diff options
Diffstat (limited to 'source/blender/geometry')
-rw-r--r-- | source/blender/geometry/CMakeLists.txt | 2 | ||||
-rw-r--r-- | source/blender/geometry/GEO_subdivide_curves.hh | 26 | ||||
-rw-r--r-- | source/blender/geometry/intern/subdivide_curves.cc | 486 |
3 files changed, 514 insertions, 0 deletions
diff --git a/source/blender/geometry/CMakeLists.txt b/source/blender/geometry/CMakeLists.txt index 21b2071d0e6..df66a806c16 100644 --- a/source/blender/geometry/CMakeLists.txt +++ b/source/blender/geometry/CMakeLists.txt @@ -25,6 +25,7 @@ set(SRC intern/resample_curves.cc intern/reverse_uv_sampler.cc intern/set_curve_type.cc + intern/subdivide_curves.cc intern/uv_parametrizer.c GEO_add_curves_on_mesh.hh @@ -37,6 +38,7 @@ set(SRC GEO_resample_curves.hh GEO_reverse_uv_sampler.hh GEO_set_curve_type.hh + GEO_subdivide_curves.hh GEO_uv_parametrizer.h ) diff --git a/source/blender/geometry/GEO_subdivide_curves.hh b/source/blender/geometry/GEO_subdivide_curves.hh new file mode 100644 index 00000000000..4f671467b24 --- /dev/null +++ b/source/blender/geometry/GEO_subdivide_curves.hh @@ -0,0 +1,26 @@ +/* SPDX-License-Identifier: GPL-2.0-or-later */ + +#pragma once + +#include "BLI_function_ref.hh" +#include "BLI_index_mask.hh" + +#include "BKE_curves.hh" + +struct CurveComponent; + +namespace blender::geometry { + +/** + * Add more points along each segment, with the amount of points to add in each segment described + * by the #cuts input. The new points are equidistant in parameter space, but not in the actual + * distances. + * + * \param selection: A selection of curves to consider when subdividing. + */ +Curves *subdivide_curves(const CurveComponent &src_component, + const bke::CurvesGeometry &src_curves, + IndexMask selection, + const VArray<int> &cuts); + +} // namespace blender::geometry diff --git a/source/blender/geometry/intern/subdivide_curves.cc b/source/blender/geometry/intern/subdivide_curves.cc new file mode 100644 index 00000000000..4fb21e53013 --- /dev/null +++ b/source/blender/geometry/intern/subdivide_curves.cc @@ -0,0 +1,486 @@ +/* SPDX-License-Identifier: GPL-2.0-or-later */ + +#include "BKE_attribute_math.hh" +#include "BKE_curves.hh" +#include "BKE_curves_utils.hh" +#include "BKE_geometry_set.hh" + +#include "BLI_task.hh" + +#include "GEO_subdivide_curves.hh" + +namespace blender::geometry { + +/** + * \warning Only the curve domain of the input is copied, so the result is invalid! + */ +static Curves *create_result_curves(const bke::CurvesGeometry &src_curves) +{ + Curves *dst_curves_id = bke::curves_new_nomain(0, src_curves.curves_num()); + bke::CurvesGeometry &dst_curves = bke::CurvesGeometry::wrap(dst_curves_id->geometry); + CurveComponent dst_component; + dst_component.replace(dst_curves_id, GeometryOwnershipType::Editable); + /* Directly copy curve attributes, since they stay the same. */ + CustomData_copy(&src_curves.curve_data, + &dst_curves.curve_data, + CD_MASK_ALL, + CD_DUPLICATE, + src_curves.curves_num()); + dst_curves.runtime->type_counts = src_curves.runtime->type_counts; + + return dst_curves_id; +} + +/** + * Return a range used to retrieve values from an array of values stored per point, but with an + * extra element at the end of each curve. This is useful for offsets within curves, where it is + * convenient to store the first 0 and have the last offset be the total result curve size. + */ +static IndexRange curve_dst_offsets(const IndexRange points, const int curve_index) +{ + return {curve_index + points.start(), points.size() + 1}; +} + +static void calculate_result_offsets(const bke::CurvesGeometry &src_curves, + const IndexMask selection, + const Span<IndexRange> unselected_ranges, + const VArray<int> &cuts, + const Span<bool> cyclic, + MutableSpan<int> dst_curve_offsets, + MutableSpan<int> dst_point_offsets) +{ + /* Fill the array with each curve's point count, then accumulate them to the offsets. */ + bke::curves::fill_curve_counts(src_curves, unselected_ranges, dst_curve_offsets); + threading::parallel_for(selection.index_range(), 1024, [&](IndexRange range) { + for (const int curve_i : selection.slice(range)) { + const IndexRange src_points = src_curves.points_for_curve(curve_i); + const IndexRange src_segments = curve_dst_offsets(src_points, curve_i); + + MutableSpan<int> point_offsets = dst_point_offsets.slice(src_segments); + + MutableSpan<int> point_counts = point_offsets.drop_back(1); + cuts.materialize_compressed(src_points, point_counts); + for (int &count : point_counts) { + /* Make sure the number of cuts is greater than zero and add one for the existing point. */ + count = std::max(count, 0) + 1; + } + if (!cyclic[curve_i]) { + /* The last point only has a segment to be subdivided if the curve isn't cyclic. */ + point_counts.last() = 1; + } + + bke::curves::accumulate_counts_to_offsets(point_offsets); + dst_curve_offsets[curve_i] = point_offsets.last(); + } + }); + bke::curves::accumulate_counts_to_offsets(dst_curve_offsets); +} + +struct AttributeTransferData { + /* Expect that if an attribute exists, it is stored as a contiguous array internally anyway. */ + GVArraySpan src; + bke::OutputAttribute dst; +}; + +static Vector<AttributeTransferData> retrieve_point_attributes(const CurveComponent &src_component, + CurveComponent &dst_component, + const Set<std::string> &skip = {}) +{ + Vector<AttributeTransferData> attributes; + src_component.attribute_foreach( + [&](const bke::AttributeIDRef &id, const AttributeMetaData meta_data) { + if (meta_data.domain != ATTR_DOMAIN_POINT) { + /* Curve domain attributes are all copied directly to the result in one step. */ + return true; + } + if (id.is_named() && skip.contains(id.name())) { + return true; + } + + GVArray src = src_component.attribute_try_get_for_read(id, ATTR_DOMAIN_POINT); + BLI_assert(src); + bke::OutputAttribute dst = dst_component.attribute_try_get_for_output_only( + id, ATTR_DOMAIN_POINT, meta_data.data_type); + BLI_assert(dst); + attributes.append({std::move(src), std::move(dst)}); + + return true; + }); + return attributes; +} + +template<typename T> +static inline void linear_interpolation(const T &a, const T &b, MutableSpan<T> dst) +{ + dst.first() = a; + const float step = 1.0f / dst.size(); + for (const int i : dst.index_range().drop_front(1)) { + dst[i] = attribute_math::mix2(i * step, a, b); + } +} + +template<typename T> +static void subdivide_attribute_linear(const bke::CurvesGeometry &src_curves, + const bke::CurvesGeometry &dst_curves, + const IndexMask selection, + const Span<int> point_offsets, + const Span<T> src, + MutableSpan<T> dst) +{ + threading::parallel_for(selection.index_range(), 512, [&](IndexRange selection_range) { + for (const int curve_i : selection.slice(selection_range)) { + const IndexRange src_points = src_curves.points_for_curve(curve_i); + const IndexRange src_segments = curve_dst_offsets(src_points, curve_i); + const Span<int> offsets = point_offsets.slice(src_segments); + + const IndexRange dst_points = dst_curves.points_for_curve(curve_i); + const Span<T> curve_src = src.slice(src_points); + MutableSpan<T> curve_dst = dst.slice(dst_points); + + threading::parallel_for(curve_src.index_range().drop_back(1), 1024, [&](IndexRange range) { + for (const int i : range) { + const IndexRange segment_points = bke::offsets_to_range(offsets, i); + linear_interpolation(curve_src[i], curve_src[i + 1], curve_dst.slice(segment_points)); + } + }); + + const IndexRange dst_last_segment = bke::offsets_to_range(offsets, src_points.size() - 1); + linear_interpolation(curve_src.last(), curve_src.first(), dst.slice(dst_last_segment)); + } + }); +} + +static void subdivide_attribute_linear(const bke::CurvesGeometry &src_curves, + const bke::CurvesGeometry &dst_curves, + const IndexMask selection, + const Span<int> point_offsets, + const GSpan src, + GMutableSpan dst) +{ + attribute_math::convert_to_static_type(dst.type(), [&](auto dummy) { + using T = decltype(dummy); + subdivide_attribute_linear( + src_curves, dst_curves, selection, point_offsets, src.typed<T>(), dst.typed<T>()); + }); +} + +template<typename T> +static void subdivide_attribute_catmull_rom(const bke::CurvesGeometry &src_curves, + const bke::CurvesGeometry &dst_curves, + const IndexMask selection, + const Span<int> point_offsets, + const Span<bool> cyclic, + const Span<T> src, + MutableSpan<T> dst) +{ + threading::parallel_for(selection.index_range(), 512, [&](IndexRange selection_range) { + for (const int curve_i : selection.slice(selection_range)) { + const IndexRange src_points = src_curves.points_for_curve(curve_i); + const IndexRange src_segments = curve_dst_offsets(src_points, curve_i); + const IndexRange dst_points = dst_curves.points_for_curve(curve_i); + + bke::curves::catmull_rom::interpolate_to_evaluated(src.slice(src_points), + cyclic[curve_i], + point_offsets.slice(src_segments), + dst.slice(dst_points)); + } + }); +} + +static void subdivide_attribute_catmull_rom(const bke::CurvesGeometry &src_curves, + const bke::CurvesGeometry &dst_curves, + const IndexMask selection, + const Span<int> point_offsets, + const Span<bool> cyclic, + const GSpan src, + GMutableSpan dst) +{ + attribute_math::convert_to_static_type(dst.type(), [&](auto dummy) { + using T = decltype(dummy); + subdivide_attribute_catmull_rom( + src_curves, dst_curves, selection, point_offsets, cyclic, src.typed<T>(), dst.typed<T>()); + }); +} + +static void subdivide_bezier_segment(const float3 &position_prev, + const float3 &handle_prev, + const float3 &handle_next, + const float3 &position_next, + const HandleType type_prev, + const HandleType type_next, + const IndexRange segment_points, + MutableSpan<float3> dst_positions, + MutableSpan<float3> dst_handles_l, + MutableSpan<float3> dst_handles_r, + MutableSpan<int8_t> dst_types_l, + MutableSpan<int8_t> dst_types_r, + const bool is_last_cyclic_segment) +{ + auto fill_segment_handle_types = [&](const HandleType type) { + /* Also change the left handle of the control point following the segment's points. And don't + * change the left handle of the first point, since that is part of the previous segment. */ + dst_types_l.slice(segment_points.shift(1)).fill(type); + dst_types_r.slice(segment_points).fill(type); + }; + + if (bke::curves::bezier::segment_is_vector(type_prev, type_next)) { + linear_interpolation(position_prev, position_next, dst_positions.slice(segment_points)); + fill_segment_handle_types(BEZIER_HANDLE_VECTOR); + } + else { + /* The first point in the segment is always copied. */ + dst_positions[segment_points.first()] = position_prev; + + /* Non-vector segments in the result curve are given free handles. This could possibly be + * improved with another pass that sets handles to aligned where possible, but currently that + * does not provide much benefit for the increased complexity. */ + fill_segment_handle_types(BEZIER_HANDLE_FREE); + + /* In order to generate a Bezier curve with the same shape as the input curve, apply the + * De Casteljau algorithm iteratively for the provided number of cuts, constantly updating the + * previous result point's right handle and the left handle at the end of the segment. */ + float3 segment_start = position_prev; + float3 segment_handle_prev = handle_prev; + float3 segment_handle_next = handle_next; + const float3 segment_end = position_next; + + for (const int i : IndexRange(segment_points.size() - 1)) { + const float parameter = 1.0f / (segment_points.size() - i); + const int point_i = segment_points[i]; + bke::curves::bezier::Insertion insert = bke::curves::bezier::insert( + segment_start, segment_handle_prev, segment_handle_next, segment_end, parameter); + + /* Copy relevant temporary data to the result. */ + dst_handles_r[point_i] = insert.handle_prev; + dst_handles_l[point_i + 1] = insert.left_handle; + dst_positions[point_i + 1] = insert.position; + + /* Update the segment to prepare it for the next subdivision. */ + segment_start = insert.position; + segment_handle_prev = insert.right_handle; + segment_handle_next = insert.handle_next; + } + + /* Copy the handles for the last segment from the working variables. */ + const int i_segment_last = is_last_cyclic_segment ? 0 : segment_points.one_after_last(); + dst_handles_r[segment_points.last()] = segment_handle_prev; + dst_handles_l[i_segment_last] = segment_handle_next; + } +} + +static void subdivide_bezier_positions(const Span<float3> src_positions, + const Span<int8_t> src_types_l, + const Span<int8_t> src_types_r, + const Span<float3> src_handles_l, + const Span<float3> src_handles_r, + const Span<int> evaluated_offsets, + const bool cyclic, + MutableSpan<float3> dst_positions, + MutableSpan<int8_t> dst_types_l, + MutableSpan<int8_t> dst_types_r, + MutableSpan<float3> dst_handles_l, + MutableSpan<float3> dst_handles_r) +{ + threading::parallel_for(src_positions.index_range().drop_back(1), 512, [&](IndexRange range) { + for (const int segment_i : range) { + const IndexRange segment = bke::offsets_to_range(evaluated_offsets, segment_i); + subdivide_bezier_segment(src_positions[segment_i], + src_handles_r[segment_i], + src_handles_l[segment_i + 1], + src_positions[segment_i + 1], + HandleType(src_types_r[segment_i]), + HandleType(src_types_l[segment_i + 1]), + segment, + dst_positions, + dst_handles_l, + dst_handles_r, + dst_types_l, + dst_types_r, + false); + } + }); + + if (cyclic) { + const int last_index = src_positions.index_range().last(); + const IndexRange segment = bke::offsets_to_range(evaluated_offsets, last_index); + const HandleType type_prev = HandleType(src_types_r.last()); + const HandleType type_next = HandleType(src_types_l.first()); + subdivide_bezier_segment(src_positions.last(), + src_handles_r.last(), + src_handles_l.first(), + src_positions.first(), + type_prev, + type_next, + segment, + dst_positions, + dst_handles_l, + dst_handles_r, + dst_types_l, + dst_types_r, + true); + + if (bke::curves::bezier::segment_is_vector(type_prev, type_next)) { + dst_types_l.first() = BEZIER_HANDLE_VECTOR; + dst_types_r.last() = BEZIER_HANDLE_VECTOR; + } + else { + dst_types_l.first() = BEZIER_HANDLE_FREE; + dst_types_r.last() = BEZIER_HANDLE_FREE; + } + } + else { + dst_positions.last() = src_positions.last(); + dst_types_l.first() = src_types_l.first(); + dst_types_r.last() = src_types_r.last(); + dst_handles_l.first() = src_handles_l.first(); + dst_handles_r.last() = src_handles_r.last(); + } + + /* TODO: It would be possible to avoid calling this for all segments besides vector segments. */ + bke::curves::bezier::calculate_auto_handles( + cyclic, dst_types_l, dst_types_r, dst_positions, dst_handles_l, dst_handles_r); +} + +Curves *subdivide_curves(const CurveComponent &src_component, + const bke::CurvesGeometry &src_curves, + const IndexMask selection, + const VArray<int> &cuts) +{ + const Vector<IndexRange> unselected_ranges = selection.extract_ranges_invert( + src_curves.curves_range()); + + /* Cyclic is accessed a lot, it's probably worth it to make sure it's a span. */ + const VArraySpan<bool> cyclic{src_curves.cyclic()}; + + Curves *dst_curves_id = create_result_curves(src_curves); + bke::CurvesGeometry &dst_curves = bke::CurvesGeometry::wrap(dst_curves_id->geometry); + CurveComponent dst_component; + dst_component.replace(dst_curves_id, GeometryOwnershipType::Editable); + + /* For each point, this contains the point offset in the corresponding result curve, + * starting at zero. For example for two curves with four points each, the values might + * look like this: + * + * | | Curve 0 | Curve 1 | + * | ------------------- |---|---|---|---|---|---|---|---|---|----| + * | Cuts | 0 | 3 | 0 | 0 | - | 2 | 0 | 0 | 4 | - | + * | New Point Count | 1 | 4 | 1 | 1 | - | 3 | 1 | 1 | 5 | - | + * | Accumulated Offsets | 0 | 1 | 5 | 6 | 7 | 0 | 3 | 4 | 5 | 10 | + * + * Storing the leading zero is unnecessary but makes the array a bit simpler to use by avoiding + * a check for the first segment, and because some existing utilities also use leading zeros. */ + Array<int> dst_point_offsets(src_curves.points_num() + src_curves.curves_num()); +#ifdef DEBUG + dst_point_offsets.fill(-1); +#endif + calculate_result_offsets(src_curves, + selection, + unselected_ranges, + cuts, + cyclic, + dst_curves.offsets_for_write(), + dst_point_offsets); + const Span<int> point_offsets = dst_point_offsets.as_span(); + + dst_curves.resize(dst_curves.offsets().last(), dst_curves.curves_num()); + + auto subdivide_catmull_rom = [&](IndexMask selection) { + for (auto &attribute : retrieve_point_attributes(src_component, dst_component)) { + subdivide_attribute_catmull_rom(src_curves, + dst_curves, + selection, + point_offsets, + cyclic, + attribute.src, + attribute.dst.as_span()); + attribute.dst.save(); + } + }; + + auto subdivide_poly = [&](IndexMask selection) { + for (auto &attribute : retrieve_point_attributes(src_component, dst_component)) { + subdivide_attribute_linear(src_curves, + dst_curves, + selection, + point_offsets, + attribute.src, + attribute.dst.as_span()); + attribute.dst.save(); + } + }; + + auto subdivide_bezier = [&](IndexMask selection) { + const Span<float3> src_positions = src_curves.positions(); + const VArraySpan<int8_t> src_types_l{src_curves.handle_types_left()}; + const VArraySpan<int8_t> src_types_r{src_curves.handle_types_right()}; + const Span<float3> src_handles_l = src_curves.handle_positions_left(); + const Span<float3> src_handles_r = src_curves.handle_positions_right(); + + MutableSpan<float3> dst_positions = dst_curves.positions_for_write(); + MutableSpan<int8_t> dst_types_l = dst_curves.handle_types_left_for_write(); + MutableSpan<int8_t> dst_types_r = dst_curves.handle_types_right_for_write(); + MutableSpan<float3> dst_handles_l = dst_curves.handle_positions_left_for_write(); + MutableSpan<float3> dst_handles_r = dst_curves.handle_positions_right_for_write(); + + threading::parallel_for(selection.index_range(), 512, [&](IndexRange range) { + for (const int curve_i : selection.slice(range)) { + const IndexRange src_points = src_curves.points_for_curve(curve_i); + const IndexRange src_segments = curve_dst_offsets(src_points, curve_i); + + const IndexRange dst_points = dst_curves.points_for_curve(curve_i); + subdivide_bezier_positions(src_positions.slice(src_points), + src_types_l.slice(src_points), + src_types_r.slice(src_points), + src_handles_l.slice(src_points), + src_handles_r.slice(src_points), + point_offsets.slice(src_segments), + cyclic[curve_i], + dst_positions.slice(dst_points), + dst_types_l.slice(dst_points), + dst_types_r.slice(dst_points), + dst_handles_l.slice(dst_points), + dst_handles_r.slice(dst_points)); + } + }); + + for (auto &attribute : retrieve_point_attributes(src_component, + dst_component, + {"position", + "handle_type_left", + "handle_type_right", + "handle_right", + "handle_left"})) { + subdivide_attribute_linear(src_curves, + dst_curves, + selection, + point_offsets, + attribute.src, + attribute.dst.as_span()); + attribute.dst.save(); + } + }; + + /* NURBS curves are just treated as poly curves. NURBS subdivision that maintains + * their shape may be possible, but probably wouldn't work with the "cuts" input. */ + auto subdivide_nurbs = subdivide_poly; + + bke::curves::foreach_curve_by_type(src_curves.curve_types(), + src_curves.curve_type_counts(), + selection, + subdivide_catmull_rom, + subdivide_poly, + subdivide_bezier, + subdivide_nurbs); + + if (!unselected_ranges.is_empty()) { + for (auto &attribute : retrieve_point_attributes(src_component, dst_component)) { + bke::curves::copy_point_data( + src_curves, dst_curves, unselected_ranges, attribute.src, attribute.dst.as_span()); + attribute.dst.save(); + } + } + + return dst_curves_id; +} + +} // namespace blender::geometry |