diff --git a/src/libslic3r/GCode/SeamPlacerNG.cpp b/src/libslic3r/GCode/SeamPlacerNG.cpp index b6cba310d..b23572eb0 100644 --- a/src/libslic3r/GCode/SeamPlacerNG.cpp +++ b/src/libslic3r/GCode/SeamPlacerNG.cpp @@ -23,74 +23,74 @@ namespace SeamPlacerImpl { class Frame { public: Frame() { - mX = Vec3d(1, 0, 0); - mY = Vec3d(0, 1, 0); - mZ = Vec3d(0, 0, 1); + mX = Vec3f(1, 0, 0); + mY = Vec3f(0, 1, 0); + mZ = Vec3f(0, 0, 1); } - Frame(const Vec3d &x, const Vec3d &y, const Vec3d &z) : + Frame(const Vec3f &x, const Vec3f &y, const Vec3f &z) : mX(x), mY(y), mZ(z) { } - void set_from_z(const Vec3d &z) { + void set_from_z(const Vec3f &z) { mZ = z.normalized(); - Vec3d tmpZ = mZ; - Vec3d tmpX = (std::abs(tmpZ.x()) > 0.99f) ? Vec3d(0, 1, 0) : Vec3d(1, 0, 0); + Vec3f tmpZ = mZ; + Vec3f tmpX = (std::abs(tmpZ.x()) > 0.99f) ? Vec3f(0, 1, 0) : Vec3f(1, 0, 0); mY = (tmpZ.cross(tmpX)).normalized(); mX = mY.cross(tmpZ); } - Vec3d to_world(const Vec3d &a) const { + Vec3f to_world(const Vec3f &a) const { return a.x() * mX + a.y() * mY + a.z() * mZ; } - Vec3d to_local(const Vec3d &a) const { - return Vec3d(mX.dot(a), mY.dot(a), mZ.dot(a)); + Vec3f to_local(const Vec3f &a) const { + return Vec3f(mX.dot(a), mY.dot(a), mZ.dot(a)); } - const Vec3d& binormal() const { + const Vec3f& binormal() const { return mX; } - const Vec3d& tangent() const { + const Vec3f& tangent() const { return mY; } - const Vec3d& normal() const { + const Vec3f& normal() const { return mZ; } private: - Vec3d mX, mY, mZ; + Vec3f mX, mY, mZ; }; -Vec3d sample_sphere_uniform(const Vec2f &samples) { - float term1 = 2.0f * M_PIf32 * samples.x(); +Vec3f sample_sphere_uniform(const Vec2f &samples) { + float term1 = 2.0f * float(PI) * samples.x(); float term2 = 2.0f * sqrt(samples.y() - samples.y() * samples.y()); return {cos(term1) * term2, sin(term1) * term2, 1.0f - 2.0f * samples.y()}; } -Vec3d sample_power_cosine_hemisphere(const Vec2f &samples, float power) { +Vec3f sample_power_cosine_hemisphere(const Vec2f &samples, float power) { float term1 = 2.f * M_PIf32 * samples.x(); float term2 = pow(samples.y(), 1.f / (power + 1.f)); float term3 = sqrt(1.f - term2 * term2); - return Vec3d(cos(term1) * term3, sin(term1) * term3, term2); + return Vec3f(cos(term1) * term3, sin(term1) * term3, term2); } -std::vector raycast_visibility(const AABBTreeIndirect::Tree<3, float> &raycasting_tree, - const indexed_triangle_set &triangles) { +std::vector raycast_visibility(size_t ray_count, const AABBTreeIndirect::Tree<3, float> &raycasting_tree, + const indexed_triangle_set &triangles, float& area_to_consider) { auto bbox = raycasting_tree.node(0).bbox; - Vec3d vision_sphere_center = bbox.center().cast(); - Vec3d side_sizes = bbox.sizes().cast(); + Vec3f vision_sphere_center = bbox.center().cast(); + Vec3f side_sizes = bbox.sizes().cast(); float vision_sphere_raidus = (sqrt(side_sizes.dot(side_sizes)) * 0.55); // 0.5 (half) covers whole object, // 0.05 added to avoid corner cases - double approx_area = 2 * side_sizes.x() * side_sizes.y() + 2 * side_sizes.x() * side_sizes.z() + // very rough approximation of object surface area from its bounding box + float approx_area = 2 * side_sizes.x() * side_sizes.y() + 2 * side_sizes.x() * side_sizes.z() + 2 * side_sizes.y() * side_sizes.z(); - auto considered_hits_area = PI * SeamPlacer::considered_hits_distance * SeamPlacer::considered_hits_distance; - size_t ray_count = SeamPlacer::expected_hits_per_area * (approx_area / considered_hits_area); + area_to_consider = SeamPlacer::expected_hits_per_area * approx_area / ray_count; // Prepare random samples per ray // std::random_device rnd_device; @@ -118,28 +118,29 @@ std::vector raycast_visibility(const AABBTreeIndirect::Tree<3, float> & std::vector { }, [&](tbb::blocked_range r, std::vector init) { for (size_t index = r.begin(); index < r.end(); ++index) { - Vec3d global_ray_dir = sample_sphere_uniform(global_dir_random_samples[index]); - Vec3d ray_origin = (vision_sphere_center - global_ray_dir * vision_sphere_raidus); - Vec3d local_dir = sample_power_cosine_hemisphere(local_dir_random_samples[index], SeamPlacer::cosine_hemisphere_sampling_power); + Vec3f global_ray_dir = sample_sphere_uniform(global_dir_random_samples[index]); + Vec3f ray_origin = (vision_sphere_center - global_ray_dir * vision_sphere_raidus); + Vec3f local_dir = sample_power_cosine_hemisphere(local_dir_random_samples[index], SeamPlacer::cosine_hemisphere_sampling_power); Frame f; f.set_from_z(global_ray_dir); - Vec3d final_ray_dir = (f.to_world(local_dir)); + Vec3f final_ray_dir = (f.to_world(local_dir)); igl::Hit hitpoint; // FIXME: This AABBTTreeIndirect query will not compile for float ray origin and - // direction for some reason - auto hit = AABBTreeIndirect::intersect_ray_first_hit(triangles.vertices, - triangles.indices, raycasting_tree, ray_origin, final_ray_dir, hitpoint); + // direction. + Vec3d ray_origin_d = ray_origin.cast(); + Vec3d final_ray_dir_d = final_ray_dir.cast(); + bool hit = AABBTreeIndirect::intersect_ray_first_hit(triangles.vertices, + triangles.indices, raycasting_tree, ray_origin_d, final_ray_dir_d, hitpoint); if (hit) { auto face = triangles.indices[hitpoint.id]; auto edge1 = triangles.vertices[face[1]] - triangles.vertices[face[0]]; auto edge2 = triangles.vertices[face[2]] - triangles.vertices[face[0]]; - Vec3d hit_pos = (triangles.vertices[face[0]] + edge1 * hitpoint.u + edge2 * hitpoint.v).cast< - double>(); - Vec3d surface_normal = edge1.cross(edge2).cast().normalized(); + Vec3f hit_pos = (triangles.vertices[face[0]] + edge1 * hitpoint.u + edge2 * hitpoint.v); + Vec3f surface_normal = edge1.cross(edge2).normalized(); init.push_back(HitInfo { hit_pos, surface_normal }); } @@ -208,7 +209,7 @@ std::vector calculate_polygon_angles_at_vertices(const Polygon &polygon, const Point v2 = p2 - p1; int64_t dot = int64_t(v1(0)) * int64_t(v2(0)) + int64_t(v1(1)) * int64_t(v2(1)); int64_t cross = int64_t(v1(0)) * int64_t(v2(1)) - int64_t(v1(1)) * int64_t(v2(0)); - float angle = float(atan2(double(cross), double(dot))); + float angle = float(atan2(float(cross), float(dot))); angles[idx_curr] = angle; } @@ -217,7 +218,8 @@ std::vector calculate_polygon_angles_at_vertices(const Polygon &polygon, struct GlobalModelInfo { std::vector geometry_raycast_hits; - KDTreeIndirect<3, coordf_t, HitInfoCoordinateFunctor> raycast_hits_tree; + KDTreeIndirect<3, float, HitInfoCoordinateFunctor> raycast_hits_tree; + float hits_area_to_consider{}; indexed_triangle_set enforcers; indexed_triangle_set blockers; AABBTreeIndirect::Tree<3, float> enforcers_tree; @@ -227,25 +229,25 @@ struct GlobalModelInfo { raycast_hits_tree(HitInfoCoordinateFunctor { &geometry_raycast_hits }) { } - double enforcer_distance_check(const Vec3d &position) const { + float enforcer_distance_check(const Vec3f &position) const { size_t hit_idx_out; - Vec3d closest_vec3d; + Vec3f closest_point; return AABBTreeIndirect::squared_distance_to_indexed_triangle_set(enforcers.vertices, enforcers.indices, - enforcers_tree, position, hit_idx_out, closest_vec3d); + enforcers_tree, position, hit_idx_out, closest_point); } - double blocker_distance_check(const Vec3d &position) const { + float blocker_distance_check(const Vec3f &position) const { size_t hit_idx_out; - Vec3d closest_vec3d; + Vec3f closest_point; return AABBTreeIndirect::squared_distance_to_indexed_triangle_set(blockers.vertices, blockers.indices, - blockers_tree, position, hit_idx_out, closest_vec3d); + blockers_tree, position, hit_idx_out, closest_point); } - double calculate_point_visibility(const Vec3d &position, double max_distance) const { + float calculate_point_visibility(const Vec3f &position, float max_distance) const { auto nearby_points = find_nearby_points(raycast_hits_tree, position, max_distance); - double visibility = 0; + float visibility = 0; for (const auto &hit_point_index : nearby_points) { - double distance = + float distance = (position - geometry_raycast_hits[hit_point_index].m_position).norm(); visibility += max_distance - distance; // The further away from the perimeter point, // the less representative ray hit is @@ -288,7 +290,7 @@ Polygons extract_perimeter_polygons(const Layer *layer) { return polygons; } -void process_perimeter_polygon(const Polygon &orig_polygon, coordf_t z_coord, std::vector &result_vec, +void process_perimeter_polygon(const Polygon &orig_polygon, float z_coord, std::vector &result_vec, const GlobalModelInfo &global_model_info) { Polygon polygon = orig_polygon; polygon.make_counter_clockwise(); @@ -296,14 +298,14 @@ void process_perimeter_polygon(const Polygon &orig_polygon, coordf_t z_coord, st std::vector angles = calculate_polygon_angles_at_vertices(polygon, lengths, SeamPlacer::polygon_angles_arm_distance); - Vec3d last_enforcer_checked_point { 0, 0, -1 }; - double enforcer_dist_sqr = global_model_info.enforcer_distance_check(last_enforcer_checked_point); - Vec3d last_blocker_checked_point { 0, 0, -1 }; - double blocker_dist_sqr = global_model_info.blocker_distance_check(last_blocker_checked_point); + Vec3f last_enforcer_checked_point { 0, 0, -1 }; + float enforcer_dist_sqr = global_model_info.enforcer_distance_check(last_enforcer_checked_point); + Vec3f last_blocker_checked_point { 0, 0, -1 }; + float blocker_dist_sqr = global_model_info.blocker_distance_check(last_blocker_checked_point); for (size_t index = 0; index < polygon.size(); ++index) { - Vec2d unscaled_p = unscale(polygon[index]); - Vec3d unscaled_position = Vec3d { unscaled_p.x(), unscaled_p.y(), z_coord }; + Vec2f unscaled_p = unscale(polygon[index]).cast(); + Vec3f unscaled_position = Vec3f { unscaled_p.x(), unscaled_p.y(), z_coord }; EnforcedBlockedSeamPoint type = EnforcedBlockedSeamPoint::NONE; float ccw_angle = angles[index]; @@ -368,6 +370,7 @@ std::pair find_previous_and_next_perimeter_point(const std::vect return {prev,next}; } +//NOTE: only rough esitmation of overhang distance float calculate_overhang(const SeamCandidate &point, const SeamCandidate &under_a, const SeamCandidate &under_b, const SeamCandidate &under_c) { auto p = Vec2d { point.m_position.x(), point.m_position.y() }; @@ -420,8 +423,10 @@ void gather_global_model_info(GlobalModelInfo &result, const PrintObject *po) { auto raycasting_tree = AABBTreeIndirect::build_aabb_tree_over_indexed_triangle_set(triangle_set.vertices, triangle_set.indices); - result.geometry_raycast_hits = raycast_visibility(raycasting_tree, triangle_set); + float hits_area_to_consider; + result.geometry_raycast_hits = raycast_visibility(SeamPlacer::ray_count, raycasting_tree, triangle_set, hits_area_to_consider); result.raycast_hits_tree.build(result.geometry_raycast_hits.size()); + result.hits_area_to_consider = hits_area_to_consider; BOOST_LOG_TRIVIAL(debug) << "SeamPlacer: build AABB tree for raycasting and gather occlusion info: end"; @@ -531,6 +536,8 @@ void SeamPlacer::calculate_candidates_visibility(const PrintObject *po, const SeamPlacerImpl::GlobalModelInfo &global_model_info) { using namespace SeamPlacerImpl; +float considered_hits_distance = sqrt(global_model_info.hits_area_to_consider / float(PI)); + tbb::parallel_for(tbb::blocked_range(0, m_perimeter_points_per_object[po].size()), [&](tbb::blocked_range r) { for (size_t layer_idx = r.begin(); layer_idx < r.end(); ++layer_idx) { @@ -581,7 +588,7 @@ void SeamPlacer::distribute_seam_positions_for_alignment(const PrintObject *po) m_perimeter_points_per_object[po][layer_idx]; size_t current = 0; while (current < layer_perimeter_points.size()) { - Vec3d seam_position = + Vec3f seam_position = layer_perimeter_points[layer_perimeter_points[current].m_seam_index].m_position; int other_layer_idx_bottom = std::max( @@ -589,10 +596,11 @@ void SeamPlacer::distribute_seam_positions_for_alignment(const PrintObject *po) int other_layer_idx_top = std::min(layer_idx + seam_align_layer_dist, m_perimeter_points_per_object[po].size() - 1); - Vec3d last_point_position = seam_position; + //distribute from current layer upwards + Vec3f last_point_position = seam_position; for (int other_layer_idx = layer_idx + 1; other_layer_idx <= other_layer_idx_top; ++other_layer_idx) { - Vec3d projected_position { last_point_position.x(), last_point_position.y(), po->get_layer(other_layer_idx)->slice_z}; + Vec3f projected_position { last_point_position.x(), last_point_position.y(), float(po->get_layer(other_layer_idx)->slice_z)}; size_t closest_point_index = find_closest_point( *m_perimeter_points_trees_per_object[po][other_layer_idx], projected_position); @@ -604,14 +612,16 @@ void SeamPlacer::distribute_seam_positions_for_alignment(const PrintObject *po) point_ref.m_nearby_seam_points->fetch_add(1, std::memory_order_relaxed); last_point_position = point_ref.m_position; } else { + //break when no close point found break; } } + //distribute downwards last_point_position = seam_position; if (layer_idx > 0) { for (int other_layer_idx = layer_idx - 1; other_layer_idx >= other_layer_idx_bottom; --other_layer_idx) { - Vec3d projected_position { last_point_position.x(), last_point_position.y(), po->get_layer(other_layer_idx)->slice_z}; + Vec3f projected_position { last_point_position.x(), last_point_position.y(), float(po->get_layer(other_layer_idx)->slice_z)}; size_t closest_point_index = find_closest_point( *m_perimeter_points_trees_per_object[po][other_layer_idx], projected_position); @@ -671,6 +681,7 @@ void SeamPlacer::init(const Print &print) { distribute_seam_positions_for_alignment(po); } + //pick seam point tbb::parallel_for(tbb::blocked_range(0, m_perimeter_points_per_object[po].size()), [&](tbb::blocked_range r) { for (size_t layer_idx = r.begin(); layer_idx < r.end(); ++layer_idx) { @@ -703,11 +714,11 @@ void SeamPlacer::place_seam(const PrintObject *po, ExtrusionLoop &loop, coordf_t const Point &fp = loop.first_point(); - auto unscaled_p = unscale(fp); - auto closest_perimeter_point_index = find_closest_point(perimeter_points_tree, - Vec3d { unscaled_p.x(), unscaled_p.y(), unscaled_z }); + Vec2f unscaled_p = unscale(fp).cast(); + size_t closest_perimeter_point_index = find_closest_point(perimeter_points_tree, + Vec3f { unscaled_p.x(), unscaled_p.y(), float(unscaled_z) }); size_t perimeter_seam_index = perimeter_points[closest_perimeter_point_index].m_seam_index; - Vec3d seam_position = perimeter_points[perimeter_seam_index].m_position; + Vec3f seam_position = perimeter_points[perimeter_seam_index].m_position; Point seam_point = scaled(Vec2d { seam_position.x(), seam_position.y() }); @@ -717,7 +728,7 @@ void SeamPlacer::place_seam(const PrintObject *po, ExtrusionLoop &loop, coordf_t loop.split_at(seam_point, true); } -// Disabled debug code, can be used to export debug data into obj files (e.g. point cloud of visibility hits +// Disabled debug code, can be used to export debug data into obj files (e.g. point cloud of visibility hits) #if 0 #include Slic3r::CNumericLocalesSetter locales_setter; diff --git a/src/libslic3r/GCode/SeamPlacerNG.hpp b/src/libslic3r/GCode/SeamPlacerNG.hpp index 057640776..ee85f94ab 100644 --- a/src/libslic3r/GCode/SeamPlacerNG.hpp +++ b/src/libslic3r/GCode/SeamPlacerNG.hpp @@ -35,13 +35,13 @@ enum EnforcedBlockedSeamPoint { }; struct SeamCandidate { - SeamCandidate(const Vec3d &pos, size_t polygon_index_reverse, float ccw_angle, EnforcedBlockedSeamPoint type) : - m_position(pos), m_visibility(0.0), m_overhang(0.0), m_polygon_index_reverse(polygon_index_reverse), m_seam_index( + SeamCandidate(const Vec3f &pos, size_t polygon_index_reverse, float ccw_angle, EnforcedBlockedSeamPoint type) : + m_position(pos), m_visibility(0.0f), m_overhang(0.0f), m_polygon_index_reverse(polygon_index_reverse), m_seam_index( 0), m_ccw_angle( ccw_angle), m_type(type) { m_nearby_seam_points = std::make_unique>(0); } - Vec3d m_position; + Vec3f m_position; float m_visibility; float m_overhang; size_t m_polygon_index_reverse; @@ -52,8 +52,8 @@ struct SeamCandidate { }; struct HitInfo { - Vec3d m_position; - Vec3d m_surface_normal; + Vec3f m_position; + Vec3f m_surface_normal; }; struct SeamCandidateCoordinateFunctor { @@ -80,15 +80,17 @@ struct HitInfoCoordinateFunctor { class SeamPlacer { public: using SeamCandidatesTree = - KDTreeIndirect<3, coordf_t, SeamPlacerImpl::SeamCandidateCoordinateFunctor>; - static constexpr double considered_hits_distance = 4.0; - static constexpr double expected_hits_per_area = 250.0; - static constexpr float cosine_hemisphere_sampling_power = 1.5; - static constexpr float polygon_angles_arm_distance = 0.6; - static constexpr float enforcer_blocker_sqr_distance_tolerance = 0.4; + KDTreeIndirect<3, float, SeamPlacerImpl::SeamCandidateCoordinateFunctor>; + static constexpr float expected_hits_per_area = 100.0f; + static constexpr size_t ray_count = 150000; //NOTE: fixed count of rays is better: + // on small models, the visibility has huge impact and precision is welcomed. + // on large models, it would be very expensive to get similar results, and the effect is arguably less important. + static constexpr float cosine_hemisphere_sampling_power = 1.5f; + static constexpr float polygon_angles_arm_distance = 0.6f; + static constexpr float enforcer_blocker_sqr_distance_tolerance = 0.4f; static constexpr size_t seam_align_iterations = 4; static constexpr size_t seam_align_layer_dist = 30; - static constexpr float seam_align_tolerable_dist = 0.3; + static constexpr float seam_align_tolerable_dist = 0.3f; //perimeter points per object per layer idx, and their corresponding KD trees std::unordered_map>> m_perimeter_points_per_object; std::unordered_map>> m_perimeter_points_trees_per_object;