viewport_lib/interaction/select/sub_object.rs
1//! Typed sub-object reference and sub-object selection set.
2//!
3//! [`SubObjectRef`] is the single canonical way to identify a face, vertex,
4//! edge, or point-cloud point relative to its parent object. It is carried
5//! inside [`PickHit::sub_object`](crate::interaction::query::picking::PickHit::sub_object)
6//! and used as the key type in [`SubSelection`].
7//!
8//! [`SubSelection`] is the sub-object counterpart to
9//! [`crate::interaction::select::selection::Selection`]. Typically an app holds both:
10//! `Selection` for which objects are selected, `SubSelection` for which faces
11//! or points within those objects are selected.
12
13use std::collections::HashSet;
14
15use crate::interaction::select::selection::NodeId;
16
17// ---------------------------------------------------------------------------
18// SubObjectRef
19// ---------------------------------------------------------------------------
20
21/// A typed reference to a sub-object within a parent scene object.
22///
23/// Produced by all pick functions when a specific surface feature is hit, and
24/// stored in [`PickHit::sub_object`](crate::interaction::query::picking::PickHit::sub_object).
25///
26/// # Variants
27///
28/// - [`Face`](SubObjectRef::Face) : triangular face, by index in the triangle list.
29/// Index `i` addresses vertices `indices[3i..3i+3]`.
30/// - [`Vertex`](SubObjectRef::Vertex) : mesh vertex, by position in the vertex buffer.
31/// - [`Edge`](SubObjectRef::Edge) : mesh edge (from parry3d `FeatureId::Edge`; rarely
32/// produced by TriMesh ray casts in practice).
33/// - [`Point`](SubObjectRef::Point) : point in a point-cloud object, by index in the
34/// positions slice.
35/// - [`Voxel`](SubObjectRef::Voxel) : voxel in a structured scalar volume.
36/// - [`Cell`](SubObjectRef::Cell) : cell in an unstructured volume mesh (`VolumeMeshData`).
37/// - [`Splat`](SubObjectRef::Splat) : gaussian splat, by index in the splat buffer.
38/// - [`Instance`](SubObjectRef::Instance) : glyph, tensor glyph, or sprite instance,
39/// by instance index.
40/// - [`Segment`](SubObjectRef::Segment) : polyline, tube, or ribbon segment, by index.
41/// - [`Strip`](SubObjectRef::Strip) : connected curve strip within a multi-strip item,
42/// by strip index.
43#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
44#[cfg_attr(feature = "serde", derive(serde::Serialize, serde::Deserialize))]
45#[non_exhaustive]
46pub enum SubObjectRef {
47 /// A triangular face identified by its index in the triangle list.
48 Face(u32),
49 /// A mesh vertex identified by its position in the vertex buffer.
50 Vertex(u32),
51 /// A mesh edge identified by its edge index (`parry3d::shape::FeatureId::Edge`).
52 ///
53 /// Rarely produced in practice; included for completeness.
54 Edge(u32),
55 /// A point within a point-cloud object, by its index in the positions slice.
56 Point(u32),
57 /// A voxel within a ray-marched volume, by its flat grid index.
58 ///
59 /// The flat index encodes `(ix, iy, iz)` as `ix + iy * nx + iz * nx * ny`.
60 /// Recover the 3-D indices using the grid dimensions from
61 /// [`VolumeData`](crate::geometry::marching_cubes::VolumeData).
62 Voxel(u32),
63 /// A cell within an unstructured volume mesh, by its index in
64 /// [`VolumeMeshData::cells`](crate::resources::volume::volume_mesh::VolumeMeshData::cells).
65 ///
66 /// Produced by [`pick_transparent_volume_mesh_cpu`](crate::interaction::query::picking::pick_transparent_volume_mesh_cpu)
67 /// and [`pick_transparent_volume_mesh_rect`](crate::interaction::query::picking::pick_transparent_volume_mesh_rect).
68 Cell(u32),
69 /// A gaussian splat identified by its index in the splat buffer.
70 Splat(u32),
71 /// A glyph, tensor glyph, or sprite instance identified by its instance index.
72 Instance(u32),
73 /// A polyline, tube, or ribbon segment identified by its segment index.
74 Segment(u32),
75 /// A connected curve strip within a multi-strip item, identified by its strip index.
76 Strip(u32),
77}
78
79impl SubObjectRef {
80 /// Returns `true` if this is a [`Face`](SubObjectRef::Face).
81 pub fn is_face(&self) -> bool {
82 matches!(self, Self::Face(_))
83 }
84
85 /// Returns `true` if this is a [`Point`](SubObjectRef::Point).
86 pub fn is_point(&self) -> bool {
87 matches!(self, Self::Point(_))
88 }
89
90 /// Returns `true` if this is a [`Vertex`](SubObjectRef::Vertex).
91 pub fn is_vertex(&self) -> bool {
92 matches!(self, Self::Vertex(_))
93 }
94
95 /// Returns `true` if this is an [`Edge`](SubObjectRef::Edge).
96 pub fn is_edge(&self) -> bool {
97 matches!(self, Self::Edge(_))
98 }
99
100 /// Returns `true` if this is a [`Voxel`](SubObjectRef::Voxel).
101 pub fn is_voxel(&self) -> bool {
102 matches!(self, Self::Voxel(_))
103 }
104
105 /// Returns `true` if this is a [`Cell`](SubObjectRef::Cell).
106 pub fn is_cell(&self) -> bool {
107 matches!(self, Self::Cell(_))
108 }
109
110 /// Returns the raw index regardless of variant.
111 pub fn index(&self) -> u32 {
112 match *self {
113 Self::Face(i)
114 | Self::Vertex(i)
115 | Self::Edge(i)
116 | Self::Point(i)
117 | Self::Voxel(i)
118 | Self::Cell(i)
119 | Self::Splat(i)
120 | Self::Instance(i)
121 | Self::Segment(i)
122 | Self::Strip(i) => i,
123 }
124 }
125
126 /// Convert from a parry3d [`FeatureId`](parry3d::shape::FeatureId).
127 ///
128 /// Returns `None` for `FeatureId::Unknown` (not expected from TriMesh ray casts).
129 pub fn from_feature_id(f: parry3d::shape::FeatureId) -> Option<Self> {
130 match f {
131 parry3d::shape::FeatureId::Face(i) => Some(Self::Face(i)),
132 parry3d::shape::FeatureId::Vertex(i) => Some(Self::Vertex(i)),
133 parry3d::shape::FeatureId::Edge(i) => Some(Self::Edge(i)),
134 _ => None,
135 }
136 }
137}
138
139// ---------------------------------------------------------------------------
140// SubSelection
141// ---------------------------------------------------------------------------
142
143/// A set of selected sub-objects (faces, vertices, edges, or points) across
144/// one or more parent objects.
145///
146/// Parallel to [`crate::interaction::select::selection::Selection`] but operates at
147/// sub-object granularity. Each entry pairs a parent `object_id` with a
148/// [`SubObjectRef`]. No ordering is maintained beyond the tracked `primary`.
149///
150/// # Typical usage
151///
152/// Hold a `SubSelection` alongside a `Selection`. Use `Selection` to track
153/// which objects are selected at object level; use `SubSelection` to track
154/// which specific faces or points within those objects are highlighted.
155///
156/// ```rust,ignore
157/// // On rect-pick:
158/// let rect_result = pick_rect(...);
159/// sub_sel.clear();
160/// sub_sel.extend_from_rect_pick(&rect_result);
161///
162/// // On ray-pick (face highlight):
163/// if let Some(sub) = hit.sub_object {
164/// sub_sel.select_one(hit.id, sub);
165/// }
166/// ```
167#[derive(Debug, Clone, Default)]
168pub struct SubSelection {
169 selected: HashSet<(NodeId, SubObjectRef)>,
170 primary: Option<(NodeId, SubObjectRef)>,
171 version: u64,
172}
173
174impl SubSelection {
175 /// Create an empty sub-selection.
176 pub fn new() -> Self {
177 Self::default()
178 }
179
180 /// Monotonically increasing generation counter.
181 ///
182 /// Incremented by `wrapping_add(1)` on every mutation. Compare against a
183 /// cached value to detect changes without re-hashing.
184 pub fn version(&self) -> u64 {
185 self.version
186 }
187
188 /// Clear and select exactly one sub-object.
189 pub fn select_one(&mut self, object_id: NodeId, sub: SubObjectRef) {
190 self.selected.clear();
191 self.selected.insert((object_id, sub));
192 self.primary = Some((object_id, sub));
193 self.version = self.version.wrapping_add(1);
194 }
195
196 /// Toggle a sub-object in or out of the selection.
197 ///
198 /// If added, it becomes the primary. If removed, primary is cleared or set
199 /// to an arbitrary remaining entry.
200 pub fn toggle(&mut self, object_id: NodeId, sub: SubObjectRef) {
201 let key = (object_id, sub);
202 if self.selected.contains(&key) {
203 self.selected.remove(&key);
204 if self.primary == Some(key) {
205 self.primary = self.selected.iter().next().copied();
206 }
207 } else {
208 self.selected.insert(key);
209 self.primary = Some(key);
210 }
211 self.version = self.version.wrapping_add(1);
212 }
213
214 /// Add a sub-object without clearing others.
215 pub fn add(&mut self, object_id: NodeId, sub: SubObjectRef) {
216 self.selected.insert((object_id, sub));
217 self.primary = Some((object_id, sub));
218 self.version = self.version.wrapping_add(1);
219 }
220
221 /// Remove a sub-object from the selection.
222 pub fn remove(&mut self, object_id: NodeId, sub: SubObjectRef) {
223 let key = (object_id, sub);
224 self.selected.remove(&key);
225 if self.primary == Some(key) {
226 self.primary = self.selected.iter().next().copied();
227 }
228 self.version = self.version.wrapping_add(1);
229 }
230
231 /// Clear the entire sub-selection.
232 pub fn clear(&mut self) {
233 self.selected.clear();
234 self.primary = None;
235 self.version = self.version.wrapping_add(1);
236 }
237
238 /// Extend from an iterator of `(object_id, SubObjectRef)` pairs.
239 ///
240 /// The last pair becomes primary.
241 pub fn extend(&mut self, items: impl IntoIterator<Item = (NodeId, SubObjectRef)>) {
242 let mut last = None;
243 for item in items {
244 self.selected.insert(item);
245 last = Some(item);
246 }
247 if let Some(item) = last {
248 self.primary = Some(item);
249 }
250 self.version = self.version.wrapping_add(1);
251 }
252
253 /// Populate from a [`RectPickResult`](crate::interaction::query::picking::RectPickResult).
254 ///
255 /// Adds all sub-objects from the rect pick without clearing the current
256 /// selection. Call [`clear`](Self::clear) first if you want a fresh selection.
257 pub fn extend_from_rect_pick(
258 &mut self,
259 result: &crate::interaction::query::picking::RectPickResult,
260 ) {
261 for (&object_id, subs) in &result.hits {
262 for &sub in subs {
263 self.selected.insert((object_id, sub));
264 self.primary = Some((object_id, sub));
265 }
266 }
267 self.version = self.version.wrapping_add(1);
268 }
269
270 /// Whether a specific sub-object is selected.
271 pub fn contains(&self, object_id: NodeId, sub: SubObjectRef) -> bool {
272 self.selected.contains(&(object_id, sub))
273 }
274
275 /// The most recently selected `(object_id, SubObjectRef)` pair.
276 pub fn primary(&self) -> Option<(NodeId, SubObjectRef)> {
277 self.primary
278 }
279
280 /// Iterate over all selected `(object_id, SubObjectRef)` pairs.
281 pub fn iter(&self) -> impl Iterator<Item = &(NodeId, SubObjectRef)> {
282 self.selected.iter()
283 }
284
285 /// All sub-object refs for a specific parent object.
286 pub fn for_object(&self, object_id: NodeId) -> impl Iterator<Item = SubObjectRef> + '_ {
287 self.selected
288 .iter()
289 .filter(move |(id, _)| *id == object_id)
290 .map(|(_, sub)| *sub)
291 }
292
293 /// Number of selected sub-objects.
294 pub fn len(&self) -> usize {
295 self.selected.len()
296 }
297
298 /// Whether the sub-selection is empty.
299 pub fn is_empty(&self) -> bool {
300 self.selected.is_empty()
301 }
302
303 /// Count of selected faces across all objects.
304 pub fn face_count(&self) -> usize {
305 self.selected.iter().filter(|(_, s)| s.is_face()).count()
306 }
307
308 /// Count of selected points across all objects.
309 pub fn point_count(&self) -> usize {
310 self.selected.iter().filter(|(_, s)| s.is_point()).count()
311 }
312
313 /// Count of selected vertices across all objects.
314 pub fn vertex_count(&self) -> usize {
315 self.selected.iter().filter(|(_, s)| s.is_vertex()).count()
316 }
317
318 /// Count of selected voxels across all objects.
319 pub fn voxel_count(&self) -> usize {
320 self.selected.iter().filter(|(_, s)| s.is_voxel()).count()
321 }
322
323 /// Count of selected cells across all objects.
324 pub fn cell_count(&self) -> usize {
325 self.selected.iter().filter(|(_, s)| s.is_cell()).count()
326 }
327}
328
329// ---------------------------------------------------------------------------
330// SubSelectionRef
331// ---------------------------------------------------------------------------
332
333/// Geometry info needed to decode a [`SubObjectRef::Voxel`] flat index into
334/// world-space AABB corners for highlight rendering.
335///
336/// Pass one entry per volume object via [`SubSelectionRef::with_voxels`].
337pub struct VolumeSelectionInfo {
338 /// Grid dimensions `[nx, ny, nz]`: same as [`VolumeData::dims`].
339 pub dims: [u32; 3],
340 /// Local-space bounding-box minimum corner (matches [`VolumeItem::bbox_min`]).
341 pub bbox_min: [f32; 3],
342 /// Local-space bounding-box maximum corner (matches [`VolumeItem::bbox_max`]).
343 pub bbox_max: [f32; 3],
344 /// World-space transform (matches [`VolumeItem::model`]).
345 pub model: [[f32; 4]; 4],
346}
347
348/// Geometry info needed to highlight [`SubObjectRef::Point`], [`SubObjectRef::Segment`],
349/// and [`SubObjectRef::Strip`] selections on a polyline item.
350///
351/// Pass one entry per polyline object via [`SubSelectionRef::with_polylines`].
352pub struct PolylineSelectionInfo {
353 /// World-space vertex positions. Each entry is one polyline node.
354 pub positions: Vec<[f32; 3]>,
355 /// Strip lengths. Same encoding as [`PolylineItem::strip_lengths`](crate::renderer::types::items::PolylineItem::strip_lengths):
356 /// each entry is the number of nodes in that strip. If empty, all positions
357 /// belong to a single strip.
358 pub strip_lengths: Vec<u32>,
359}
360
361/// Geometry info needed to highlight a [`SubObjectRef::Cell`] selection.
362///
363/// Contains the vertex positions and cell connectivity from the host's
364/// [`VolumeMeshData`](crate::resources::volume::volume_mesh::VolumeMeshData). Pass one
365/// entry per volume mesh object via [`SubSelectionRef::with_cells`].
366pub struct CellSelectionInfo {
367 /// World-space vertex positions. Indexed by cell connectivity entries.
368 pub positions: Vec<[f32; 3]>,
369 /// Cell connectivity. Each entry is `[u32; 8]` with
370 /// `u32::MAX` padding for cells with fewer than 8 vertices (same encoding
371 /// as [`VolumeMeshData::cells`](crate::resources::volume::volume_mesh::VolumeMeshData::cells)).
372 pub cells: Vec<[u32; 8]>,
373}
374
375/// A renderer-owned snapshot of a [`SubSelection`] taken at frame submission time.
376///
377/// Bundles the selection items with the CPU-side mesh and point cloud data the
378/// renderer needs to build highlight geometry. The renderer does not hold a
379/// reference to any app-owned data between frames.
380///
381/// # Usage
382///
383/// ```ignore
384/// fd.interaction.sub_selection = Some(SubSelectionRef::new(
385/// &self.sub_selection,
386/// mesh_lookup,
387/// model_matrices,
388/// point_positions,
389/// ));
390/// ```
391pub struct SubSelectionRef {
392 /// Snapshot of all selected (node_id, sub_object) pairs.
393 pub(crate) items: Vec<(NodeId, SubObjectRef)>,
394 /// CPU-side vertex positions and triangle indices keyed by node id.
395 ///
396 /// Same format as the `mesh_lookup` parameter to
397 /// [`pick_scene_cpu`](crate::interaction::query::picking::pick_scene_cpu):
398 /// the value is `(positions, indices)` where every three consecutive
399 /// indices form one triangle.
400 pub(crate) mesh_lookup: std::collections::HashMap<u64, (Vec<[f32; 3]>, Vec<u32>)>,
401 /// World-space model matrix for each node, keyed by node id.
402 ///
403 /// Used to transform local-space mesh positions into world space when
404 /// building fill and edge geometry. Nodes absent from the map are treated
405 /// as having an identity transform.
406 pub(crate) model_matrices: std::collections::HashMap<u64, glam::Mat4>,
407 /// World-space point cloud positions keyed by node id.
408 ///
409 /// Required for [`SubObjectRef::Point`] highlights. The index carried by
410 /// `Point(i)` addresses `point_positions[node_id][i]`.
411 pub(crate) point_positions: std::collections::HashMap<u64, Vec<[f32; 3]>>,
412 /// Volume geometry info keyed by node id.
413 ///
414 /// Required for [`SubObjectRef::Voxel`] highlights. Each entry provides the
415 /// grid dimensions and bounding box so the renderer can decode flat voxel
416 /// indices into world-space AABB wireframes.
417 pub(crate) voxel_lookup: std::collections::HashMap<u64, VolumeSelectionInfo>,
418 /// Unstructured volume mesh geometry keyed by node id.
419 ///
420 /// Required for [`SubObjectRef::Cell`] highlights. Each entry provides the
421 /// vertex positions and cell connectivity so the renderer can draw edge
422 /// outlines around selected cells.
423 pub(crate) cell_lookup: std::collections::HashMap<u64, CellSelectionInfo>,
424 /// Polyline geometry keyed by node id.
425 ///
426 /// Required for [`SubObjectRef::Point`], [`SubObjectRef::Segment`], and
427 /// [`SubObjectRef::Strip`] highlights on polyline items. Each entry provides
428 /// the positions and strip lengths so the renderer can draw node sprites and
429 /// segment edge lines.
430 pub(crate) polyline_lookup: std::collections::HashMap<u64, PolylineSelectionInfo>,
431 /// Curve-family geometry keyed by node id.
432 ///
433 /// Covers [`StreamtubeItem`](crate::renderer::types::items::StreamtubeItem),
434 /// [`TubeItem`](crate::renderer::types::items::TubeItem), and
435 /// [`RibbonItem`](crate::renderer::types::items::RibbonItem).
436 /// Required for [`SubObjectRef::Segment`] and [`SubObjectRef::Strip`] highlights
437 /// on these types. Uses the same [`PolylineSelectionInfo`] encoding since all
438 /// three share identical `positions` / `strip_lengths` fields.
439 pub(crate) curve_family_lookup: std::collections::HashMap<u64, PolylineSelectionInfo>,
440 /// Version counter copied from the source [`SubSelection::version()`].
441 ///
442 /// The renderer uses this to skip GPU buffer rebuilds when the selection
443 /// has not changed since the previous frame.
444 pub version: u64,
445}
446
447impl SubSelectionRef {
448 /// Create a snapshot from a live [`SubSelection`].
449 ///
450 /// - `mesh_lookup` : CPU positions + indices per node id (same type as the
451 /// `mesh_lookup` argument to the CPU pick functions).
452 /// - `model_matrices` : world transform per node id.
453 /// - `point_positions` : point cloud positions per node id (for
454 /// [`SubObjectRef::Point`] entries).
455 pub fn new(
456 sub_selection: &SubSelection,
457 mesh_lookup: std::collections::HashMap<u64, (Vec<[f32; 3]>, Vec<u32>)>,
458 model_matrices: std::collections::HashMap<u64, glam::Mat4>,
459 point_positions: std::collections::HashMap<u64, Vec<[f32; 3]>>,
460 ) -> Self {
461 Self {
462 items: sub_selection.iter().map(|(n, s)| (*n, *s)).collect(),
463 mesh_lookup,
464 model_matrices,
465 point_positions,
466 voxel_lookup: std::collections::HashMap::new(),
467 cell_lookup: std::collections::HashMap::new(),
468 polyline_lookup: std::collections::HashMap::new(),
469 curve_family_lookup: std::collections::HashMap::new(),
470 version: sub_selection.version(),
471 }
472 }
473
474 /// Attach volume geometry info for [`SubObjectRef::Voxel`] highlight rendering.
475 ///
476 /// `lookup` maps each volume's node id to its [`VolumeSelectionInfo`]. Without
477 /// this, selected voxels are silently skipped during highlight geometry build.
478 pub fn with_voxels(
479 mut self,
480 lookup: std::collections::HashMap<u64, VolumeSelectionInfo>,
481 ) -> Self {
482 self.voxel_lookup = lookup;
483 self
484 }
485
486 /// Attach unstructured volume mesh geometry for [`SubObjectRef::Cell`] highlight rendering.
487 ///
488 /// `lookup` maps each volume mesh's node id to its [`CellSelectionInfo`]. Without
489 /// this, selected cells are silently skipped during highlight geometry build.
490 pub fn with_cells(mut self, lookup: std::collections::HashMap<u64, CellSelectionInfo>) -> Self {
491 self.cell_lookup = lookup;
492 self
493 }
494
495 /// Attach polyline geometry for [`SubObjectRef::Point`], [`SubObjectRef::Segment`],
496 /// and [`SubObjectRef::Strip`] highlight rendering.
497 ///
498 /// `lookup` maps each polyline item's node id to its [`PolylineSelectionInfo`].
499 /// Without this, selected polyline nodes and segments are silently skipped during
500 /// highlight geometry build.
501 pub fn with_polylines(
502 mut self,
503 lookup: std::collections::HashMap<u64, PolylineSelectionInfo>,
504 ) -> Self {
505 self.polyline_lookup = lookup;
506 self
507 }
508
509 /// Attach curve-family geometry for [`SubObjectRef::Segment`] and
510 /// [`SubObjectRef::Strip`] highlight rendering on streamtube, tube, and ribbon items.
511 ///
512 /// `lookup` maps each item's node id to a [`PolylineSelectionInfo`] (same
513 /// `positions` / `strip_lengths` encoding). Without this, selected segments
514 /// and strips on these types are silently skipped during highlight geometry build.
515 pub fn with_curve_families(
516 mut self,
517 lookup: std::collections::HashMap<u64, PolylineSelectionInfo>,
518 ) -> Self {
519 self.curve_family_lookup = lookup;
520 self
521 }
522
523 /// Returns `true` if the snapshot contains no selected sub-objects.
524 pub fn is_empty(&self) -> bool {
525 self.items.is_empty()
526 }
527}
528
529// ---------------------------------------------------------------------------
530// Tests
531// ---------------------------------------------------------------------------
532
533#[cfg(test)]
534mod tests {
535 use super::*;
536 use crate::interaction::query::picking::RectPickResult;
537
538 // --- SubObjectRef ---
539
540 #[test]
541 fn sub_object_ref_kind_checks() {
542 assert!(SubObjectRef::Face(0).is_face());
543 assert!(!SubObjectRef::Face(0).is_point());
544 assert!(!SubObjectRef::Face(0).is_vertex());
545 assert!(!SubObjectRef::Face(0).is_edge());
546
547 assert!(SubObjectRef::Point(1).is_point());
548 assert!(SubObjectRef::Vertex(2).is_vertex());
549 assert!(SubObjectRef::Edge(3).is_edge());
550 }
551
552 #[test]
553 fn sub_object_ref_index() {
554 assert_eq!(SubObjectRef::Face(7).index(), 7);
555 assert_eq!(SubObjectRef::Vertex(42).index(), 42);
556 assert_eq!(SubObjectRef::Edge(0).index(), 0);
557 assert_eq!(SubObjectRef::Point(99).index(), 99);
558 }
559
560 #[test]
561 fn sub_object_ref_from_feature_id() {
562 use parry3d::shape::FeatureId;
563 assert_eq!(
564 SubObjectRef::from_feature_id(FeatureId::Face(3)),
565 Some(SubObjectRef::Face(3))
566 );
567 assert_eq!(
568 SubObjectRef::from_feature_id(FeatureId::Vertex(1)),
569 Some(SubObjectRef::Vertex(1))
570 );
571 assert_eq!(
572 SubObjectRef::from_feature_id(FeatureId::Edge(2)),
573 Some(SubObjectRef::Edge(2))
574 );
575 assert_eq!(SubObjectRef::from_feature_id(FeatureId::Unknown), None);
576 }
577
578 #[test]
579 fn sub_object_ref_hashable() {
580 let mut set = std::collections::HashSet::new();
581 set.insert(SubObjectRef::Face(0));
582 set.insert(SubObjectRef::Face(0)); // duplicate
583 set.insert(SubObjectRef::Face(1));
584 set.insert(SubObjectRef::Point(0)); // same index, different variant
585 assert_eq!(set.len(), 3);
586 }
587
588 // --- SubSelection ---
589
590 #[test]
591 fn sub_selection_select_one_clears_others() {
592 let mut sel = SubSelection::new();
593 sel.add(1, SubObjectRef::Face(0));
594 sel.add(1, SubObjectRef::Face(1));
595 sel.select_one(1, SubObjectRef::Face(5));
596 assert_eq!(sel.len(), 1);
597 assert!(sel.contains(1, SubObjectRef::Face(5)));
598 assert!(!sel.contains(1, SubObjectRef::Face(0)));
599 }
600
601 #[test]
602 fn sub_selection_toggle() {
603 let mut sel = SubSelection::new();
604 sel.toggle(1, SubObjectRef::Face(0));
605 assert!(sel.contains(1, SubObjectRef::Face(0)));
606 sel.toggle(1, SubObjectRef::Face(0));
607 assert!(!sel.contains(1, SubObjectRef::Face(0)));
608 assert!(sel.is_empty());
609 }
610
611 #[test]
612 fn sub_selection_add_preserves_others() {
613 let mut sel = SubSelection::new();
614 sel.add(1, SubObjectRef::Face(0));
615 sel.add(1, SubObjectRef::Face(1));
616 assert_eq!(sel.len(), 2);
617 assert!(sel.contains(1, SubObjectRef::Face(0)));
618 assert!(sel.contains(1, SubObjectRef::Face(1)));
619 }
620
621 #[test]
622 fn sub_selection_remove() {
623 let mut sel = SubSelection::new();
624 sel.add(1, SubObjectRef::Face(0));
625 sel.add(1, SubObjectRef::Face(1));
626 sel.remove(1, SubObjectRef::Face(0));
627 assert!(!sel.contains(1, SubObjectRef::Face(0)));
628 assert_eq!(sel.len(), 1);
629 }
630
631 #[test]
632 fn sub_selection_clear() {
633 let mut sel = SubSelection::new();
634 sel.add(1, SubObjectRef::Face(0));
635 sel.add(2, SubObjectRef::Point(3));
636 sel.clear();
637 assert!(sel.is_empty());
638 assert_eq!(sel.primary(), None);
639 }
640
641 #[test]
642 fn sub_selection_primary_tracks_last() {
643 let mut sel = SubSelection::new();
644 sel.add(1, SubObjectRef::Face(0));
645 assert_eq!(sel.primary(), Some((1, SubObjectRef::Face(0))));
646 sel.add(2, SubObjectRef::Point(5));
647 assert_eq!(sel.primary(), Some((2, SubObjectRef::Point(5))));
648 }
649
650 #[test]
651 fn sub_selection_contains() {
652 let mut sel = SubSelection::new();
653 sel.add(10, SubObjectRef::Face(3));
654 assert!(sel.contains(10, SubObjectRef::Face(3)));
655 assert!(!sel.contains(10, SubObjectRef::Face(4)));
656 assert!(!sel.contains(99, SubObjectRef::Face(3)));
657 }
658
659 #[test]
660 fn sub_selection_for_object() {
661 let mut sel = SubSelection::new();
662 sel.add(1, SubObjectRef::Face(0));
663 sel.add(1, SubObjectRef::Face(1));
664 sel.add(2, SubObjectRef::Face(0));
665 let obj1: Vec<SubObjectRef> = {
666 let mut v: Vec<_> = sel.for_object(1).collect();
667 v.sort_by_key(|s| s.index());
668 v
669 };
670 assert_eq!(obj1, vec![SubObjectRef::Face(0), SubObjectRef::Face(1)]);
671 let obj2: Vec<SubObjectRef> = sel.for_object(2).collect();
672 assert_eq!(obj2, vec![SubObjectRef::Face(0)]);
673 assert_eq!(sel.for_object(99).count(), 0);
674 }
675
676 #[test]
677 fn sub_selection_version_increments() {
678 let mut sel = SubSelection::new();
679 let v0 = sel.version();
680 sel.add(1, SubObjectRef::Face(0));
681 assert!(sel.version() > v0);
682 let v1 = sel.version();
683 sel.clear();
684 assert!(sel.version() > v1);
685 }
686
687 #[test]
688 fn sub_selection_kind_counts() {
689 let mut sel = SubSelection::new();
690 sel.add(1, SubObjectRef::Face(0));
691 sel.add(1, SubObjectRef::Face(1));
692 sel.add(2, SubObjectRef::Point(0));
693 sel.add(3, SubObjectRef::Vertex(0));
694 assert_eq!(sel.face_count(), 2);
695 assert_eq!(sel.point_count(), 1);
696 assert_eq!(sel.vertex_count(), 1);
697 }
698
699 #[test]
700 fn sub_selection_extend() {
701 let mut sel = SubSelection::new();
702 sel.extend([
703 (1, SubObjectRef::Face(0)),
704 (1, SubObjectRef::Face(1)),
705 (2, SubObjectRef::Point(3)),
706 ]);
707 assert_eq!(sel.len(), 3);
708 assert_eq!(sel.primary(), Some((2, SubObjectRef::Point(3))));
709 }
710
711 #[test]
712 fn sub_selection_extend_from_rect_pick() {
713 let mut result = RectPickResult::default();
714 result
715 .hits
716 .insert(10, vec![SubObjectRef::Face(0), SubObjectRef::Face(1)]);
717 result.hits.insert(20, vec![SubObjectRef::Point(5)]);
718
719 let mut sel = SubSelection::new();
720 sel.extend_from_rect_pick(&result);
721
722 assert_eq!(sel.len(), 3);
723 assert!(sel.contains(10, SubObjectRef::Face(0)));
724 assert!(sel.contains(10, SubObjectRef::Face(1)));
725 assert!(sel.contains(20, SubObjectRef::Point(5)));
726 assert_eq!(sel.face_count(), 2);
727 assert_eq!(sel.point_count(), 1);
728 }
729}