.
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// Traversal stack with nodes and thier current parent
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// Traversal stack with nodes and their current parent
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const SlicingParameters &slicing_params = print_object.slicing_parameters();
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std::vector<SupportElement*> path;
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indexed_triangle_set cummulative_mesh;
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indexed_triangle_set partial_mesh;
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indexed_triangle_set temp_mesh;
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for (LayerIndex layer_idx = 0; layer_idx + 1 < LayerIndex(move_bounds.size()); ++ layer_idx) {
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SupportElements &layer = move_bounds[layer_idx];
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SupportElements &layer_above = move_bounds[layer_idx + 1];
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for (SupportElement &start_element : layer)
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struct Branch {
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if (! start_element.state.marked && ! start_element.parents.empty()) {
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std::vector<const SupportElement*> path;
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bool has_root{ false };
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bool has_tip { false };
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};
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struct Slice {
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Polygons polygons;
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size_t num_branches{ 0 };
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};
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struct Tree {
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std::vector<Branch> branches;
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std::vector<Slice> slices;
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LayerIndex first_layer_id{ -1 };
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};
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std::vector<Tree> trees;
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struct TreeVisitor {
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static void visit_recursive(std::vector<SupportElements> &move_bounds, SupportElement &start_element, Tree &out) {
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assert(! start_element.state.marked && ! start_element.parents.empty());
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// Collect elements up to a bifurcation above.
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// Collect elements up to a bifurcation above.
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start_element.state.marked = true;
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start_element.state.marked = true;
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// For each branch bifurcating from this point:
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SupportElements &layer = move_bounds[start_element.state.layer_idx];
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SupportElements &layer_above = move_bounds[start_element.state.layer_idx + 1];
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bool root = out.branches.empty();
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for (size_t parent_idx = 0; parent_idx < start_element.parents.size(); ++ parent_idx) {
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for (size_t parent_idx = 0; parent_idx < start_element.parents.size(); ++ parent_idx) {
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path.clear();
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Branch branch;
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path.emplace_back(&start_element);
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branch.path.emplace_back(&start_element);
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// Traverse each branch until it branches again.
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// Traverse each branch until it branches again.
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SupportElement &first_parent = layer_above[start_element.parents[parent_idx]];
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SupportElement &first_parent = layer_above[start_element.parents[parent_idx]];
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assert(path.back()->state.layer_idx + 1 == first_parent.state.layer_idx);
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assert(branch.path.back()->state.layer_idx + 1 == first_parent.state.layer_idx);
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path.emplace_back(&first_parent);
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branch.path.emplace_back(&first_parent);
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if (first_parent.parents.size() < 2)
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if (first_parent.parents.size() < 2)
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first_parent.state.marked = true;
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first_parent.state.marked = true;
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if (first_parent.parents.size() == 1) {
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SupportElement *next_branch = nullptr;
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if (first_parent.parents.size() == 1)
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for (SupportElement *parent = &first_parent;;) {
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for (SupportElement *parent = &first_parent;;) {
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SupportElement &next_parent = move_bounds[parent->state.layer_idx + 1][parent->parents.front()];
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SupportElement &next_parent = move_bounds[parent->state.layer_idx + 1][parent->parents.front()];
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assert(path.back()->state.layer_idx + 1 == next_parent.state.layer_idx);
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assert(branch.path.back()->state.layer_idx + 1 == next_parent.state.layer_idx);
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path.emplace_back(&next_parent);
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branch.path.emplace_back(&next_parent);
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if (next_parent.parents.size() > 1)
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if (next_parent.parents.size() > 1) {
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next_branch = &next_parent;
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break;
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break;
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}
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next_parent.state.marked = true;
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next_parent.state.marked = true;
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if (next_parent.parents.size() == 0)
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if (next_parent.parents.size() == 0)
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break;
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break;
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parent = &next_parent;
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parent = &next_parent;
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}
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}
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assert(branch.path.size() >= 2);
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branch.has_root = root;
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branch.has_tip = ! next_branch;
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out.branches.emplace_back(std::move(branch));
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if (next_branch)
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visit_recursive(move_bounds, *next_branch, out);
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}
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}
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}
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};
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for (LayerIndex layer_idx = 0; layer_idx + 1 < LayerIndex(move_bounds.size()); ++ layer_idx)
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for (SupportElement &start_element : move_bounds[layer_idx])
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if (! start_element.state.marked && ! start_element.parents.empty()) {
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trees.push_back({});
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TreeVisitor::visit_recursive(move_bounds, start_element, trees.back());
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assert(! trees.back().branches.empty());
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}
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const SlicingParameters &slicing_params = print_object.slicing_parameters();
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MeshSlicingParams mesh_slicing_params;
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mesh_slicing_params.mode = MeshSlicingParams::SlicingMode::Positive;
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tbb::parallel_for(tbb::blocked_range<size_t>(0, trees.size()),
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[&trees, &config, &slicing_params, &move_bounds, &mesh_slicing_params, &throw_on_cancel](const tbb::blocked_range<size_t> &range) {
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indexed_triangle_set partial_mesh;
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std::vector<float> slice_z;
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for (size_t tree_id = range.begin(); tree_id < range.end(); ++ tree_id) {
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Tree &tree = trees[tree_id];
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for (const Branch &branch : tree.branches) {
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// Triangulate the tube.
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// Triangulate the tube.
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partial_mesh.clear();
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partial_mesh.clear();
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extrude_branch(path, config, slicing_params, move_bounds, partial_mesh);
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std::pair<float, float> zspan = extrude_branch(branch.path, config, slicing_params, move_bounds, partial_mesh);
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#if 0
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LayerIndex layer_begin = branch.has_root ?
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{
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branch.path.front()->state.layer_idx :
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char fname[2048];
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std::min(branch.path.front()->state.layer_idx, layer_idx_ceil(slicing_params, config, zspan.first));
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static int irun = 0;
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LayerIndex layer_end = (branch.has_tip ?
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sprintf(fname, "d:\\temp\\meshes\\tree-raw-%d.obj", ++ irun);
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branch.path.back()->state.layer_idx :
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its_write_obj(partial_mesh, fname);
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std::max(branch.path.back()->state.layer_idx, layer_idx_floor(slicing_params, config, zspan.second))) + 1;
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#if 0
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slice_z.clear();
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temp_mesh.clear();
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for (LayerIndex layer_idx = layer_begin; layer_idx < layer_end; ++ layer_idx) {
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cut_mesh(partial_mesh, layer_z(slicing_params, path.back()->state.layer_idx) + EPSILON, nullptr, &temp_mesh, false);
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const double print_z = layer_z(slicing_params, config, layer_idx);
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sprintf(fname, "d:\\temp\\meshes\\tree-trimmed1-%d.obj", irun);
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const double bottom_z = layer_idx > 0 ? layer_z(slicing_params, config, layer_idx - 1) : 0.;
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its_write_obj(temp_mesh, fname);
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slice_z.emplace_back(float(0.5 * (bottom_z + print_z)));
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partial_mesh.clear();
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cut_mesh(temp_mesh, layer_z(slicing_params, path.front()->state.layer_idx) - EPSILON, &partial_mesh, nullptr, false);
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sprintf(fname, "d:\\temp\\meshes\\tree-trimmed2-%d.obj", irun);
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#endif
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its_write_obj(partial_mesh, fname);
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}
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}
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#endif
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std::vector<Polygons> slices = slice_mesh(partial_mesh, slice_z, mesh_slicing_params, throw_on_cancel);
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its_merge(cummulative_mesh, partial_mesh);
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size_t num_empty = std::find_if(slices.begin(), slices.end(), [](auto &s) { return !s.empty(); }) - slices.begin();
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layer_begin += LayerIndex(num_empty);
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for (; slices.back().empty(); -- layer_end);
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LayerIndex new_begin = tree.first_layer_id == -1 ? layer_begin : std::min(tree.first_layer_id, layer_begin);
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LayerIndex new_end = tree.first_layer_id == -1 ? layer_end : std::max(tree.first_layer_id + LayerIndex(tree.slices.size()), layer_end);
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size_t new_size = size_t(new_end - new_begin);
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if (tree.first_layer_id == -1) {
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} else if (tree.slices.capacity() < new_size) {
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std::vector<Slice> new_slices;
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new_slices.reserve(new_size);
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if (LayerIndex dif = tree.first_layer_id - new_begin; dif > 0)
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new_slices.insert(new_slices.end(), dif, {});
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append(new_slices, std::move(tree.slices));
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tree.slices.swap(new_slices);
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} else if (LayerIndex dif = tree.first_layer_id - new_begin; dif > 0)
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tree.slices.insert(tree.slices.begin(), tree.first_layer_id - new_begin, {});
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tree.slices.insert(tree.slices.end(), new_size - tree.slices.size(), {});
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layer_begin -= LayerIndex(num_empty);
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for (LayerIndex i = layer_begin; i != layer_end; ++ i)
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if (Polygons &src = slices[i - layer_begin]; ! src.empty()) {
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Slice &dst = tree.slices[i - new_begin];
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if (++ dst.num_branches > 1)
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append(dst.polygons, std::move(src));
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else
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dst.polygons = std::move(std::move(src));
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||||||
|
}
|
||||||
|
tree.first_layer_id = new_begin;
|
||||||
|
}
|
||||||
|
}
|
||||||
|
});
|
||||||
|
|
||||||
|
tbb::parallel_for(tbb::blocked_range<size_t>(0, trees.size()),
|
||||||
|
[&trees, &throw_on_cancel](const tbb::blocked_range<size_t> &range) {
|
||||||
|
for (size_t tree_id = range.begin(); tree_id < range.end(); ++ tree_id) {
|
||||||
|
Tree &tree = trees[tree_id];
|
||||||
|
for (Slice &slice : tree.slices)
|
||||||
|
if (slice.num_branches > 1) {
|
||||||
|
slice.polygons = union_(slice.polygons);
|
||||||
|
slice.num_branches = 1;
|
||||||
}
|
}
|
||||||
throw_on_cancel();
|
throw_on_cancel();
|
||||||
}
|
}
|
||||||
}
|
|
||||||
return cummulative_mesh;
|
|
||||||
}
|
|
||||||
|
|
||||||
// Organic specific: Slice the cummulative mesh produced by draw_branches().
|
|
||||||
static void slice_branches(
|
|
||||||
PrintObject &print_object,
|
|
||||||
const TreeModelVolumes &volumes,
|
|
||||||
const TreeSupportSettings &config,
|
|
||||||
const std::vector<Polygons> &overhangs,
|
|
||||||
std::vector<SupportElements> &move_bounds,
|
|
||||||
const indexed_triangle_set &cummulative_mesh,
|
|
||||||
|
|
||||||
SupportGeneratorLayersPtr &bottom_contacts,
|
|
||||||
SupportGeneratorLayersPtr &top_contacts,
|
|
||||||
SupportGeneratorLayersPtr &intermediate_layers,
|
|
||||||
SupportGeneratorLayerStorage &layer_storage,
|
|
||||||
|
|
||||||
std::function<void()> throw_on_cancel)
|
|
||||||
{
|
|
||||||
const SlicingParameters &slicing_params = print_object.slicing_parameters();
|
|
||||||
std::vector<float> slice_z;
|
|
||||||
for (size_t layer_idx = 0; layer_idx < move_bounds.size(); ++ layer_idx) {
|
|
||||||
const double print_z = layer_z(print_object.slicing_parameters(), config, layer_idx);
|
|
||||||
const double bottom_z = layer_idx > 0 ? layer_z(print_object.slicing_parameters(), config, layer_idx - 1) : 0.;
|
|
||||||
slice_z.emplace_back(float(0.5 * (bottom_z + print_z)));
|
|
||||||
}
|
|
||||||
// Remove the trailing slices.
|
|
||||||
while (! slice_z.empty())
|
|
||||||
if (move_bounds[slice_z.size() - 1].empty())
|
|
||||||
slice_z.pop_back();
|
|
||||||
else
|
|
||||||
break;
|
|
||||||
|
|
||||||
#if 0
|
|
||||||
its_write_obj(cummulative_mesh, "d:\\temp\\meshes\\tree.obj");
|
|
||||||
#endif
|
|
||||||
|
|
||||||
MeshSlicingParamsEx params;
|
|
||||||
params.closing_radius = float(print_object.config().slice_closing_radius.value);
|
|
||||||
params.mode = MeshSlicingParams::SlicingMode::Positive;
|
|
||||||
std::vector<ExPolygons> slices = slice_mesh_ex(cummulative_mesh, slice_z, params, throw_on_cancel);
|
|
||||||
// Trim the slices.
|
|
||||||
std::vector<Polygons> support_layer_storage(move_bounds.size());
|
|
||||||
tbb::parallel_for(tbb::blocked_range<size_t>(0, slices.size()),
|
|
||||||
[&](const tbb::blocked_range<size_t> &range) {
|
|
||||||
for (size_t layer_idx = range.begin(); layer_idx < range.end(); ++layer_idx)
|
|
||||||
if (ExPolygons &src = slices[layer_idx]; ! src.empty())
|
|
||||||
support_layer_storage[layer_idx] = diff_clipped(to_polygons(std::move(src)), volumes.getCollision(0, layer_idx, true));
|
|
||||||
});
|
});
|
||||||
|
|
||||||
std::vector<Polygons> support_roof_storage(move_bounds.size());
|
size_t num_layers = 0;
|
||||||
finalize_interface_and_support_areas(print_object, volumes, config, overhangs, support_layer_storage, support_roof_storage,
|
for (Tree &tree : trees)
|
||||||
bottom_contacts, top_contacts, intermediate_layers, layer_storage, throw_on_cancel);
|
if (tree.first_layer_id >= 0)
|
||||||
|
num_layers = std::max(num_layers, size_t(tree.first_layer_id + tree.slices.size()));
|
||||||
|
|
||||||
|
std::vector<Slice> slices(num_layers, Slice{});
|
||||||
|
for (Tree &tree : trees)
|
||||||
|
if (tree.first_layer_id >= 0) {
|
||||||
|
for (LayerIndex i = tree.first_layer_id; i != tree.first_layer_id + LayerIndex(tree.slices.size()); ++ i)
|
||||||
|
if (Slice &src = tree.slices[i - tree.first_layer_id]; ! src.polygons.empty()) {
|
||||||
|
Slice &dst = slices[i];
|
||||||
|
if (++ dst.num_branches > 1)
|
||||||
|
append(dst.polygons, std::move(src.polygons));
|
||||||
|
else
|
||||||
|
dst.polygons = std::move(src.polygons);
|
||||||
|
}
|
||||||
|
}
|
||||||
|
|
||||||
|
std::vector<Polygons> support_layer_storage(move_bounds.size());
|
||||||
|
tbb::parallel_for(tbb::blocked_range<size_t>(0, std::min(move_bounds.size(), slices.size())),
|
||||||
|
[&slices, &support_layer_storage, &throw_on_cancel](const tbb::blocked_range<size_t> &range) {
|
||||||
|
for (size_t slice_id = range.begin(); slice_id < range.end(); ++ slice_id) {
|
||||||
|
Slice &slice = slices[slice_id];
|
||||||
|
support_layer_storage[slice_id] = slice.num_branches > 1 ? union_(slice.polygons) : std::move(slice.polygons);
|
||||||
|
throw_on_cancel();
|
||||||
|
}
|
||||||
|
});
|
||||||
|
|
||||||
|
//FIXME simplify!
|
||||||
|
return support_layer_storage;
|
||||||
}
|
}
|
||||||
|
|
||||||
/*!
|
/*!
|
||||||
@ -4413,10 +4483,9 @@ static void generate_support_areas(Print &print, const BuildVolume &build_volume
|
|||||||
bottom_contacts, top_contacts, intermediate_layers, layer_storage, throw_on_cancel);
|
bottom_contacts, top_contacts, intermediate_layers, layer_storage, throw_on_cancel);
|
||||||
else {
|
else {
|
||||||
assert(print_object.config().support_material_style == smsOrganic);
|
assert(print_object.config().support_material_style == smsOrganic);
|
||||||
indexed_triangle_set branches = draw_branches(*print.get_object(processing.second.front()), volumes, config, move_bounds, throw_on_cancel);
|
std::vector<Polygons> support_layer_storage = draw_branches(*print.get_object(processing.second.front()), volumes, config, move_bounds, throw_on_cancel);
|
||||||
// Reduce memory footprint. After this point only slice_branches() will use volumes and from that only collisions with zero radius will be used.
|
std::vector<Polygons> support_roof_storage(support_layer_storage.size());
|
||||||
volumes.clear_all_but_object_collision();
|
finalize_interface_and_support_areas(print_object, volumes, config, overhangs, support_layer_storage, support_roof_storage,
|
||||||
slice_branches(*print.get_object(processing.second.front()), volumes, config, overhangs, move_bounds, branches,
|
|
||||||
bottom_contacts, top_contacts, intermediate_layers, layer_storage, throw_on_cancel);
|
bottom_contacts, top_contacts, intermediate_layers, layer_storage, throw_on_cancel);
|
||||||
}
|
}
|
||||||
|
|
||||||
|
Loading…
Reference in New Issue
Block a user