1use std::ops::Range;
4
5use fixedbitset::FixedBitSet;
6use rustc_hash::FxHashSet;
7
8use fallow_types::discover::FileId;
9
10use super::ModuleGraph;
11use super::types::ModuleNode;
12
13impl ModuleGraph {
14 #[must_use]
27 pub fn find_cycles(&self) -> Vec<Vec<FileId>> {
28 let n = self.modules.len();
29 if n == 0 {
30 return Vec::new();
31 }
32
33 let (all_succs, succ_ranges) = self.build_runtime_successors(n);
34
35 let mut state = SccState::new(n);
36 for start_node in 0..n {
37 if state.indices[start_node] != u32::MAX {
38 continue;
39 }
40 state.run_dfs_from(start_node, &all_succs, &succ_ranges);
41 }
42
43 self.enumerate_cycles_from_sccs(&state.sccs, &all_succs, &succ_ranges)
44 }
45
46 fn build_runtime_successors(&self, n: usize) -> (Vec<usize>, Vec<Range<usize>>) {
49 let mut all_succs: Vec<usize> = Vec::with_capacity(self.edges.len());
50 let mut succ_ranges: Vec<Range<usize>> = Vec::with_capacity(n);
51 let mut seen_set = FxHashSet::default();
52 for module in &self.modules {
53 let start = all_succs.len();
54 seen_set.clear();
55 for edge in &self.edges[module.edge_range.clone()] {
56 if edge.symbols.iter().all(|s| s.is_type_only) {
57 continue;
58 }
59 let target = edge.target.0 as usize;
60 if target < n && seen_set.insert(target) {
61 all_succs.push(target);
62 }
63 }
64 let end = all_succs.len();
65 succ_ranges.push(start..end);
66 }
67 (all_succs, succ_ranges)
68 }
69
70 #[expect(
72 clippy::cast_possible_truncation,
73 reason = "file count is bounded by project size, well under u32::MAX"
74 )]
75 fn enumerate_cycles_from_sccs(
76 &self,
77 sccs: &[Vec<FileId>],
78 all_succs: &[usize],
79 succ_ranges: &[Range<usize>],
80 ) -> Vec<Vec<FileId>> {
81 const MAX_CYCLES_PER_SCC: usize = 20;
82
83 let succs = SuccessorMap {
84 all_succs,
85 succ_ranges,
86 modules: &self.modules,
87 };
88
89 let mut result: Vec<Vec<FileId>> = Vec::new();
90 let mut seen_cycles: FxHashSet<Vec<u32>> = FxHashSet::default();
91
92 for scc in sccs {
93 if scc.len() == 2 {
94 let mut cycle = vec![scc[0].0 as usize, scc[1].0 as usize];
95 if self.modules[cycle[1]].path < self.modules[cycle[0]].path {
96 cycle.swap(0, 1);
97 }
98 let key: Vec<u32> = cycle.iter().map(|&n| n as u32).collect();
99 if seen_cycles.insert(key) {
100 result.push(cycle.into_iter().map(|n| FileId(n as u32)).collect());
101 }
102 continue;
103 }
104
105 let scc_nodes: Vec<usize> = scc.iter().map(|id| id.0 as usize).collect();
106 let elementary = enumerate_elementary_cycles(&scc_nodes, &succs, MAX_CYCLES_PER_SCC);
107
108 for cycle in elementary {
109 let key: Vec<u32> = cycle.iter().map(|&n| n as u32).collect();
110 if seen_cycles.insert(key) {
111 result.push(cycle.into_iter().map(|n| FileId(n as u32)).collect());
112 }
113 }
114 }
115
116 result.sort_by(|a, b| {
117 a.len().cmp(&b.len()).then_with(|| {
118 self.modules[a[0].0 as usize]
119 .path
120 .cmp(&self.modules[b[0].0 as usize].path)
121 })
122 });
123
124 result
125 }
126}
127
128struct SccFrame {
130 node: usize,
131 succ_pos: usize,
132 succ_end: usize,
133}
134
135struct SccState {
137 index_counter: u32,
138 indices: Vec<u32>,
139 lowlinks: Vec<u32>,
140 on_stack: FixedBitSet,
141 stack: Vec<usize>,
142 sccs: Vec<Vec<FileId>>,
143}
144
145impl SccState {
146 fn new(n: usize) -> Self {
147 Self {
148 index_counter: 0,
149 indices: vec![u32::MAX; n],
150 lowlinks: vec![0; n],
151 on_stack: FixedBitSet::with_capacity(n),
152 stack: Vec::new(),
153 sccs: Vec::new(),
154 }
155 }
156
157 fn discover(&mut self, node: usize) {
159 self.indices[node] = self.index_counter;
160 self.lowlinks[node] = self.index_counter;
161 self.index_counter += 1;
162 self.on_stack.insert(node);
163 self.stack.push(node);
164 }
165
166 fn frame_for(node: usize, succ_ranges: &[Range<usize>]) -> SccFrame {
168 let range = &succ_ranges[node];
169 SccFrame {
170 node,
171 succ_pos: range.start,
172 succ_end: range.end,
173 }
174 }
175
176 fn run_dfs_from(&mut self, start: usize, all_succs: &[usize], succ_ranges: &[Range<usize>]) {
179 self.discover(start);
180 let mut dfs_stack: Vec<SccFrame> = vec![Self::frame_for(start, succ_ranges)];
181
182 while let Some(frame) = dfs_stack.last_mut() {
183 if frame.succ_pos < frame.succ_end {
184 if let Some(child) = self.advance_frame(frame, all_succs) {
185 dfs_stack.push(Self::frame_for(child, succ_ranges));
186 }
187 } else {
188 let v = frame.node;
189 let v_lowlink = self.lowlinks[v];
190 dfs_stack.pop();
191 if let Some(parent) = dfs_stack.last() {
192 let pv = parent.node;
193 self.lowlinks[pv] = self.lowlinks[pv].min(v_lowlink);
194 }
195 self.collect_root_scc(v);
196 }
197 }
198 }
199
200 fn advance_frame(&mut self, frame: &mut SccFrame, all_succs: &[usize]) -> Option<usize> {
203 let w = all_succs[frame.succ_pos];
204 frame.succ_pos += 1;
205 if self.indices[w] == u32::MAX {
206 self.discover(w);
207 Some(w)
208 } else {
209 if self.on_stack.contains(w) {
210 let v = frame.node;
211 self.lowlinks[v] = self.lowlinks[v].min(self.indices[w]);
212 }
213 None
214 }
215 }
216
217 #[expect(
220 clippy::cast_possible_truncation,
221 reason = "file count is bounded by project size, well under u32::MAX"
222 )]
223 #[expect(
224 clippy::expect_used,
225 reason = "Tarjan traversal only pops nodes that were pushed onto the SCC stack"
226 )]
227 fn collect_root_scc(&mut self, v: usize) {
228 if self.lowlinks[v] != self.indices[v] {
229 return;
230 }
231 let mut scc = Vec::new();
232 loop {
233 let w = self.stack.pop().expect("SCC stack should not be empty");
234 self.on_stack.set(w, false);
235 scc.push(FileId(w as u32));
236 if w == v {
237 break;
238 }
239 }
240 if scc.len() >= 2 {
241 self.sccs.push(scc);
242 }
243 }
244}
245
246fn canonical_cycle(cycle: &[usize], modules: &[ModuleNode]) -> Vec<usize> {
248 if cycle.is_empty() {
249 return Vec::new();
250 }
251 let min_pos = cycle
252 .iter()
253 .enumerate()
254 .min_by(|(_, a), (_, b)| modules[**a].path.cmp(&modules[**b].path))
255 .map_or(0, |(i, _)| i);
256 let mut result = cycle[min_pos..].to_vec();
257 result.extend_from_slice(&cycle[..min_pos]);
258 result
259}
260
261struct CycleFrame {
262 succ_pos: usize,
263 succ_end: usize,
264}
265
266struct SuccessorMap<'a> {
267 all_succs: &'a [usize],
268 succ_ranges: &'a [Range<usize>],
269 modules: &'a [ModuleNode],
270}
271
272#[expect(
273 clippy::cast_possible_truncation,
274 reason = "file count is bounded by project size, well under u32::MAX"
275)]
276fn try_record_cycle(
277 path: &[usize],
278 modules: &[ModuleNode],
279 seen: &mut FxHashSet<Vec<u32>>,
280 cycles: &mut Vec<Vec<usize>>,
281) {
282 let canonical = canonical_cycle(path, modules);
283 let key: Vec<u32> = canonical.iter().map(|&n| n as u32).collect();
284 if seen.insert(key) {
285 cycles.push(canonical);
286 }
287}
288
289struct DfsCycleInput<'a> {
294 start: usize,
295 depth_limit: usize,
296 scc_set: &'a FxHashSet<usize>,
297 succs: &'a SuccessorMap<'a>,
298 max_cycles: usize,
299 seen: &'a mut FxHashSet<Vec<u32>>,
300 cycles: &'a mut Vec<Vec<usize>>,
301}
302
303fn dfs_find_cycles_from(input: &mut DfsCycleInput<'_>) {
304 let mut path: Vec<usize> = vec![input.start];
305 let mut path_set = FixedBitSet::with_capacity(input.succs.modules.len());
306 path_set.insert(input.start);
307
308 let range = &input.succs.succ_ranges[input.start];
309 let mut dfs: Vec<CycleFrame> = vec![CycleFrame {
310 succ_pos: range.start,
311 succ_end: range.end,
312 }];
313
314 while let Some(frame) = dfs.last_mut() {
315 if input.cycles.len() >= input.max_cycles {
316 return;
317 }
318
319 if frame.succ_pos >= frame.succ_end {
320 dfs.pop();
321 if path.len() > 1 {
322 let Some(removed) = path.pop() else {
323 continue;
324 };
325 path_set.set(removed, false);
326 }
327 continue;
328 }
329
330 let w = input.succs.all_succs[frame.succ_pos];
331 frame.succ_pos += 1;
332
333 if !input.scc_set.contains(&w) {
334 continue;
335 }
336
337 if w == input.start && path.len() >= 2 && path.len() == input.depth_limit {
338 try_record_cycle(&path, input.succs.modules, input.seen, input.cycles);
339 continue;
340 }
341
342 if path_set.contains(w) || path.len() >= input.depth_limit {
343 continue;
344 }
345
346 path.push(w);
347 path_set.insert(w);
348
349 let range = &input.succs.succ_ranges[w];
350 dfs.push(CycleFrame {
351 succ_pos: range.start,
352 succ_end: range.end,
353 });
354 }
355}
356
357fn enumerate_elementary_cycles(
363 scc_nodes: &[usize],
364 succs: &SuccessorMap<'_>,
365 max_cycles: usize,
366) -> Vec<Vec<usize>> {
367 let scc_set: FxHashSet<usize> = scc_nodes.iter().copied().collect();
368 let mut cycles: Vec<Vec<usize>> = Vec::new();
369 let mut seen: FxHashSet<Vec<u32>> = FxHashSet::default();
370
371 let mut sorted_nodes: Vec<usize> = scc_nodes.to_vec();
372 sorted_nodes.sort_by(|a, b| succs.modules[*a].path.cmp(&succs.modules[*b].path));
373
374 let max_depth = scc_nodes.len().min(12); for depth_limit in 2..=max_depth {
376 if cycles.len() >= max_cycles {
377 break;
378 }
379
380 for &start in &sorted_nodes {
381 if cycles.len() >= max_cycles {
382 break;
383 }
384
385 dfs_find_cycles_from(&mut DfsCycleInput {
386 start,
387 depth_limit,
388 scc_set: &scc_set,
389 succs,
390 max_cycles,
391 seen: &mut seen,
392 cycles: &mut cycles,
393 });
394 }
395 }
396
397 cycles
398}
399
400#[cfg(test)]
401mod tests {
402 use std::ops::Range;
403 use std::path::PathBuf;
404
405 use rustc_hash::FxHashSet;
406
407 use crate::graph::types::ModuleNode;
408 use crate::resolve::{ResolveResult, ResolvedImport, ResolvedModule};
409 use fallow_types::discover::{DiscoveredFile, EntryPoint, EntryPointSource, FileId};
410 use fallow_types::extract::{ExportName, ImportInfo, ImportedName, VisibilityTag};
411
412 use super::{
413 DfsCycleInput, ModuleGraph, SuccessorMap, canonical_cycle, dfs_find_cycles_from,
414 enumerate_elementary_cycles, try_record_cycle,
415 };
416
417 #[expect(
419 clippy::cast_possible_truncation,
420 reason = "test file counts are trivially small"
421 )]
422 fn build_cycle_graph(file_count: usize, edges_spec: &[(u32, u32)]) -> ModuleGraph {
423 let files: Vec<DiscoveredFile> = (0..file_count)
424 .map(|i| DiscoveredFile {
425 id: FileId(i as u32),
426 path: PathBuf::from(format!("/project/file{i}.ts")),
427 size_bytes: 100,
428 })
429 .collect();
430
431 let resolved_modules: Vec<ResolvedModule> = (0..file_count)
432 .map(|i| {
433 let imports: Vec<ResolvedImport> = edges_spec
434 .iter()
435 .filter(|(src, _)| *src == i as u32)
436 .map(|(_, tgt)| ResolvedImport {
437 info: ImportInfo {
438 source: format!("./file{tgt}"),
439 imported_name: ImportedName::Named("x".to_string()),
440 local_name: "x".to_string(),
441 is_type_only: false,
442 from_style: false,
443 span: oxc_span::Span::new(0, 10),
444 source_span: oxc_span::Span::default(),
445 },
446 target: ResolveResult::InternalModule(FileId(*tgt)),
447 })
448 .collect();
449
450 ResolvedModule {
451 file_id: FileId(i as u32),
452 path: PathBuf::from(format!("/project/file{i}.ts")),
453 exports: vec![fallow_types::extract::ExportInfo {
454 name: ExportName::Named("x".to_string()),
455 local_name: Some("x".to_string()),
456 is_type_only: false,
457 visibility: VisibilityTag::None,
458 expected_unused_reason: None,
459 span: oxc_span::Span::new(0, 20),
460 members: vec![],
461 is_side_effect_used: false,
462 super_class: None,
463 }],
464 re_exports: vec![],
465 resolved_imports: imports,
466 resolved_dynamic_imports: vec![],
467 resolved_dynamic_patterns: vec![],
468 member_accesses: vec![],
469 semantic_facts: Box::default(),
470 whole_object_uses: Box::default(),
471 has_cjs_exports: false,
472 has_angular_component_template_url: false,
473 unused_import_bindings: FxHashSet::default(),
474 type_referenced_import_bindings: vec![],
475 value_referenced_import_bindings: vec![],
476 namespace_object_aliases: vec![],
477 exported_factory_returns: Box::default(),
478 exported_factory_return_object_shapes: Box::default(),
479 type_member_types: Box::default(),
480 }
481 })
482 .collect();
483
484 let entry_points = vec![EntryPoint {
485 path: PathBuf::from("/project/file0.ts"),
486 source: EntryPointSource::PackageJsonMain,
487 }];
488
489 ModuleGraph::build(&resolved_modules, &entry_points, &files)
490 }
491
492 fn dfs_find_cycles_from_for_test(mut input: DfsCycleInput<'_>) {
493 dfs_find_cycles_from(&mut input);
494 }
495
496 #[test]
497 fn find_cycles_empty_graph() {
498 let graph = ModuleGraph::build(&[], &[], &[]);
499 assert!(graph.find_cycles().is_empty());
500 }
501
502 #[test]
503 fn find_cycles_no_cycles() {
504 let graph = build_cycle_graph(3, &[(0, 1), (1, 2)]);
505 assert!(graph.find_cycles().is_empty());
506 }
507
508 #[test]
509 fn find_cycles_simple_two_node_cycle() {
510 let graph = build_cycle_graph(2, &[(0, 1), (1, 0)]);
511 let cycles = graph.find_cycles();
512 assert_eq!(cycles.len(), 1);
513 assert_eq!(cycles[0].len(), 2);
514 }
515
516 #[test]
517 fn find_cycles_three_node_cycle() {
518 let graph = build_cycle_graph(3, &[(0, 1), (1, 2), (2, 0)]);
519 let cycles = graph.find_cycles();
520 assert_eq!(cycles.len(), 1);
521 assert_eq!(cycles[0].len(), 3);
522 }
523
524 #[test]
525 fn find_cycles_self_import_ignored() {
526 let graph = build_cycle_graph(1, &[(0, 0)]);
527 let cycles = graph.find_cycles();
528 assert!(
529 cycles.is_empty(),
530 "self-imports should not be reported as cycles"
531 );
532 }
533
534 #[test]
535 fn find_cycles_multiple_independent_cycles() {
536 let graph = build_cycle_graph(4, &[(0, 1), (1, 0), (2, 3), (3, 2)]);
537 let cycles = graph.find_cycles();
538 assert_eq!(cycles.len(), 2);
539 assert!(cycles.iter().all(|c| c.len() == 2));
540 }
541
542 #[test]
543 fn find_cycles_linear_chain_with_back_edge() {
544 let graph = build_cycle_graph(4, &[(0, 1), (1, 2), (2, 3), (3, 1)]);
545 let cycles = graph.find_cycles();
546 assert_eq!(cycles.len(), 1);
547 assert_eq!(cycles[0].len(), 3);
548 let ids: Vec<u32> = cycles[0].iter().map(|f| f.0).collect();
549 assert!(ids.contains(&1));
550 assert!(ids.contains(&2));
551 assert!(ids.contains(&3));
552 assert!(!ids.contains(&0));
553 }
554
555 #[test]
556 fn find_cycles_overlapping_cycles_enumerated() {
557 let graph = build_cycle_graph(3, &[(0, 1), (1, 0), (1, 2), (2, 1)]);
558 let cycles = graph.find_cycles();
559 assert_eq!(
560 cycles.len(),
561 2,
562 "should find 2 elementary cycles, not 1 SCC"
563 );
564 assert!(
565 cycles.iter().all(|c| c.len() == 2),
566 "both cycles should have length 2"
567 );
568 }
569
570 #[test]
571 fn find_cycles_deterministic_ordering() {
572 let graph1 = build_cycle_graph(3, &[(0, 1), (1, 2), (2, 0)]);
573 let graph2 = build_cycle_graph(3, &[(0, 1), (1, 2), (2, 0)]);
574 let cycles1 = graph1.find_cycles();
575 let cycles2 = graph2.find_cycles();
576 assert_eq!(cycles1.len(), cycles2.len());
577 for (c1, c2) in cycles1.iter().zip(cycles2.iter()) {
578 let paths1: Vec<&PathBuf> = c1
579 .iter()
580 .map(|f| &graph1.modules[f.0 as usize].path)
581 .collect();
582 let paths2: Vec<&PathBuf> = c2
583 .iter()
584 .map(|f| &graph2.modules[f.0 as usize].path)
585 .collect();
586 assert_eq!(paths1, paths2);
587 }
588 }
589
590 #[test]
591 fn find_cycles_sorted_by_length() {
592 let graph = build_cycle_graph(5, &[(0, 1), (1, 0), (2, 3), (3, 4), (4, 2)]);
593 let cycles = graph.find_cycles();
594 assert_eq!(cycles.len(), 2);
595 assert!(
596 cycles[0].len() <= cycles[1].len(),
597 "cycles should be sorted by length"
598 );
599 }
600
601 #[test]
602 fn find_cycles_large_cycle() {
603 let edges: Vec<(u32, u32)> = (0..10).map(|i| (i, (i + 1) % 10)).collect();
604 let graph = build_cycle_graph(10, &edges);
605 let cycles = graph.find_cycles();
606 assert_eq!(cycles.len(), 1);
607 assert_eq!(cycles[0].len(), 10);
608 }
609
610 #[test]
611 fn find_cycles_complex_scc_multiple_elementary() {
612 let graph = build_cycle_graph(4, &[(0, 1), (1, 2), (2, 3), (3, 0), (0, 2)]);
613 let cycles = graph.find_cycles();
614 assert!(
615 cycles.len() >= 2,
616 "should find at least 2 elementary cycles, got {}",
617 cycles.len()
618 );
619 assert!(cycles.iter().all(|c| c.len() <= 4));
620 }
621
622 #[test]
623 fn find_cycles_no_duplicate_cycles() {
624 let graph = build_cycle_graph(3, &[(0, 1), (1, 2), (2, 0)]);
625 let cycles = graph.find_cycles();
626 assert_eq!(cycles.len(), 1, "triangle should produce exactly 1 cycle");
627 assert_eq!(cycles[0].len(), 3);
628 }
629
630 #[expect(
635 clippy::cast_possible_truncation,
636 reason = "test file counts are trivially small"
637 )]
638 fn build_test_succs(
639 file_count: usize,
640 edges_spec: &[(usize, usize)],
641 ) -> (Vec<ModuleNode>, Vec<usize>, Vec<Range<usize>>) {
642 let modules: Vec<ModuleNode> = (0..file_count)
643 .map(|i| {
644 let mut node = ModuleNode {
645 file_id: FileId(i as u32),
646 path: PathBuf::from(format!("/project/file{i}.ts")),
647 edge_range: 0..0,
648 exports: vec![],
649 re_exports: vec![],
650 flags: ModuleNode::flags_from(i == 0, true, false),
651 };
652 node.set_reachable(true);
653 node
654 })
655 .collect();
656
657 let mut all_succs: Vec<usize> = Vec::new();
658 let mut succ_ranges: Vec<Range<usize>> = Vec::with_capacity(file_count);
659 for src in 0..file_count {
660 let start = all_succs.len();
661 let mut seen = FxHashSet::default();
662 for &(s, t) in edges_spec {
663 if s == src && t < file_count && seen.insert(t) {
664 all_succs.push(t);
665 }
666 }
667 let end = all_succs.len();
668 succ_ranges.push(start..end);
669 }
670
671 (modules, all_succs, succ_ranges)
672 }
673
674 #[test]
675 fn canonical_cycle_empty() {
676 let modules: Vec<ModuleNode> = vec![];
677 assert!(canonical_cycle(&[], &modules).is_empty());
678 }
679
680 #[test]
681 fn canonical_cycle_rotates_to_smallest_path() {
682 let (modules, _, _) = build_test_succs(3, &[]);
683 let result = canonical_cycle(&[2, 0, 1], &modules);
684 assert_eq!(result, vec![0, 1, 2]);
685 }
686
687 #[test]
688 fn canonical_cycle_already_canonical() {
689 let (modules, _, _) = build_test_succs(3, &[]);
690 let result = canonical_cycle(&[0, 1, 2], &modules);
691 assert_eq!(result, vec![0, 1, 2]);
692 }
693
694 #[test]
695 fn canonical_cycle_single_node() {
696 let (modules, _, _) = build_test_succs(1, &[]);
697 let result = canonical_cycle(&[0], &modules);
698 assert_eq!(result, vec![0]);
699 }
700
701 #[test]
702 fn try_record_cycle_inserts_new_cycle() {
703 let (modules, _, _) = build_test_succs(3, &[]);
704 let mut seen = FxHashSet::default();
705 let mut cycles = Vec::new();
706
707 try_record_cycle(&[0, 1, 2], &modules, &mut seen, &mut cycles);
708 assert_eq!(cycles.len(), 1);
709 assert_eq!(cycles[0], vec![0, 1, 2]);
710 }
711
712 #[test]
713 fn try_record_cycle_deduplicates_rotated_cycle() {
714 let (modules, _, _) = build_test_succs(3, &[]);
715 let mut seen = FxHashSet::default();
716 let mut cycles = Vec::new();
717
718 try_record_cycle(&[0, 1, 2], &modules, &mut seen, &mut cycles);
719 try_record_cycle(&[1, 2, 0], &modules, &mut seen, &mut cycles);
720 try_record_cycle(&[2, 0, 1], &modules, &mut seen, &mut cycles);
721
722 assert_eq!(
723 cycles.len(),
724 1,
725 "rotations of the same cycle should be deduped"
726 );
727 }
728
729 #[test]
730 fn try_record_cycle_single_node_self_loop() {
731 let (modules, _, _) = build_test_succs(1, &[]);
732 let mut seen = FxHashSet::default();
733 let mut cycles = Vec::new();
734
735 try_record_cycle(&[0], &modules, &mut seen, &mut cycles);
736 assert_eq!(cycles.len(), 1);
737 assert_eq!(cycles[0], vec![0]);
738 }
739
740 #[test]
741 fn try_record_cycle_distinct_cycles_both_recorded() {
742 let (modules, _, _) = build_test_succs(4, &[]);
743 let mut seen = FxHashSet::default();
744 let mut cycles = Vec::new();
745
746 try_record_cycle(&[0, 1], &modules, &mut seen, &mut cycles);
747 try_record_cycle(&[2, 3], &modules, &mut seen, &mut cycles);
748
749 assert_eq!(cycles.len(), 2);
750 }
751
752 #[test]
753 fn successor_map_empty_graph() {
754 let (modules, all_succs, succ_ranges) = build_test_succs(0, &[]);
755 let succs = SuccessorMap {
756 all_succs: &all_succs,
757 succ_ranges: &succ_ranges,
758 modules: &modules,
759 };
760 assert!(succs.all_succs.is_empty());
761 assert!(succs.succ_ranges.is_empty());
762 }
763
764 #[test]
765 fn successor_map_single_node_self_edge() {
766 let (modules, all_succs, succ_ranges) = build_test_succs(1, &[(0, 0)]);
767 let succs = SuccessorMap {
768 all_succs: &all_succs,
769 succ_ranges: &succ_ranges,
770 modules: &modules,
771 };
772 assert_eq!(succs.all_succs.len(), 1);
773 assert_eq!(succs.all_succs[0], 0);
774 assert_eq!(succs.succ_ranges[0], 0..1);
775 }
776
777 #[test]
778 fn successor_map_deduplicates_edges() {
779 let (modules, all_succs, succ_ranges) = build_test_succs(2, &[(0, 1), (0, 1)]);
780 let succs = SuccessorMap {
781 all_succs: &all_succs,
782 succ_ranges: &succ_ranges,
783 modules: &modules,
784 };
785 let range = &succs.succ_ranges[0];
786 assert_eq!(
787 range.end - range.start,
788 1,
789 "duplicate edges should be deduped"
790 );
791 }
792
793 #[test]
794 fn successor_map_multiple_successors() {
795 let (modules, all_succs, succ_ranges) = build_test_succs(4, &[(0, 1), (0, 2), (0, 3)]);
796 let succs = SuccessorMap {
797 all_succs: &all_succs,
798 succ_ranges: &succ_ranges,
799 modules: &modules,
800 };
801 let range = &succs.succ_ranges[0];
802 assert_eq!(range.end - range.start, 3);
803 for i in 1..4 {
804 let r = &succs.succ_ranges[i];
805 assert_eq!(r.end - r.start, 0);
806 }
807 }
808
809 #[test]
810 fn dfs_find_cycles_from_isolated_node() {
811 let (modules, all_succs, succ_ranges) = build_test_succs(1, &[]);
812 let succs = SuccessorMap {
813 all_succs: &all_succs,
814 succ_ranges: &succ_ranges,
815 modules: &modules,
816 };
817 let scc_set: FxHashSet<usize> = std::iter::once(0).collect();
818 let mut seen = FxHashSet::default();
819 let mut cycles = Vec::new();
820
821 dfs_find_cycles_from_for_test(DfsCycleInput {
822 start: 0,
823 depth_limit: 2,
824 scc_set: &scc_set,
825 succs: &succs,
826 max_cycles: 10,
827 seen: &mut seen,
828 cycles: &mut cycles,
829 });
830 assert!(cycles.is_empty(), "isolated node should have no cycles");
831 }
832
833 #[test]
834 fn dfs_find_cycles_from_simple_two_cycle() {
835 let (modules, all_succs, succ_ranges) = build_test_succs(2, &[(0, 1), (1, 0)]);
836 let succs = SuccessorMap {
837 all_succs: &all_succs,
838 succ_ranges: &succ_ranges,
839 modules: &modules,
840 };
841 let scc_set: FxHashSet<usize> = [0, 1].into_iter().collect();
842 let mut seen = FxHashSet::default();
843 let mut cycles = Vec::new();
844
845 dfs_find_cycles_from_for_test(DfsCycleInput {
846 start: 0,
847 depth_limit: 2,
848 scc_set: &scc_set,
849 succs: &succs,
850 max_cycles: 10,
851 seen: &mut seen,
852 cycles: &mut cycles,
853 });
854 assert_eq!(cycles.len(), 1);
855 assert_eq!(cycles[0].len(), 2);
856 }
857
858 #[test]
859 fn dfs_find_cycles_from_diamond_graph() {
860 let (modules, all_succs, succ_ranges) =
861 build_test_succs(4, &[(0, 1), (0, 2), (1, 3), (2, 3), (3, 0)]);
862 let succs = SuccessorMap {
863 all_succs: &all_succs,
864 succ_ranges: &succ_ranges,
865 modules: &modules,
866 };
867 let scc_set: FxHashSet<usize> = [0, 1, 2, 3].into_iter().collect();
868 let mut seen = FxHashSet::default();
869 let mut cycles = Vec::new();
870
871 dfs_find_cycles_from_for_test(DfsCycleInput {
872 start: 0,
873 depth_limit: 3,
874 scc_set: &scc_set,
875 succs: &succs,
876 max_cycles: 10,
877 seen: &mut seen,
878 cycles: &mut cycles,
879 });
880 assert_eq!(cycles.len(), 2, "diamond should have two 3-node cycles");
881 assert!(cycles.iter().all(|c| c.len() == 3));
882 }
883
884 #[test]
885 fn dfs_find_cycles_from_depth_limit_prevents_longer_cycles() {
886 let (modules, all_succs, succ_ranges) =
887 build_test_succs(4, &[(0, 1), (1, 2), (2, 3), (3, 0)]);
888 let succs = SuccessorMap {
889 all_succs: &all_succs,
890 succ_ranges: &succ_ranges,
891 modules: &modules,
892 };
893 let scc_set: FxHashSet<usize> = [0, 1, 2, 3].into_iter().collect();
894 let mut seen = FxHashSet::default();
895 let mut cycles = Vec::new();
896
897 dfs_find_cycles_from_for_test(DfsCycleInput {
898 start: 0,
899 depth_limit: 3,
900 scc_set: &scc_set,
901 succs: &succs,
902 max_cycles: 10,
903 seen: &mut seen,
904 cycles: &mut cycles,
905 });
906 assert!(
907 cycles.is_empty(),
908 "depth_limit=3 should prevent finding a 4-node cycle"
909 );
910 }
911
912 #[test]
913 fn dfs_find_cycles_from_depth_limit_exact_match() {
914 let (modules, all_succs, succ_ranges) =
915 build_test_succs(4, &[(0, 1), (1, 2), (2, 3), (3, 0)]);
916 let succs = SuccessorMap {
917 all_succs: &all_succs,
918 succ_ranges: &succ_ranges,
919 modules: &modules,
920 };
921 let scc_set: FxHashSet<usize> = [0, 1, 2, 3].into_iter().collect();
922 let mut seen = FxHashSet::default();
923 let mut cycles = Vec::new();
924
925 dfs_find_cycles_from_for_test(DfsCycleInput {
926 start: 0,
927 depth_limit: 4,
928 scc_set: &scc_set,
929 succs: &succs,
930 max_cycles: 10,
931 seen: &mut seen,
932 cycles: &mut cycles,
933 });
934 assert_eq!(
935 cycles.len(),
936 1,
937 "depth_limit=4 should find the 4-node cycle"
938 );
939 assert_eq!(cycles[0].len(), 4);
940 }
941
942 #[test]
943 fn dfs_find_cycles_from_respects_max_cycles() {
944 let edges: Vec<(usize, usize)> = (0..4)
945 .flat_map(|i| (0..4).filter(move |&j| i != j).map(move |j| (i, j)))
946 .collect();
947 let (modules, all_succs, succ_ranges) = build_test_succs(4, &edges);
948 let succs = SuccessorMap {
949 all_succs: &all_succs,
950 succ_ranges: &succ_ranges,
951 modules: &modules,
952 };
953 let scc_set: FxHashSet<usize> = (0..4).collect();
954 let mut seen = FxHashSet::default();
955 let mut cycles = Vec::new();
956
957 dfs_find_cycles_from_for_test(DfsCycleInput {
958 start: 0,
959 depth_limit: 2,
960 scc_set: &scc_set,
961 succs: &succs,
962 max_cycles: 2,
963 seen: &mut seen,
964 cycles: &mut cycles,
965 });
966 assert!(
967 cycles.len() <= 2,
968 "should respect max_cycles limit, got {}",
969 cycles.len()
970 );
971 }
972
973 #[test]
974 fn dfs_find_cycles_from_ignores_nodes_outside_scc() {
975 let (modules, all_succs, succ_ranges) = build_test_succs(3, &[(0, 1), (1, 2), (2, 0)]);
976 let succs = SuccessorMap {
977 all_succs: &all_succs,
978 succ_ranges: &succ_ranges,
979 modules: &modules,
980 };
981 let scc_set: FxHashSet<usize> = [0, 1].into_iter().collect();
982 let mut seen = FxHashSet::default();
983 let mut cycles = Vec::new();
984
985 for depth in 2..=3 {
986 dfs_find_cycles_from_for_test(DfsCycleInput {
987 start: 0,
988 depth_limit: depth,
989 scc_set: &scc_set,
990 succs: &succs,
991 max_cycles: 10,
992 seen: &mut seen,
993 cycles: &mut cycles,
994 });
995 }
996 assert!(
997 cycles.is_empty(),
998 "should not find cycles through nodes outside the SCC set"
999 );
1000 }
1001
1002 #[test]
1003 fn enumerate_elementary_cycles_empty_scc() {
1004 let (modules, all_succs, succ_ranges) = build_test_succs(0, &[]);
1005 let succs = SuccessorMap {
1006 all_succs: &all_succs,
1007 succ_ranges: &succ_ranges,
1008 modules: &modules,
1009 };
1010 let cycles = enumerate_elementary_cycles(&[], &succs, 10);
1011 assert!(cycles.is_empty());
1012 }
1013
1014 #[test]
1015 fn enumerate_elementary_cycles_max_cycles_limit() {
1016 let edges: Vec<(usize, usize)> = (0..4)
1017 .flat_map(|i| (0..4).filter(move |&j| i != j).map(move |j| (i, j)))
1018 .collect();
1019 let (modules, all_succs, succ_ranges) = build_test_succs(4, &edges);
1020 let succs = SuccessorMap {
1021 all_succs: &all_succs,
1022 succ_ranges: &succ_ranges,
1023 modules: &modules,
1024 };
1025 let scc_nodes: Vec<usize> = (0..4).collect();
1026
1027 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 3);
1028 assert!(
1029 cycles.len() <= 3,
1030 "should respect max_cycles=3 limit, got {}",
1031 cycles.len()
1032 );
1033 }
1034
1035 #[test]
1036 fn enumerate_elementary_cycles_finds_all_in_triangle() {
1037 let (modules, all_succs, succ_ranges) = build_test_succs(3, &[(0, 1), (1, 2), (2, 0)]);
1038 let succs = SuccessorMap {
1039 all_succs: &all_succs,
1040 succ_ranges: &succ_ranges,
1041 modules: &modules,
1042 };
1043 let scc_nodes: Vec<usize> = vec![0, 1, 2];
1044
1045 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 20);
1046 assert_eq!(cycles.len(), 1);
1047 assert_eq!(cycles[0].len(), 3);
1048 }
1049
1050 #[test]
1051 fn enumerate_elementary_cycles_iterative_deepening_order() {
1052 let (modules, all_succs, succ_ranges) =
1053 build_test_succs(3, &[(0, 1), (1, 0), (1, 2), (2, 0)]);
1054 let succs = SuccessorMap {
1055 all_succs: &all_succs,
1056 succ_ranges: &succ_ranges,
1057 modules: &modules,
1058 };
1059 let scc_nodes: Vec<usize> = vec![0, 1, 2];
1060
1061 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 20);
1062 assert!(cycles.len() >= 2, "should find at least 2 cycles");
1063 assert!(
1064 cycles[0].len() <= cycles[cycles.len() - 1].len(),
1065 "shorter cycles should be found before longer ones"
1066 );
1067 }
1068
1069 #[test]
1070 fn find_cycles_max_cycles_per_scc_respected() {
1071 let edges: Vec<(u32, u32)> = (0..5)
1072 .flat_map(|i| (0..5).filter(move |&j| i != j).map(move |j| (i, j)))
1073 .collect();
1074 let graph = build_cycle_graph(5, &edges);
1075 let cycles = graph.find_cycles();
1076 assert!(
1077 cycles.len() <= 20,
1078 "should cap at MAX_CYCLES_PER_SCC, got {}",
1079 cycles.len()
1080 );
1081 assert!(
1082 !cycles.is_empty(),
1083 "dense graph should still find some cycles"
1084 );
1085 }
1086
1087 #[test]
1088 fn find_cycles_graph_with_no_cycles_returns_empty() {
1089 let graph = build_cycle_graph(5, &[(0, 1), (0, 2), (0, 3), (0, 4)]);
1090 assert!(graph.find_cycles().is_empty());
1091 }
1092
1093 #[test]
1094 fn find_cycles_diamond_no_cycle() {
1095 let graph = build_cycle_graph(4, &[(0, 1), (0, 2), (1, 3), (2, 3)]);
1096 assert!(graph.find_cycles().is_empty());
1097 }
1098
1099 #[test]
1100 fn find_cycles_diamond_with_back_edge() {
1101 let graph = build_cycle_graph(4, &[(0, 1), (0, 2), (1, 3), (2, 3), (3, 0)]);
1102 let cycles = graph.find_cycles();
1103 assert!(
1104 cycles.len() >= 2,
1105 "diamond with back-edge should have at least 2 elementary cycles, got {}",
1106 cycles.len()
1107 );
1108 assert_eq!(cycles[0].len(), 3);
1109 }
1110
1111 #[test]
1112 fn canonical_cycle_non_sequential_indices() {
1113 let (modules, _, _) = build_test_succs(5, &[]);
1114 let result = canonical_cycle(&[3, 1, 4], &modules);
1115 assert_eq!(result, vec![1, 4, 3]);
1116 }
1117
1118 #[test]
1119 fn canonical_cycle_different_starting_points_same_result() {
1120 let (modules, _, _) = build_test_succs(4, &[]);
1121 let r1 = canonical_cycle(&[0, 1, 2, 3], &modules);
1122 let r2 = canonical_cycle(&[1, 2, 3, 0], &modules);
1123 let r3 = canonical_cycle(&[2, 3, 0, 1], &modules);
1124 let r4 = canonical_cycle(&[3, 0, 1, 2], &modules);
1125 assert_eq!(r1, r2);
1126 assert_eq!(r2, r3);
1127 assert_eq!(r3, r4);
1128 assert_eq!(r1, vec![0, 1, 2, 3]);
1129 }
1130
1131 #[test]
1132 fn canonical_cycle_two_node_both_rotations() {
1133 let (modules, _, _) = build_test_succs(2, &[]);
1134 assert_eq!(canonical_cycle(&[0, 1], &modules), vec![0, 1]);
1135 assert_eq!(canonical_cycle(&[1, 0], &modules), vec![0, 1]);
1136 }
1137
1138 #[test]
1139 fn dfs_find_cycles_from_self_loop_not_found() {
1140 let (modules, all_succs, succ_ranges) = build_test_succs(1, &[(0, 0)]);
1141 let succs = SuccessorMap {
1142 all_succs: &all_succs,
1143 succ_ranges: &succ_ranges,
1144 modules: &modules,
1145 };
1146 let scc_set: FxHashSet<usize> = std::iter::once(0).collect();
1147 let mut seen = FxHashSet::default();
1148 let mut cycles = Vec::new();
1149
1150 for depth in 1..=3 {
1151 dfs_find_cycles_from_for_test(DfsCycleInput {
1152 start: 0,
1153 depth_limit: depth,
1154 scc_set: &scc_set,
1155 succs: &succs,
1156 max_cycles: 10,
1157 seen: &mut seen,
1158 cycles: &mut cycles,
1159 });
1160 }
1161 assert!(
1162 cycles.is_empty(),
1163 "self-loop should not be detected as a cycle by dfs_find_cycles_from"
1164 );
1165 }
1166
1167 #[test]
1168 fn enumerate_elementary_cycles_self_loop_not_found() {
1169 let (modules, all_succs, succ_ranges) = build_test_succs(1, &[(0, 0)]);
1170 let succs = SuccessorMap {
1171 all_succs: &all_succs,
1172 succ_ranges: &succ_ranges,
1173 modules: &modules,
1174 };
1175 let cycles = enumerate_elementary_cycles(&[0], &succs, 20);
1176 assert!(
1177 cycles.is_empty(),
1178 "self-loop should not produce elementary cycles"
1179 );
1180 }
1181
1182 #[test]
1183 fn find_cycles_two_cycles_sharing_edge() {
1184 let graph = build_cycle_graph(4, &[(0, 1), (1, 2), (2, 0), (1, 3), (3, 0)]);
1185 let cycles = graph.find_cycles();
1186 assert_eq!(
1187 cycles.len(),
1188 2,
1189 "two cycles sharing edge A->B should both be found, got {}",
1190 cycles.len()
1191 );
1192 assert!(
1193 cycles.iter().all(|c| c.len() == 3),
1194 "both cycles should have length 3"
1195 );
1196 }
1197
1198 #[test]
1199 fn enumerate_elementary_cycles_shared_edge() {
1200 let (modules, all_succs, succ_ranges) =
1201 build_test_succs(4, &[(0, 1), (1, 2), (2, 0), (1, 3), (3, 0)]);
1202 let succs = SuccessorMap {
1203 all_succs: &all_succs,
1204 succ_ranges: &succ_ranges,
1205 modules: &modules,
1206 };
1207 let scc_nodes: Vec<usize> = vec![0, 1, 2, 3];
1208 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 20);
1209 assert_eq!(
1210 cycles.len(),
1211 2,
1212 "should find exactly 2 elementary cycles sharing edge 0->1, got {}",
1213 cycles.len()
1214 );
1215 }
1216
1217 #[test]
1218 fn enumerate_elementary_cycles_pentagon_with_chords() {
1219 let (modules, all_succs, succ_ranges) =
1220 build_test_succs(5, &[(0, 1), (1, 2), (2, 3), (3, 4), (4, 0), (0, 2), (0, 3)]);
1221 let succs = SuccessorMap {
1222 all_succs: &all_succs,
1223 succ_ranges: &succ_ranges,
1224 modules: &modules,
1225 };
1226 let scc_nodes: Vec<usize> = vec![0, 1, 2, 3, 4];
1227 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 20);
1228
1229 assert!(
1230 cycles.len() >= 3,
1231 "pentagon with chords should have at least 3 elementary cycles, got {}",
1232 cycles.len()
1233 );
1234 let unique: FxHashSet<Vec<usize>> = cycles.iter().cloned().collect();
1235 assert_eq!(
1236 unique.len(),
1237 cycles.len(),
1238 "all enumerated cycles should be unique"
1239 );
1240 assert_eq!(
1241 cycles[0].len(),
1242 3,
1243 "shortest cycle in pentagon with chords should be length 3"
1244 );
1245 }
1246
1247 #[test]
1248 fn find_cycles_large_scc_complete_graph_k6() {
1249 let edges: Vec<(u32, u32)> = (0..6)
1250 .flat_map(|i| (0..6).filter(move |&j| i != j).map(move |j| (i, j)))
1251 .collect();
1252 let graph = build_cycle_graph(6, &edges);
1253 let cycles = graph.find_cycles();
1254
1255 assert!(
1256 cycles.len() <= 20,
1257 "should cap at MAX_CYCLES_PER_SCC (20), got {}",
1258 cycles.len()
1259 );
1260 assert_eq!(
1261 cycles.len(),
1262 20,
1263 "K6 has far more than 20 elementary cycles, so we should hit the cap"
1264 );
1265 assert_eq!(cycles[0].len(), 2, "shortest cycles in K6 should be 2-node");
1266 }
1267
1268 #[test]
1269 fn enumerate_elementary_cycles_respects_depth_cap_of_12() {
1270 let edges: Vec<(usize, usize)> = (0..15).map(|i| (i, (i + 1) % 15)).collect();
1271 let (modules, all_succs, succ_ranges) = build_test_succs(15, &edges);
1272 let succs = SuccessorMap {
1273 all_succs: &all_succs,
1274 succ_ranges: &succ_ranges,
1275 modules: &modules,
1276 };
1277 let scc_nodes: Vec<usize> = (0..15).collect();
1278 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 20);
1279
1280 assert!(
1281 cycles.is_empty(),
1282 "a pure 15-node cycle should not be found with depth cap of 12, got {} cycles",
1283 cycles.len()
1284 );
1285 }
1286
1287 #[test]
1288 fn enumerate_elementary_cycles_finds_cycle_at_depth_cap_boundary() {
1289 let edges: Vec<(usize, usize)> = (0..12).map(|i| (i, (i + 1) % 12)).collect();
1290 let (modules, all_succs, succ_ranges) = build_test_succs(12, &edges);
1291 let succs = SuccessorMap {
1292 all_succs: &all_succs,
1293 succ_ranges: &succ_ranges,
1294 modules: &modules,
1295 };
1296 let scc_nodes: Vec<usize> = (0..12).collect();
1297 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 20);
1298
1299 assert_eq!(
1300 cycles.len(),
1301 1,
1302 "a pure 12-node cycle should be found at the depth cap boundary"
1303 );
1304 assert_eq!(cycles[0].len(), 12);
1305 }
1306
1307 #[test]
1308 fn enumerate_elementary_cycles_13_node_pure_cycle_not_found() {
1309 let edges: Vec<(usize, usize)> = (0..13).map(|i| (i, (i + 1) % 13)).collect();
1310 let (modules, all_succs, succ_ranges) = build_test_succs(13, &edges);
1311 let succs = SuccessorMap {
1312 all_succs: &all_succs,
1313 succ_ranges: &succ_ranges,
1314 modules: &modules,
1315 };
1316 let scc_nodes: Vec<usize> = (0..13).collect();
1317 let cycles = enumerate_elementary_cycles(&scc_nodes, &succs, 20);
1318
1319 assert!(
1320 cycles.is_empty(),
1321 "13-node pure cycle exceeds depth cap of 12"
1322 );
1323 }
1324
1325 #[test]
1326 fn find_cycles_max_cycles_per_scc_enforced_on_k7() {
1327 let edges: Vec<(u32, u32)> = (0..7)
1328 .flat_map(|i| (0..7).filter(move |&j| i != j).map(move |j| (i, j)))
1329 .collect();
1330 let graph = build_cycle_graph(7, &edges);
1331 let cycles = graph.find_cycles();
1332
1333 assert!(
1334 cycles.len() <= 20,
1335 "K7 should cap at MAX_CYCLES_PER_SCC (20), got {}",
1336 cycles.len()
1337 );
1338 assert_eq!(
1339 cycles.len(),
1340 20,
1341 "K7 has far more than 20 elementary cycles, should hit the cap exactly"
1342 );
1343 }
1344
1345 #[test]
1346 fn find_cycles_two_dense_sccs_each_capped() {
1347 let mut edges: Vec<(u32, u32)> = Vec::new();
1348 for i in 0..4 {
1349 for j in 0..4 {
1350 if i != j {
1351 edges.push((i, j));
1352 }
1353 }
1354 }
1355 for i in 4..8 {
1356 for j in 4..8 {
1357 if i != j {
1358 edges.push((i, j));
1359 }
1360 }
1361 }
1362 let graph = build_cycle_graph(8, &edges);
1363 let cycles = graph.find_cycles();
1364
1365 assert!(!cycles.is_empty(), "two dense SCCs should produce cycles");
1366 assert!(
1367 cycles.len() > 2,
1368 "should find multiple cycles across both SCCs, got {}",
1369 cycles.len()
1370 );
1371 }
1372
1373 mod proptests {
1374 use super::*;
1375 use proptest::prelude::*;
1376
1377 proptest! {
1378 #[test]
1381 fn dag_has_no_cycles(
1382 file_count in 2..20usize,
1383 edge_pairs in prop::collection::vec((0..19u32, 0..19u32), 0..30),
1384 ) {
1385 let dag_edges: Vec<(u32, u32)> = edge_pairs
1386 .into_iter()
1387 .filter(|(a, b)| (*a as usize) < file_count && (*b as usize) < file_count && a < b)
1388 .collect();
1389
1390 let graph = build_cycle_graph(file_count, &dag_edges);
1391 let cycles = graph.find_cycles();
1392 prop_assert!(
1393 cycles.is_empty(),
1394 "DAG should have no cycles, but found {}",
1395 cycles.len()
1396 );
1397 }
1398
1399 #[test]
1401 fn mutual_edges_always_detect_cycle(extra_nodes in 0..10usize) {
1402 let file_count = 2 + extra_nodes;
1403 let graph = build_cycle_graph(file_count, &[(0, 1), (1, 0)]);
1404 let cycles = graph.find_cycles();
1405 prop_assert!(
1406 !cycles.is_empty(),
1407 "A->B->A should always produce at least one cycle"
1408 );
1409 let has_pair_cycle = cycles.iter().any(|c| {
1410 c.contains(&FileId(0)) && c.contains(&FileId(1))
1411 });
1412 prop_assert!(has_pair_cycle, "Should find a cycle containing nodes 0 and 1");
1413 }
1414
1415 #[test]
1417 fn cycle_members_are_valid_indices(
1418 file_count in 2..15usize,
1419 edge_pairs in prop::collection::vec((0..14u32, 0..14u32), 1..20),
1420 ) {
1421 let edges: Vec<(u32, u32)> = edge_pairs
1422 .into_iter()
1423 .filter(|(a, b)| (*a as usize) < file_count && (*b as usize) < file_count && a != b)
1424 .collect();
1425
1426 let graph = build_cycle_graph(file_count, &edges);
1427 let cycles = graph.find_cycles();
1428 for cycle in &cycles {
1429 prop_assert!(cycle.len() >= 2, "Cycles must have at least 2 nodes");
1430 for file_id in cycle {
1431 prop_assert!(
1432 (file_id.0 as usize) < file_count,
1433 "FileId {} exceeds file count {}",
1434 file_id.0, file_count
1435 );
1436 }
1437 }
1438 }
1439
1440 #[test]
1442 fn cycles_sorted_by_length(
1443 file_count in 3..12usize,
1444 edge_pairs in prop::collection::vec((0..11u32, 0..11u32), 2..25),
1445 ) {
1446 let edges: Vec<(u32, u32)> = edge_pairs
1447 .into_iter()
1448 .filter(|(a, b)| (*a as usize) < file_count && (*b as usize) < file_count && a != b)
1449 .collect();
1450
1451 let graph = build_cycle_graph(file_count, &edges);
1452 let cycles = graph.find_cycles();
1453 for window in cycles.windows(2) {
1454 prop_assert!(
1455 window[0].len() <= window[1].len(),
1456 "Cycles should be sorted by length: {} > {}",
1457 window[0].len(), window[1].len()
1458 );
1459 }
1460 }
1461 }
1462 }
1463
1464 fn build_cycle_graph_with_type_only(
1466 file_count: usize,
1467 edges_spec: &[(u32, u32, bool)], ) -> ModuleGraph {
1469 let files: Vec<DiscoveredFile> = (0..file_count)
1470 .map(|i| DiscoveredFile {
1471 id: FileId(i as u32),
1472 path: PathBuf::from(format!("/project/file{i}.ts")),
1473 size_bytes: 100,
1474 })
1475 .collect();
1476
1477 let resolved_modules: Vec<ResolvedModule> = (0..file_count)
1478 .map(|i| {
1479 let imports: Vec<ResolvedImport> = edges_spec
1480 .iter()
1481 .filter(|(src, _, _)| *src == i as u32)
1482 .map(|(_, tgt, type_only)| ResolvedImport {
1483 info: ImportInfo {
1484 source: format!("./file{tgt}"),
1485 imported_name: ImportedName::Named("x".to_string()),
1486 local_name: "x".to_string(),
1487 is_type_only: *type_only,
1488 from_style: false,
1489 span: oxc_span::Span::new(0, 10),
1490 source_span: oxc_span::Span::default(),
1491 },
1492 target: ResolveResult::InternalModule(FileId(*tgt)),
1493 })
1494 .collect();
1495
1496 ResolvedModule {
1497 file_id: FileId(i as u32),
1498 path: PathBuf::from(format!("/project/file{i}.ts")),
1499 exports: vec![fallow_types::extract::ExportInfo {
1500 name: ExportName::Named("x".to_string()),
1501 local_name: Some("x".to_string()),
1502 is_type_only: false,
1503 visibility: VisibilityTag::None,
1504 expected_unused_reason: None,
1505 span: oxc_span::Span::new(0, 20),
1506 members: vec![],
1507 is_side_effect_used: false,
1508 super_class: None,
1509 }],
1510 re_exports: vec![],
1511 resolved_imports: imports,
1512 resolved_dynamic_imports: vec![],
1513 resolved_dynamic_patterns: vec![],
1514 member_accesses: vec![],
1515 semantic_facts: Box::default(),
1516 whole_object_uses: Box::default(),
1517 has_cjs_exports: false,
1518 has_angular_component_template_url: false,
1519 unused_import_bindings: FxHashSet::default(),
1520 type_referenced_import_bindings: vec![],
1521 value_referenced_import_bindings: vec![],
1522 namespace_object_aliases: vec![],
1523 exported_factory_returns: Box::default(),
1524 exported_factory_return_object_shapes: Box::default(),
1525 type_member_types: Box::default(),
1526 }
1527 })
1528 .collect();
1529
1530 let entry_points = vec![EntryPoint {
1531 path: PathBuf::from("/project/file0.ts"),
1532 source: EntryPointSource::PackageJsonMain,
1533 }];
1534
1535 ModuleGraph::build(&resolved_modules, &entry_points, &files)
1536 }
1537
1538 #[test]
1539 fn type_only_bidirectional_import_not_a_cycle() {
1540 let graph = build_cycle_graph_with_type_only(2, &[(0, 1, true), (1, 0, true)]);
1541 let cycles = graph.find_cycles();
1542 assert!(
1543 cycles.is_empty(),
1544 "type-only bidirectional imports should not be reported as cycles"
1545 );
1546 }
1547
1548 #[test]
1549 fn mixed_type_and_value_import_not_a_cycle() {
1550 let graph = build_cycle_graph_with_type_only(2, &[(0, 1, false), (1, 0, true)]);
1551 let cycles = graph.find_cycles();
1552 assert!(
1553 cycles.is_empty(),
1554 "A->B (value) + B->A (type-only) is not a runtime cycle"
1555 );
1556 }
1557
1558 #[test]
1559 fn both_value_imports_with_one_type_still_a_cycle() {
1560 let graph = build_cycle_graph_with_type_only(2, &[(0, 1, false), (1, 0, false)]);
1561 let cycles = graph.find_cycles();
1562 assert!(
1563 !cycles.is_empty(),
1564 "bidirectional value imports should be reported as a cycle"
1565 );
1566 }
1567
1568 #[test]
1569 fn all_value_imports_still_a_cycle() {
1570 let graph = build_cycle_graph_with_type_only(2, &[(0, 1, false), (1, 0, false)]);
1571 let cycles = graph.find_cycles();
1572 assert_eq!(cycles.len(), 1);
1573 }
1574
1575 #[test]
1576 fn three_node_type_only_cycle_not_reported() {
1577 let graph =
1578 build_cycle_graph_with_type_only(3, &[(0, 1, true), (1, 2, true), (2, 0, true)]);
1579 let cycles = graph.find_cycles();
1580 assert!(
1581 cycles.is_empty(),
1582 "three-node type-only cycle should not be reported"
1583 );
1584 }
1585
1586 #[test]
1587 fn three_node_cycle_one_value_edge_still_reported() {
1588 let graph =
1589 build_cycle_graph_with_type_only(3, &[(0, 1, false), (1, 2, true), (2, 0, true)]);
1590 let cycles = graph.find_cycles();
1591 assert!(
1592 cycles.is_empty(),
1593 "cycle broken by type-only edge in the middle should not be reported"
1594 );
1595 }
1596}