fallow_types/extract.rs
1//! Module extraction types.
2
3use oxc_span::Span;
4
5use crate::discover::FileId;
6use crate::suppress::{Suppression, UnknownSuppressionKind};
7
8/// Extracted module information from a single file.
9#[derive(Debug, Clone)]
10pub struct ModuleInfo {
11 /// Unique identifier for this file.
12 pub file_id: FileId,
13 /// All export declarations in this module.
14 pub exports: Vec<ExportInfo>,
15 /// All import declarations in this module.
16 pub imports: Vec<ImportInfo>,
17 /// All re-export declarations (e.g., `export { foo } from './bar'`).
18 pub re_exports: Vec<ReExportInfo>,
19 /// All dynamic `import()` calls with string literal sources.
20 pub dynamic_imports: Vec<DynamicImportInfo>,
21 /// Dynamic import patterns.
22 pub dynamic_import_patterns: Vec<DynamicImportPattern>,
23 /// All `require()` calls.
24 pub require_calls: Vec<RequireCallInfo>,
25 /// Package names statically referenced through package path resolution.
26 pub package_path_references: Box<[String]>,
27 /// Static member access expressions (e.g., `Status.Active`).
28 pub member_accesses: Vec<MemberAccess>,
29 /// Typed semantic facts produced by extraction for cross-layer analysis.
30 ///
31 /// This carries facts that were previously encoded as synthetic
32 /// `member_accesses` strings. Extraction and analysis now use typed facts.
33 pub semantic_facts: Box<[SemanticFact]>,
34 /// Identifiers used in whole-object access patterns.
35 pub whole_object_uses: Box<[String]>,
36 /// Whether this module uses CommonJS exports.
37 pub has_cjs_exports: bool,
38 /// Whether this module declares an Angular component `templateUrl`.
39 pub has_angular_component_template_url: bool,
40 /// xxh3 hash of the file content for incremental caching.
41 pub content_hash: u64,
42 /// Inline suppression directives parsed from comments.
43 pub suppressions: Vec<Suppression>,
44 /// Suppression tokens that did not parse to any known `IssueKind`.
45 /// Surfaced as `StaleSuppression` findings via `find_stale` so users see
46 /// typos or obsolete kind names instead of having the entire marker
47 /// silently discarded. See issue #449.
48 pub unknown_suppression_kinds: Vec<UnknownSuppressionKind>,
49 /// Local names of import bindings that are never referenced in this file.
50 /// Populated via `oxc_semantic` scope analysis. Used at graph-build time
51 /// to skip adding references for imports whose binding is never read,
52 /// improving unused-export detection precision.
53 pub unused_import_bindings: Vec<String>,
54 /// Local import bindings that are referenced from TypeScript type positions.
55 /// Used to distinguish value-namespace and type-namespace references when a
56 /// module exports both `const X` and `type X`.
57 pub type_referenced_import_bindings: Vec<String>,
58 /// Local import bindings referenced from runtime/value positions.
59 pub value_referenced_import_bindings: Vec<String>,
60 /// Pre-computed byte offsets where each line starts.
61 pub line_offsets: Vec<u32>,
62 /// Per-function complexity metrics.
63 pub complexity: Vec<FunctionComplexity>,
64 /// Feature flag use sites.
65 pub flag_uses: Vec<FlagUse>,
66 /// Heritage metadata for exported classes that declare `implements`.
67 pub class_heritage: Vec<ClassHeritageInfo>,
68 /// Exported free-function factories that provably return one class instance
69 /// (`export function useApi() { return new RESTApi() }`). Origin-module proof
70 /// that an exported function returns a class instance, so a cross-module
71 /// `const x = useApi(); x.member` consumer can credit the returned class.
72 /// See issue #1441 (Part A).
73 pub exported_factory_returns: Box<[FactoryReturnExport]>,
74 /// Angular `InjectionToken<Interface>` declarations, as
75 /// `(token_export_name, interface_name)` pairs. Recorded only for
76 /// `new InjectionToken<I>(...)` initializers whose `InjectionToken` is
77 /// imported from `@angular/core`. The analyze layer follows the token's
78 /// interface type argument to the classes that `implement` it so a template
79 /// member call through `inject(TOKEN)` credits the concrete implementation.
80 /// See issue #920 (follow-up to #911 / #913).
81 pub injection_tokens: Vec<(String, String)>,
82 /// Local type-capable declarations.
83 pub local_type_declarations: Vec<LocalTypeDeclaration>,
84 /// Type references in exported public signatures.
85 pub public_signature_type_references: Vec<PublicSignatureTypeReference>,
86 /// Aliases of namespace imports re-exported through an object literal.
87 pub namespace_object_aliases: Vec<NamespaceObjectAlias>,
88 /// Deduped Iconify collection prefixes found in static icon props.
89 pub iconify_prefixes: Vec<String>,
90 /// Deduped Nuxt UI `i-<collection>-<icon>` icon class suffixes found in
91 /// static script-side icon properties.
92 pub iconify_icon_names: Vec<String>,
93 /// Bare identifiers that may be resolved by framework auto-imports.
94 pub auto_import_candidates: Vec<String>,
95 /// File-level string directives in source order (e.g. `"use client"`,
96 /// `"use server"`, `"use strict"`). Captured from `Program::directives`.
97 /// Consumed by the security `client-server-leak` detector to identify
98 /// React Server Component client boundaries.
99 pub directives: Vec<String>,
100 /// Byte-offset starts of dynamic `import()` expressions wrapped in
101 /// `next/dynamic(() => import('./X'), { ssr: false })`. The ssr:false option
102 /// is Next.js's sanctioned way to pull a client-only module, so a server-only
103 /// module reached ONLY through such an import is NOT a client-server leak. The
104 /// security `client-server-leak` BFS resolves each dynamic import to a graph
105 /// edge; these span starts let the BFS exclude exactly those edges (matched
106 /// against the edge's `import_span`). Empty for files with no ssr:false
107 /// dynamic import. Captured only by JS/TS extraction.
108 pub client_only_dynamic_import_spans: Vec<u32>,
109 /// Captured security sink sites (category-blind). Consumed by the
110 /// catalogue-driven `tainted_sink` detector. Captured only by JS/TS
111 /// extraction; empty for CSS/MDX/etc. See `security_matchers.toml`.
112 pub security_sinks: Vec<SinkSite>,
113 /// Count of sink-shaped nodes whose callee could not be flattened to a
114 /// static path (dynamic dispatch, computed members, aliased bindings).
115 /// Surfaced in-band so an empty catalogue result with a non-zero count is
116 /// not a clean bill.
117 pub security_sinks_skipped: u32,
118 /// Compact span-level diagnostics for skipped security sink callees. Kept
119 /// next to `security_sinks_skipped` so warm-cache and cold-cache security
120 /// output can explain where the blind spots are concentrated without source
121 /// snippets.
122 pub security_unresolved_callee_sites: Vec<SkippedSecurityCalleeSite>,
123 /// Local bindings whose initializer (or destructured object) is a flattened
124 /// member-access path. Used by the security `tainted_sink` detector to
125 /// back-trace a sink argument to a known untrusted source: the analyze layer
126 /// matches each binding's `source_path` against the data-driven source
127 /// catalogue (`security_matchers.toml` `[[source]]` rows) and treats the
128 /// matching `local` names as source-tainted. Intra-module and name-based
129 /// (no scope analysis); a conservative association, never a taint proof.
130 pub tainted_bindings: Vec<TaintedBinding>,
131 /// Sink arguments that were recognized as sanitizer calls at extraction
132 /// time. Used for direct sink calls such as
133 /// `el.innerHTML = DOMPurify.sanitize(input)`.
134 pub sanitized_sink_args: Vec<SanitizedSinkArg>,
135 /// Known defensive control call sites found in this module. Consumed only by
136 /// the `fallow security --surface` agent JSON path.
137 pub security_control_sites: Vec<SecurityControlSite>,
138 /// Statically flattenable callee paths invoked in this module, deduped per
139 /// unique path (first occurrence wins). Consumed by the
140 /// `boundaries.calls.forbidden` detector. Captured unconditionally because
141 /// extraction is config-blind; the per-module cost is bounded by the
142 /// unique-callee count.
143 pub callee_uses: Vec<CalleeUse>,
144 /// `"use client"` / `"use server"` directive strings written as expression
145 /// statements in `program.body` (misplaced, NOT in the leading
146 /// prologue), so the RSC bundler silently ignores them. One entry per
147 /// occurrence. Consumed by the `misplaced-directive` detector. Captured
148 /// only by JS/TS extraction.
149 pub misplaced_directives: Vec<MisplacedDirectiveSite>,
150 /// Export LOCAL NAMES of exported functions / const-arrows whose body has an
151 /// inline `"use server"` directive (`export async function f() { "use server"
152 /// }`), captured in a NON-`"use server"` file. Consumed by the
153 /// `unused-server-action` detector to reclassify an unused inline Server
154 /// Action export out of `unused-export`. Captured only by JS/TS extraction.
155 pub inline_server_action_exports: Vec<String>,
156 /// Vue `provide`/`inject` and Svelte `setContext`/`getContext` call sites
157 /// keyed by an identifier symbol. Consumed by the `unprovided-inject`
158 /// detector to find an inject/getContext whose key is provided nowhere
159 /// project-wide. Only identifier-keyed sites are recorded (string-literal
160 /// and computed keys abstain). Captured by JS/TS and SFC extraction.
161 pub di_key_sites: Vec<DiKeySite>,
162 /// `true` when this module contains a `provide(...)` / `*.provide(...)` /
163 /// `setContext(...)` call whose key argument is NOT a plain identifier
164 /// (spread, computed, member, loop variable). Such a call can provide an
165 /// unknowable key, so the `unprovided-inject` detector abstains on ALL
166 /// inject findings project-wide when any reachable module sets this flag.
167 /// Mirrors the spread-return whole-object abstain used for Pinia stores.
168 pub has_dynamic_provide: bool,
169 /// Local names of import bindings that ARE referenced somewhere in this file
170 /// (script value/type position OR template/markup). The complement of
171 /// `unused_import_bindings` among `imports`. Derived in
172 /// `release_resolution_payload` (where both `imports` and
173 /// `unused_import_bindings` are still present) so it survives the release and
174 /// is readable by the analyze layer; it is never cached (recomputed on every
175 /// cache load). Consumed by the `unrendered-component` detector to credit a
176 /// Vue/Svelte SFC that some file actually imports-and-uses, distinguishing it
177 /// from a component reachable only through a barrel re-export.
178 pub referenced_import_bindings: Vec<String>,
179 /// Vue `<script setup>` `defineProps` and Svelte 5 `$props()` declared
180 /// props. Consumed by the `unused-component-prop` detector to flag a prop
181 /// referenced nowhere in its own SFC. Each entry carries `used_in_script` /
182 /// `used_in_template`.
183 pub component_props: Vec<ComponentProp>,
184 /// `true` when the template spreads the whole props/attrs object
185 /// (`v-bind="$attrs"` / `v-bind="$props"` / `v-bind="props"`) or the props
186 /// return is destructured with a rest element. Either form can consume a prop
187 /// indirectly, so the detector abstains on the whole file.
188 pub has_props_attrs_fallthrough: bool,
189 /// `true` when the SFC calls `defineExpose(...)`. A prop may be re-exposed,
190 /// so the detector conservatively abstains on the whole file.
191 pub has_define_expose: bool,
192 /// `true` when the SFC calls `defineModel(...)`. Two-way model props are out
193 /// of scope for v1, so the detector abstains on the whole file.
194 pub has_define_model: bool,
195 /// `true` when props were declared through an unharvestable shape, such as a
196 /// Vue type-reference argument or an opaque Svelte `$props()` destructure.
197 /// The detector abstains on the whole file so a prop is never falsely
198 /// flagged.
199 pub has_unharvestable_props: bool,
200 /// Vue `<script setup>` `defineEmits` declared events. Consumed by the
201 /// `unused-component-emit` detector to flag an event emitted nowhere in its
202 /// own SFC. Each entry carries `used`.
203 pub component_emits: Vec<ComponentEmit>,
204 /// Angular component/directive inputs declared via `@Input()` decorators or
205 /// signal `input()` / `input.required()` / `model()` initializers. Consumed
206 /// by the `unused-component-input` detector to flag an input read nowhere in
207 /// its own component. Empty for every non-Angular class.
208 pub angular_inputs: Vec<AngularInputMember>,
209 /// Angular component/directive outputs declared via `@Output()` decorators or
210 /// signal `output()` / `outputFromObservable()` initializers. Consumed by the
211 /// `unused-component-output` detector to flag an output emitted nowhere in its
212 /// own component. A `model()` is recorded as an input only (see
213 /// `AngularOutputMember`). Empty for every non-Angular class.
214 pub angular_outputs: Vec<AngularOutputMember>,
215 /// Angular `@Component` declarations with their `selector` value(s), harvested
216 /// from `@Component({ selector: '...' })` decorators. Consumed by the Angular
217 /// arm of the `unrendered-component` detector. Empty for every non-Angular
218 /// class and for `@Directive`. See `AngularComponentSelector`.
219 pub angular_component_selectors: Vec<AngularComponentSelector>,
220 /// Lit / web-component custom elements REGISTERED in this file via
221 /// `@customElement('x-foo')` or `customElements.define('x-foo', C)`. Consumed
222 /// by the Lit arm of the `unrendered-component` detector, which flags a
223 /// registered element whose tag is rendered in NO `html` template
224 /// project-wide. Empty for non-Lit / non-web-component files. See
225 /// `RegisteredCustomElement`.
226 pub registered_custom_elements: Vec<RegisteredCustomElement>,
227 /// Custom-element tag names USED (rendered) in this file's `html` tagged
228 /// templates, e.g. `` html`<x-foo></x-foo>` `` -> `x-foo`. Only hyphenated
229 /// (custom-element) tags are recorded; native HTML tags are excluded by the
230 /// hyphen requirement. The detector unions these project-wide into the
231 /// rendered-tag set. Empty for files with no `html` templates.
232 pub used_custom_element_tags: Vec<String>,
233 /// Custom element selector tag names referenced in this file's Angular
234 /// templates (inline `@Component({ template })` and the linked external
235 /// `templateUrl` `.html` module), e.g. `<app-foo>` -> `app-foo`. Native HTML
236 /// tag names are excluded at harvest. The detector unions these project-wide
237 /// into the used-selector set. Empty for non-Angular files.
238 pub angular_used_selectors: Vec<String>,
239 /// Angular component class names referenced as a route entry or bootstrap
240 /// target: a route `component: Foo` / `loadComponent: () => import().then(m =>
241 /// m.Foo)` value, a `bootstrapApplication(Foo)` argument, or a
242 /// `bootstrap: [Foo]` NgModule entry. These are render-equivalent entry points
243 /// (Angular instantiates them without a template `<tag>`), so the Angular
244 /// `unrendered-component` detector abstains on a component whose class name is
245 /// in the project-wide union. A plain `declarations: [...]` / `imports: [...]`
246 /// registration is intentionally NOT harvested here (that is the dead case the
247 /// rule catches). Empty for non-Angular files.
248 pub angular_entry_component_refs: Vec<String>,
249 /// `true` when this file dynamically renders an Angular component fallow
250 /// cannot attribute to a literal class reference: a
251 /// `ViewContainerRef.createComponent(...)` / `*.createComponent(<ident>)`
252 /// call, or an `*ngComponentOutlet` template binding. The Angular
253 /// `unrendered-component` detector abstains project-wide when ANY reachable
254 /// module sets this (mirroring `unprovided-inject`'s `has_dynamic_provide`),
255 /// since a component could be rendered by a non-literal class reference.
256 pub has_dynamic_component_render: bool,
257 /// `true` when `defineEmits` was called with an unharvestable argument (a
258 /// type-reference type argument such as `defineEmits<MyEmits>()`, a
259 /// non-literal runtime form, or an unbound `defineEmits([...])`). The
260 /// detector abstains on the whole file so an emit is never falsely flagged.
261 pub has_unharvestable_emits: bool,
262 /// `true` when an `emit(<nonLiteral>)` call was seen (the emitted event name
263 /// cannot be known statically). The detector abstains on the whole file.
264 pub has_dynamic_emit: bool,
265 /// `true` when the `defineEmits` return binding was used as a WHOLE value
266 /// (passed to a function, returned, or spread), which can emit any event
267 /// opaquely. The detector abstains on the whole file.
268 pub has_emit_whole_object_use: bool,
269 /// SvelteKit `load()` return-object keys harvested from a
270 /// `+page.{ts,server.ts,js,server.js}` file's terminal return literal.
271 /// Consumed by the `unused-load-data-key` detector. Empty for every file
272 /// that is not a page-load producer (gated by basename at harvest time).
273 pub load_return_keys: Vec<LoadReturnKey>,
274 /// `true` when this file's `load()` body could not be harvested safely (a
275 /// spread return, a non-object/non-literal return, more than one top-level
276 /// `return`, a computed key, or a wrapped/re-exported `load`). The detector
277 /// abstains on the whole file so a key is never falsely flagged.
278 pub has_unharvestable_load: bool,
279 /// `true` when this file passes the whole `data` object opaquely (script
280 /// `const X = data`, `fn(data)` / `fn(...data)`, or template `data={data}` /
281 /// `{...data}` in a route component), so a child can read arbitrary keys the
282 /// detector cannot see. Name-gated on the `data` binding. Read ONLY by the
283 /// `unused-load-data-key` detector, so capturing it for all files is
284 /// byte-identity-safe. See FP-1 in the plan.
285 pub has_load_data_whole_use: bool,
286 /// `true` when this file uses the whole `page.data` / `$page.data` store
287 /// object opaquely (e.g. `Object.values(page.data)`, `{...$page.data}`), so a
288 /// reflective read could consume any route's key. Drives the
289 /// `unused-load-data-key` detector's project-wide abstain. Derived in
290 /// `release_resolution_payload` from `whole_object_uses` BEFORE that vector is
291 /// released (mirroring `referenced_import_bindings`), so it survives the
292 /// release the detector runs after; it is never cached (recomputed each run
293 /// from the cached `whole_object_uses`). Reassignment forms
294 /// (`const all = $page.data`) are not whole-object-tracked and stay out of
295 /// scope, matching the syntactic analyzer's conservative posture.
296 pub has_page_data_store_whole_use: bool,
297 /// React/JSX component definitions: functions/arrows whose body returns JSX.
298 /// Captured only for `.jsx`/`.tsx` files when a React/Preact dependency is
299 /// plausible. Consumed by the React `unused-component-prop` arm and the
300 /// complexity-fold phase. Empty for non-React files.
301 pub component_functions: Vec<ComponentFunction>,
302 /// React component props (reuses the shared `ComponentProp` struct). For
303 /// React, `used_in_template` is always false and `used_in_script` means
304 /// used-in-body. Empty for non-React files.
305 pub react_props: Vec<ComponentProp>,
306 /// React hook call sites (`useState` / `useEffect` / `useMemo` /
307 /// `useCallback` / custom `use*`). Drives hook-density complexity context.
308 /// Empty for non-React files.
309 pub hook_uses: Vec<HookUse>,
310 /// React render edges: one component rendering another. Captured with the
311 /// child's written name; child-to-`FileId` resolution is deferred to graph
312 /// build. Empty for non-React files.
313 pub render_edges: Vec<RenderEdge>,
314 /// Svelte custom events dispatched via `dispatch('<name>')` where `dispatch`
315 /// is the binding from `const dispatch = createEventDispatcher()`. Consumed
316 /// by the `unused-svelte-event` detector to flag an event dispatched here but
317 /// listened to nowhere project-wide. Each entry carries the literal event
318 /// name and its span. Empty for every non-Svelte file.
319 pub svelte_dispatched_events: Vec<DispatchedEvent>,
320 /// Svelte custom-event listener names harvested from template `on:<name>`
321 /// bindings on COMPONENT tags (PascalCase tag names). Lowercase DOM-element
322 /// `on:click` is a DOM event, not a custom event, and is excluded. Unioned
323 /// project-wide by the `unused-svelte-event` detector to build the liberal
324 /// "listened" set. Empty for every non-Svelte file.
325 pub svelte_listened_events: Vec<String>,
326 /// `true` when a `dispatch(<nonLiteral>)` call was seen (the dispatched event
327 /// name cannot be known statically), or the `dispatch` binding was used as a
328 /// whole value (passed / returned). The `unused-svelte-event` detector
329 /// abstains on the whole component so an event is never falsely flagged.
330 pub has_dynamic_dispatch: bool,
331}
332
333impl ModuleInfo {
334 /// Release extraction payload that resolution has already copied into the graph.
335 ///
336 /// This keeps fields needed by analysis, health, security, LSP, coverage,
337 /// and hash drift checks, while dropping vectors that otherwise duplicate
338 /// data owned by `ResolvedModule` or already credited into the module graph.
339 pub fn release_resolution_payload(&mut self) {
340 // Derive the referenced-binding set BEFORE releasing `unused_import_bindings`:
341 // the analyze-layer `unrendered-component` detector needs "which imports are
342 // actually used" but runs after this release, so capture the compact
343 // complement here. Skip empty local names (side-effect imports).
344 self.referenced_import_bindings = self
345 .imports
346 .iter()
347 .map(|import| import.local_name.clone())
348 .filter(|name| !name.is_empty() && !self.unused_import_bindings.contains(name))
349 .collect();
350 self.referenced_import_bindings.sort_unstable();
351 self.referenced_import_bindings.dedup();
352
353 // Derive the project-wide page-data-store whole-use signal BEFORE
354 // releasing `whole_object_uses`: the `unused-load-data-key` detector runs
355 // after this release and needs to know whether ANY module reflectively
356 // consumes the whole `page.data` / `$page.data` store.
357 self.has_page_data_store_whole_use = self
358 .whole_object_uses
359 .iter()
360 .any(|name| name == "page.data" || name == "$page.data");
361
362 Self::release_vec(&mut self.dynamic_imports);
363 Self::release_vec(&mut self.require_calls);
364 Self::release_boxed_slice(&mut self.package_path_references);
365 Self::release_boxed_slice(&mut self.whole_object_uses);
366 Self::release_vec(&mut self.unused_import_bindings);
367 Self::release_vec(&mut self.type_referenced_import_bindings);
368 Self::release_vec(&mut self.value_referenced_import_bindings);
369 Self::release_vec(&mut self.namespace_object_aliases);
370 Self::release_vec(&mut self.auto_import_candidates);
371 }
372
373 fn release_vec<T>(values: &mut Vec<T>) {
374 *values = Vec::new();
375 }
376
377 fn release_boxed_slice<T>(values: &mut Box<[T]>) {
378 *values = Box::default();
379 }
380}
381
382/// Defensive control family detected on a source to sink path.
383#[derive(
384 Debug,
385 Clone,
386 Copy,
387 PartialEq,
388 Eq,
389 PartialOrd,
390 Ord,
391 serde::Serialize,
392 serde::Deserialize,
393 bitcode::Encode,
394 bitcode::Decode,
395)]
396#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
397#[serde(rename_all = "kebab-case")]
398pub enum SecurityControlKind {
399 /// Sanitization or escaping before a sink.
400 Sanitization,
401 /// Input validation or schema parsing.
402 Validation,
403 /// Authentication check or middleware.
404 Authentication,
405 /// Authorization or permission check.
406 Authorization,
407}
408
409/// A known defensive control call site.
410#[derive(Debug, Clone, serde::Serialize, serde::Deserialize, bitcode::Encode, bitcode::Decode)]
411pub struct SecurityControlSite {
412 /// Control family.
413 pub kind: SecurityControlKind,
414 /// Flattened callee path or a stable synthetic name for guard-derived
415 /// controls.
416 pub callee_path: String,
417 /// Byte offset of the control span start.
418 pub span_start: u32,
419 /// Byte offset of the control span end.
420 pub span_end: u32,
421}
422
423/// Sanitizer output domain. Kept intentionally narrow so a sanitizer for one
424/// domain cannot suppress a different sink family.
425#[derive(
426 Debug,
427 Clone,
428 Copy,
429 PartialEq,
430 Eq,
431 PartialOrd,
432 Ord,
433 serde::Serialize,
434 serde::Deserialize,
435 bitcode::Encode,
436 bitcode::Decode,
437)]
438pub enum SanitizerScope {
439 /// HTML markup sanitized by DOMPurify-compatible APIs.
440 Html,
441 /// URL or redirect target checked against a literal-backed allowlist.
442 Url,
443 /// Path value checked against a high-confidence containment guard.
444 Path,
445 /// SQL identifier quoted with a helper that doubles embedded identifier quotes.
446 SqlIdentifier,
447}
448
449/// A captured sink argument that is itself a recognized sanitizer call.
450#[derive(Debug, Clone, serde::Serialize, serde::Deserialize, bitcode::Encode, bitcode::Decode)]
451pub struct SanitizedSinkArg {
452 /// Byte offset of the owning sink span start.
453 pub span_start: u32,
454 /// The positional argument index on the owning sink.
455 pub arg_index: u32,
456 /// The sanitizer output domain for this argument.
457 pub scope: SanitizerScope,
458}
459
460/// A local binding tied to the flattened member-access path it was initialized
461/// from. The analyze layer matches `source_path` against the data-driven source
462/// catalogue; when it matches, `local` is treated as carrying untrusted input.
463///
464/// Captured for two shapes: a direct assignment (`const id = req.query.id` ->
465/// `{ local: "id", source_path: "req.query" }`, the literal-key tail dropped so
466/// the path matches a catalogue prefix) and an object destructure
467/// (`const { id } = req.query` -> `{ local: "id", source_path: "req.query" }`).
468#[derive(Debug, Clone, serde::Serialize, serde::Deserialize, bitcode::Encode, bitcode::Decode)]
469pub struct TaintedBinding {
470 /// The local binding name introduced by the declarator.
471 pub local: String,
472 /// The flattened object member-access path the binding was sourced from.
473 pub source_path: String,
474 /// Byte offset of the source read (the member-access expression the binding
475 /// was sourced from), so the analyze layer can anchor a taint trace's source
476 /// node at the real read line instead of the module import line. Stored as a
477 /// `u32` (not `Span`) to stay bitcode-encodable for the cache. `0` when no
478 /// concrete read expression is available (synthetic framework-param /
479 /// helper-return bindings), in which case the analyze layer falls back to the
480 /// sink site rather than claiming a spurious line.
481 pub source_span_start: u32,
482}
483
484/// Why a sink-shaped callee could not be flattened into a static catalogue
485/// path.
486#[derive(
487 Debug,
488 Clone,
489 Copy,
490 PartialEq,
491 Eq,
492 PartialOrd,
493 Ord,
494 serde::Serialize,
495 serde::Deserialize,
496 bitcode::Encode,
497 bitcode::Decode,
498)]
499#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
500#[serde(rename_all = "kebab-case")]
501pub enum SkippedSecurityCalleeReason {
502 /// A computed member access such as `client[method](input)`.
503 ComputedMember,
504 /// A dynamic non-member callee such as `(factory())(input)`.
505 DynamicDispatch,
506 /// An assignment target whose object could not be flattened.
507 UnsupportedAssignmentObject,
508}
509
510/// Syntactic expression shape for a skipped security callee.
511#[derive(
512 Debug,
513 Clone,
514 Copy,
515 PartialEq,
516 Eq,
517 PartialOrd,
518 Ord,
519 serde::Serialize,
520 serde::Deserialize,
521 bitcode::Encode,
522 bitcode::Decode,
523)]
524#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
525#[serde(rename_all = "kebab-case")]
526pub enum SkippedSecurityCalleeExpressionKind {
527 /// `obj.prop(...)`.
528 StaticMemberExpression,
529 /// `obj[prop](...)`.
530 ComputedMemberExpression,
531 /// A bare identifier or private identifier callee.
532 Identifier,
533 /// Any other call-like expression that cannot be represented compactly.
534 Other,
535}
536
537/// Span-only diagnostic for a skipped security callee inside one module.
538#[derive(Debug, Clone, serde::Serialize, serde::Deserialize, bitcode::Encode, bitcode::Decode)]
539pub struct SkippedSecurityCalleeSite {
540 /// Why the callee was skipped.
541 pub reason: SkippedSecurityCalleeReason,
542 /// Compact expression shape of the skipped callee.
543 pub expression_kind: SkippedSecurityCalleeExpressionKind,
544 /// Start byte offset of the skipped callee expression.
545 pub span_start: u32,
546 /// End byte offset of the skipped callee expression.
547 pub span_end: u32,
548}
549
550/// The syntactic shape of a captured security sink site. Category-blind: the
551/// extractor records the shape and the dotted/bare callee path; the analyze
552/// layer matches it against the data-driven catalogue. See
553/// `crates/core/data/security_matchers.toml`.
554#[derive(
555 Debug,
556 Clone,
557 Copy,
558 PartialEq,
559 Eq,
560 serde::Serialize,
561 serde::Deserialize,
562 bitcode::Encode,
563 bitcode::Decode,
564)]
565pub enum SinkShape {
566 /// A call to a bare identifier (e.g. `eval(x)`).
567 Call,
568 /// A call to a dotted member path (e.g. `child_process.exec(x)`).
569 MemberCall,
570 /// An assignment to a member target (e.g. `el.innerHTML = x`).
571 MemberAssign,
572 /// A tagged template expression (e.g. ``sql`...${x}...` ``).
573 TaggedTemplate,
574 /// A JSX attribute value (e.g. `dangerouslySetInnerHTML={x}`).
575 JsxAttr,
576 /// A constructor call (e.g. `new Function("return x")`).
577 NewExpression,
578 /// A static string literal assigned to a secret-shaped identifier or known
579 /// provider credential prefix.
580 SecretLiteral,
581}
582
583/// The shape of the argument captured at a sink site. Category-blind like
584/// [`SinkShape`], but finer-grained: it lets the catalogue matcher require or
585/// exclude specific argument shapes. The discriminator is what distinguishes an
586/// unsafe SQL string concatenation or template-into-`.execute()` from a
587/// safely-parameterized `` sql`${x}` `` tagged template, an object-literal
588/// `.execute({ sql, args })` argument, or a literal-aware sink argument.
589#[derive(
590 Debug,
591 Clone,
592 Copy,
593 PartialEq,
594 Eq,
595 serde::Serialize,
596 serde::Deserialize,
597 bitcode::Encode,
598 bitcode::Decode,
599)]
600pub enum SinkArgKind {
601 /// A template literal with at least one `${...}` substitution (e.g.
602 /// `` `SELECT ${x}` ``). On a `tagged-template` shape this is the tag's
603 /// quasi; on a `call`/`member-call` shape it is the positional argument.
604 TemplateWithSubst,
605 /// A binary `+` string concatenation (e.g. `"SELECT " + x`).
606 Concat,
607 /// An object literal (e.g. `.execute({ sql, args })`, the parameterized form).
608 Object,
609 /// A call expression argument (e.g. `query(buildSql())`).
610 Call,
611 /// A literal argument admitted by a literal-aware security matcher.
612 Literal,
613 /// A zero-argument sink captured because the callee itself is the signal.
614 NoArg,
615 /// Any other non-literal expression (bare identifier, member access, etc.).
616 Other,
617}
618
619/// Static URL construction shape captured for URL-shaped security sinks.
620#[derive(
621 Debug,
622 Clone,
623 Copy,
624 PartialEq,
625 Eq,
626 serde::Serialize,
627 serde::Deserialize,
628 bitcode::Encode,
629 bitcode::Decode,
630)]
631#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
632#[serde(rename_all = "kebab-case")]
633pub enum SecurityUrlShape {
634 /// The sink target has a fixed origin, scheme, or relative root while only
635 /// path or query components are dynamic.
636 FixedOriginDynamicPath,
637 /// The sink target's scheme or origin is dynamic or opaque.
638 DynamicOrigin,
639}
640
641/// Literal values attached to literal-aware security sink captures.
642#[derive(
643 Debug,
644 Clone,
645 PartialEq,
646 Eq,
647 serde::Serialize,
648 serde::Deserialize,
649 bitcode::Encode,
650 bitcode::Decode,
651)]
652pub enum SinkLiteralValue {
653 /// A string literal value.
654 String(String),
655 /// An integer numeric literal value.
656 Integer(i64),
657 /// A boolean literal value.
658 Boolean(bool),
659 /// A null literal value.
660 Null,
661}
662
663/// Static object-literal property metadata attached to a captured sink
664/// argument. Nested object paths are flattened with dot-separated keys.
665#[derive(
666 Debug,
667 Clone,
668 PartialEq,
669 Eq,
670 serde::Serialize,
671 serde::Deserialize,
672 bitcode::Encode,
673 bitcode::Decode,
674)]
675pub struct SinkObjectProperty {
676 /// Static property name. Nested object properties use dot-separated paths.
677 pub key: String,
678 /// Literal property value when statically knowable.
679 pub value: SinkLiteralValue,
680}
681
682/// A captured sink site. The visitor records every existing non-literal call /
683/// member-assign / member-call / tagged-template / jsx-attr sink site, and a
684/// small allowlist of literal-aware sites where the literal value is the signal.
685/// It knows nothing about CWE categories.
686#[derive(Debug, Clone, serde::Serialize, serde::Deserialize, bitcode::Encode, bitcode::Decode)]
687pub struct SinkSite {
688 /// The syntactic shape of the sink site.
689 pub sink_shape: SinkShape,
690 /// The flattened dotted/bare callee or member path.
691 pub callee_path: String,
692 /// The positional argument index. For zero-argument captures this is 0.
693 pub arg_index: u32,
694 /// Whether the relevant argument is non-literal. Existing non-literal
695 /// catalogue rows require this to remain true.
696 pub arg_is_non_literal: bool,
697 /// The finer-grained shape of the captured argument. Lets the catalogue
698 /// require unsafe shapes (concat / template-with-substitution / literal /
699 /// no-arg) and exclude safe ones (object literal, the parameterized form).
700 /// See [`SinkArgKind`].
701 pub arg_kind: SinkArgKind,
702 /// Literal argument value for literal-aware rows.
703 pub arg_literal: Option<SinkLiteralValue>,
704 /// Risky regex fragment for structural ReDoS candidates.
705 pub regex_pattern: Option<String>,
706 /// Static object-literal properties for option-object rows.
707 pub object_properties: Vec<SinkObjectProperty>,
708 /// Static top-level object-literal keys, including keys whose values are not
709 /// literal. Used by missing-option rows that only need key presence.
710 pub object_property_keys: Vec<String>,
711 /// Whether [`object_property_keys`](Self::object_property_keys) is complete.
712 /// False for non-object arguments and object literals with spread or
713 /// non-static keys, where a missing-key claim would be speculative.
714 pub object_property_keys_complete: bool,
715 /// Identifier names referenced anywhere inside the captured non-literal sink
716 /// argument, or contextual names for zero-argument captures such as a
717 /// token-like `Math.random()` assignment target. Deduped in source order.
718 /// Used by the analyze layer to back-trace the sink argument to a known
719 /// untrusted source or to apply narrow context gates. Intra-module,
720 /// name-based, conservative; it is never a taint proof.
721 pub arg_idents: Vec<String>,
722 /// Flattened static member paths referenced inside the captured non-literal
723 /// sink argument. Includes both the full path and source-object path for
724 /// leaf reads (`process.env.SECRET` records `process.env.SECRET` and
725 /// `process.env`) so direct source expressions can be matched without an
726 /// intermediate local binding.
727 pub arg_source_paths: Vec<String>,
728 /// Byte offset of the sink span start. Stored as `u32` (not `Span`) so the
729 /// struct is bitcode-encodable and can be persisted directly in the cache.
730 pub span_start: u32,
731 /// Byte offset of the sink span end.
732 pub span_end: u32,
733 /// The arg-0 URL string literal of a network-shaped call (`fetch`, `axios.*`,
734 /// `got`, ...), captured so the `secret-to-network` category (#890) can carry
735 /// a destination-host signal on its candidate: `Some(literal)` when the
736 /// destination is a static string literal (almost always intended auth, e.g.
737 /// the credential's own provider), `None` when it is dynamic (the suspicious
738 /// case). `None` for non-call sinks and calls with no arg 0.
739 pub url_arg_literal: Option<String>,
740 /// URL construction shape for URL-like sink arguments when the extractor can
741 /// classify it syntactically. `None` for non-URL sinks and URL expressions
742 /// whose shape is not visible at the sink.
743 pub url_shape: Option<SecurityUrlShape>,
744}
745
746impl SinkSite {
747 /// Reconstruct the source span from the stored byte offsets.
748 #[must_use]
749 pub fn span(&self) -> Span {
750 Span::new(self.span_start, self.span_end)
751 }
752}
753
754/// Env var-name prefixes that frameworks inline into the client bundle by
755/// convention. A read of one of these is normal and safe, so it does NOT count
756/// as a secret source (issue #890). Shared by the extract layer (so public env
757/// vars never become source signals) and the bespoke `client-server-leak` rule.
758pub const PUBLIC_ENV_PREFIXES: &[&str] = &[
759 "NEXT_PUBLIC_",
760 "VITE_",
761 "NUXT_PUBLIC_",
762 "REACT_APP_",
763 "PUBLIC_",
764 "GATSBY_",
765 "EXPO_PUBLIC_",
766 "STORYBOOK_",
767];
768
769/// Exact env var names that are public by convention (no prefix).
770pub const PUBLIC_ENV_EXACT: &[&str] = &["NODE_ENV"];
771
772/// Env var-name tokens that usually describe public build or deployment
773/// metadata rather than secrets. Secret-shaped names win over these tokens.
774pub const PUBLIC_ENV_METADATA_TOKENS: &[&str] =
775 &["BRANCH", "ENVIRONMENT", "MODE", "REF", "SHA", "TAG"];
776
777/// Env var-name tokens that should keep a variable source-backed even when the
778/// name also contains public metadata tokens such as `REF` or `SHA`.
779pub const SECRET_ENV_TOKENS: &[&str] = &[
780 "AUTH",
781 "CREDENTIAL",
782 "CREDENTIALS",
783 "KEY",
784 "PASS",
785 "PASSWORD",
786 "PRIVATE",
787 "SECRET",
788 "TOKEN",
789];
790
791fn env_name_has_token(name: &str, tokens: &[&str]) -> bool {
792 name.split(|ch: char| !ch.is_ascii_alphanumeric())
793 .filter(|part| !part.is_empty())
794 .any(|part| tokens.contains(&part))
795}
796
797/// Whether an env var name is public-by-convention (build-inlined into the
798/// client bundle), and therefore not a secret.
799#[must_use]
800pub fn is_public_env_var(name: &str) -> bool {
801 if PUBLIC_ENV_EXACT.contains(&name) || PUBLIC_ENV_PREFIXES.iter().any(|p| name.starts_with(p)) {
802 return true;
803 }
804 env_name_has_token(name, PUBLIC_ENV_METADATA_TOKENS)
805 && !env_name_has_token(name, SECRET_ENV_TOKENS)
806}
807
808/// Whether a flattened member path is a PUBLIC env-secret read
809/// (`process.env.NEXT_PUBLIC_X`, `import.meta.env.VITE_Y`), which must not be
810/// recorded as a secret source. Non-env paths (`req.query.id`) are never public.
811#[must_use]
812pub fn is_public_env_path(path: &str) -> bool {
813 for object in ["process.env.", "import.meta.env."] {
814 if let Some(var) = path.strip_prefix(object) {
815 return is_public_env_var(var);
816 }
817 }
818 false
819}
820
821/// One alias entry tying an exported object's dotted property path to a namespace import.
822#[derive(Debug, Clone)]
823pub struct NamespaceObjectAlias {
824 /// Canonical export name.
825 pub via_export_name: String,
826 /// Dotted suffix of the property path relative to the export.
827 pub suffix: String,
828 /// Local name of the namespace import.
829 pub namespace_local: String,
830}
831
832/// Compute a table of line-start byte offsets from source text.
833#[must_use]
834#[expect(
835 clippy::cast_possible_truncation,
836 reason = "source files are practically < 4GB"
837)]
838pub fn compute_line_offsets(source: &str) -> Vec<u32> {
839 let mut offsets = vec![0u32];
840 for (i, byte) in source.bytes().enumerate() {
841 if byte == b'\n' {
842 debug_assert!(
843 u32::try_from(i + 1).is_ok(),
844 "source file exceeds u32::MAX bytes: line offsets would overflow"
845 );
846 offsets.push((i + 1) as u32);
847 }
848 }
849 offsets
850}
851
852/// Convert a byte offset to a 1-based line number and 0-based byte column.
853#[must_use]
854#[expect(
855 clippy::cast_possible_truncation,
856 reason = "line count is bounded by source size"
857)]
858pub fn byte_offset_to_line_col(line_offsets: &[u32], byte_offset: u32) -> (u32, u32) {
859 let line_idx = match line_offsets.binary_search(&byte_offset) {
860 Ok(idx) => idx,
861 Err(idx) => idx.saturating_sub(1),
862 };
863 let line = line_idx as u32 + 1;
864 let col = byte_offset - line_offsets[line_idx];
865 (line, col)
866}
867
868/// Complexity metrics for a single function/method/arrow.
869#[derive(Debug, Clone, serde::Serialize, bitcode::Encode, bitcode::Decode)]
870pub struct FunctionComplexity {
871 /// Function name (or `"<anonymous>"` for unnamed functions/arrows).
872 pub name: String,
873 /// 1-based line number where the function starts.
874 pub line: u32,
875 /// 0-based byte column where the function starts.
876 pub col: u32,
877 /// `McCabe` cyclomatic complexity (1 + decision points).
878 pub cyclomatic: u16,
879 /// `SonarSource` cognitive complexity (structural + nesting penalty).
880 pub cognitive: u16,
881 /// Number of lines in the function body.
882 pub line_count: u32,
883 /// Number of parameters (excluding TypeScript's `this` parameter).
884 pub param_count: u8,
885 /// Number of React hook calls (`useState` / `useEffect` / `useMemo` /
886 /// `useCallback` / custom `use*`) made directly in this function's body.
887 /// Non-zero only for React components/hooks; descriptive context surfaced in
888 /// the hotspot drill-down, never a tunable threshold (anti-numerology).
889 pub react_hook_count: u16,
890 /// Maximum JSX element nesting depth reached in this function's body (the
891 /// deepest chain of element-inside-element). `0` when the function renders
892 /// no JSX. Descriptive context surfaced in the hotspot drill-down, never a
893 /// tunable threshold (anti-numerology).
894 pub react_jsx_max_depth: u16,
895 /// Number of props destructured from this component's first parameter (the
896 /// `{ a, b, c }` props object). `0` for non-component functions and for
897 /// components taking a bare `props` identifier (not statically countable).
898 /// Descriptive context surfaced in the hotspot drill-down, never a tunable
899 /// threshold (anti-numerology).
900 pub react_prop_count: u16,
901 /// Content digest of the function's full-span source slice.
902 pub source_hash: Option<String>,
903 /// Per-decision-point breakdown explaining WHICH constructs drove the
904 /// cyclomatic and cognitive scores. One entry per increment event (an `if`
905 /// emits one cyclomatic and one cognitive entry at the same line, because
906 /// the two metrics accrue at different granularities). Always computed and
907 /// cached; surfaced in JSON only behind `health --complexity-breakdown`.
908 pub contributions: Vec<ComplexityContribution>,
909}
910
911/// Structural CSS metrics for a single style rule, computed from the parsed CSS
912/// syntax tree. A rule is recorded only when it crosses a structural floor (an
913/// id selector, a complex selector, a `!important` declaration, or deep
914/// nesting), so the vector stays bounded on normal stylesheets.
915///
916/// Not persisted in the extraction cache: `fallow health` computes these
917/// on demand from the CSS source, so there is no `bitcode` derive.
918#[derive(Debug, Clone, serde::Serialize)]
919#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
920pub struct CssRuleMetric {
921 /// 1-based line of the rule's first selector.
922 pub line: u32,
923 /// 1-based column of the rule's first selector.
924 pub col: u32,
925 /// Specificity component `a` (id selectors), max across the rule's selectors.
926 pub specificity_a: u16,
927 /// Specificity component `b` (class / attribute / pseudo-class selectors).
928 pub specificity_b: u16,
929 /// Specificity component `c` (type / pseudo-element selectors).
930 pub specificity_c: u16,
931 /// Largest selector component count across the rule's selector list.
932 pub complexity: u16,
933 /// Declaration count in the rule (normal plus `!important`).
934 pub declaration_count: u16,
935 /// `!important` declaration count in the rule.
936 pub important_count: u16,
937 /// Style-rule nesting depth (0 = top level).
938 pub nesting_depth: u8,
939}
940
941/// A style rule's declaration-block fingerprint and location, for cross-file
942/// duplicate-block detection. Only rules with a meaningful number of
943/// declarations are recorded (small blocks repeat legitimately). Internal
944/// staging only: this is consumed in-process by the health layer to build the
945/// grouped `duplicate_declaration_blocks` output and is never serialized.
946#[derive(Debug, Clone)]
947pub struct CssDeclarationBlock {
948 /// xxh3 fingerprint over the rule's normalized (sorted, `!important`-tagged)
949 /// declaration set.
950 pub fingerprint: u64,
951 /// 1-based line of the rule's first selector.
952 pub line: u32,
953 /// Declaration count in the rule (normal plus `!important`).
954 pub declaration_count: u16,
955}
956
957/// Stylesheet-level structural CSS analytics, computed from the parsed CSS
958/// syntax tree. Feeds `fallow health` penalty weights and located findings,
959/// never a standalone CSS score.
960#[derive(Debug, Clone, Default, serde::Serialize)]
961#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
962pub struct CssAnalytics {
963 /// Total declarations across every style rule (normal plus `!important`).
964 pub total_declarations: u32,
965 /// Total `!important` declarations across every style rule.
966 pub important_declarations: u32,
967 /// Number of style rules.
968 pub rule_count: u32,
969 /// Number of style rules with no declarations.
970 pub empty_rule_count: u32,
971 /// Deepest style-rule nesting depth observed (0 = no nesting).
972 pub max_nesting_depth: u8,
973 /// Rules that crossed the structural floor, in source order. Bounded; see
974 /// [`Self::notable_truncated`]. The scalar aggregates above always reflect
975 /// the full stylesheet regardless of truncation.
976 pub notable_rules: Vec<CssRuleMetric>,
977 /// `true` when more rules crossed the structural floor than `notable_rules`
978 /// retains (compiled utility CSS can emit thousands of `!important` rules),
979 /// so consumers can note that per-rule findings were capped.
980 pub notable_truncated: bool,
981 /// Distinct color VALUES in the stylesheet, sorted (a palette-size /
982 /// design-token-sprawl signal). The parser canonicalizes notation, so the
983 /// authored format is NOT preserved: `red`, `#f00`, `#ff0000`, and
984 /// `rgb(255,0,0)` all collapse to one entry, and every legacy sRGB notation
985 /// renders as hex. Notation-MIXING (hex vs rgb vs hsl) is therefore not
986 /// detectable from this set; it would need a separate raw-token pass.
987 pub colors: Vec<String>,
988 /// Distinct `font-size` declaration values in the stylesheet, sorted.
989 pub font_sizes: Vec<String>,
990 /// Distinct `z-index` declaration values in the stylesheet, sorted.
991 pub z_indexes: Vec<String>,
992 /// Distinct `box-shadow` declaration values in the stylesheet, sorted. A
993 /// high count signals an uncontrolled shadow scale (design-token sprawl).
994 pub box_shadows: Vec<String>,
995 /// Distinct `border-radius` declaration values in the stylesheet, sorted.
996 pub border_radii: Vec<String>,
997 /// Distinct `line-height` declaration values in the stylesheet, sorted.
998 pub line_heights: Vec<String>,
999 /// Distinct custom properties (`--x`) DEFINED in the stylesheet, sorted.
1000 pub defined_custom_properties: Vec<String>,
1001 /// Distinct custom properties REFERENCED via `var()` in the stylesheet.
1002 pub referenced_custom_properties: Vec<String>,
1003 /// Distinct `@keyframes` names DEFINED in the stylesheet, sorted.
1004 pub defined_keyframes: Vec<String>,
1005 /// Distinct `@keyframes` names REFERENCED via `animation` / `animation-name`.
1006 pub referenced_keyframes: Vec<String>,
1007 /// Distinct custom properties REGISTERED via an `@property` rule, sorted.
1008 pub registered_custom_properties: Vec<String>,
1009 /// Distinct cascade layers DECLARED (via `@layer a, b;` statements or named
1010 /// `@layer a { }` blocks), sorted.
1011 pub declared_layers: Vec<String>,
1012 /// Distinct cascade layers POPULATED by a named `@layer a { }` block, sorted.
1013 /// A layer declared but never populated (and not imported into) is a
1014 /// cleanup candidate.
1015 pub populated_layers: Vec<String>,
1016 /// Distinct font families DECLARED by an `@font-face` rule in the stylesheet,
1017 /// sorted. A declared family referenced by no `font-family` anywhere is a
1018 /// dead web-font payload (cleanup candidate).
1019 pub defined_font_faces: Vec<String>,
1020 /// Distinct font families REFERENCED via `font-family` / `font` in the
1021 /// stylesheet, sorted (generic keywords like `serif` excluded).
1022 pub referenced_font_families: Vec<String>,
1023 /// Per-rule declaration-block fingerprints for rules at or above the minimum
1024 /// block size, used to detect duplicate declaration blocks across the
1025 /// project. Internal staging consumed by the health layer; never serialized
1026 /// (the public output is the grouped `duplicate_declaration_blocks`).
1027 #[serde(skip)]
1028 #[cfg_attr(feature = "schema", schemars(skip))]
1029 pub declaration_blocks: Vec<CssDeclarationBlock>,
1030}
1031
1032/// Which complexity metric a [`ComplexityContribution`] adds to.
1033#[derive(Debug, Clone, Copy, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1034#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1035#[serde(rename_all = "kebab-case")]
1036pub enum ComplexityMetric {
1037 /// `McCabe` cyclomatic complexity (independent execution paths).
1038 Cyclomatic,
1039 /// `SonarSource` cognitive complexity (structural + nesting penalty).
1040 Cognitive,
1041}
1042
1043/// The syntactic construct that produced a single complexity increment.
1044///
1045/// Mirrors `SonarSource` cognitive-complexity vocabulary where it overlaps.
1046/// `Case` means a `case` label carrying a test; a bare `default` adds nothing
1047/// to cyclomatic complexity and so produces no contribution.
1048#[derive(Debug, Clone, Copy, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1049#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1050#[serde(rename_all = "kebab-case")]
1051pub enum ComplexityContributionKind {
1052 /// An `if` condition.
1053 If,
1054 /// A bare `else` branch (cognitive only).
1055 Else,
1056 /// An `else if` continuation (both metrics: cyclomatic +1, cognitive flat
1057 /// +1 with no nesting penalty).
1058 ElseIf,
1059 /// A `?:` conditional (ternary) expression.
1060 Ternary,
1061 /// A logical `&&` operator.
1062 LogicalAnd,
1063 /// A logical `||` operator.
1064 LogicalOr,
1065 /// A `??` nullish-coalescing operator.
1066 NullishCoalescing,
1067 /// A logical assignment operator (`&&=`, `||=`, `??=`); cyclomatic only.
1068 LogicalAssignment,
1069 /// An optional-chaining link (`?.`); cyclomatic only.
1070 OptionalChain,
1071 /// A `for` loop.
1072 For,
1073 /// A `for...in` loop.
1074 ForIn,
1075 /// A `for...of` loop.
1076 ForOf,
1077 /// A `while` loop.
1078 While,
1079 /// A `do...while` loop.
1080 DoWhile,
1081 /// A `switch` statement (cognitive only; each `case` adds cyclomatic).
1082 Switch,
1083 /// A `case` label carrying a test (cyclomatic only).
1084 Case,
1085 /// A `catch` clause.
1086 Catch,
1087 /// A labeled `break` (cognitive only).
1088 LabeledBreak,
1089 /// A labeled `continue` (cognitive only).
1090 LabeledContinue,
1091 /// Legacy JSX-depth contribution kind kept for schema compatibility. Current
1092 /// extraction records JSX nesting as descriptive `react_jsx_max_depth`
1093 /// context and does not emit this kind for layout depth.
1094 JsxDepth,
1095 /// React hook density (cognitive only). One contribution per hook call in a
1096 /// component body (`useState` / `useEffect` / `useMemo` / `useCallback` /
1097 /// custom `use*`); a hook-heavy component accrues cognitive load the same way
1098 /// branching does.
1099 HookDensity,
1100 /// React prop count past the comfortable floor (cognitive only). A component
1101 /// destructuring many props is doing many things; the props beyond the floor
1102 /// fold into cognitive so a wide-interface component surfaces as a hotspot.
1103 PropCount,
1104}
1105
1106/// A single complexity increment, located at its source line/column.
1107///
1108/// `weight` is the amount this construct added to `metric`; for nested
1109/// cognitive increments `weight == 1 + nesting`. Consumers that render inline
1110/// (the VS Code editor breakdown) group contributions by `line` and sum the
1111/// weights, deferring the per-kind list to a hover.
1112#[derive(Debug, Clone, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1113#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1114pub struct ComplexityContribution {
1115 /// 1-based line number where the construct begins.
1116 pub line: u32,
1117 /// 0-based byte column where the construct begins.
1118 pub col: u32,
1119 /// Which metric this increment contributes to.
1120 pub metric: ComplexityMetric,
1121 /// The syntactic construct responsible for the increment.
1122 pub kind: ComplexityContributionKind,
1123 /// The amount added to `metric` at this site (`1 + nesting` for nested
1124 /// cognitive increments, otherwise `1`).
1125 pub weight: u16,
1126 /// The nesting depth at the increment site (`0` when not nested). Lets a
1127 /// consumer explain a cognitive `+3` as "+1 base, +2 nesting".
1128 pub nesting: u16,
1129}
1130
1131/// The kind of feature flag pattern detected.
1132#[derive(Debug, Clone, Copy, PartialEq, Eq, bitcode::Encode, bitcode::Decode)]
1133pub enum FlagUseKind {
1134 /// `process.env.FEATURE_X` pattern.
1135 EnvVar,
1136 /// SDK function call like `useFlag('name')`.
1137 SdkCall,
1138 /// Config object access like `config.features.x`.
1139 ConfigObject,
1140}
1141
1142/// A feature flag use site.
1143#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode)]
1144pub struct FlagUse {
1145 /// Flag identifier.
1146 pub flag_name: String,
1147 /// Detection kind.
1148 pub kind: FlagUseKind,
1149 /// 1-based line number.
1150 pub line: u32,
1151 /// 0-based byte column offset.
1152 pub col: u32,
1153 /// Start byte offset of the guarded block.
1154 pub guard_span_start: Option<u32>,
1155 /// End byte offset of the guarded block.
1156 pub guard_span_end: Option<u32>,
1157 /// SDK/provider name.
1158 pub sdk_name: Option<String>,
1159}
1160
1161const _: () = assert!(std::mem::size_of::<FlagUse>() <= 96);
1162
1163/// A dynamic import with a partially resolved pattern.
1164#[derive(Debug, Clone)]
1165pub struct DynamicImportPattern {
1166 /// Static prefix of the import path (e.g., "./locales/"). May contain glob characters.
1167 pub prefix: String,
1168 /// Static suffix of the import path (e.g., ".json"), if any.
1169 pub suffix: Option<String>,
1170 /// Source span in the original file.
1171 pub span: Span,
1172}
1173
1174/// Visibility tag from JSDoc/TSDoc comments that suppresses unused-export detection.
1175#[derive(Debug, Clone, Copy, Default, PartialEq, Eq, serde::Serialize, serde::Deserialize)]
1176#[serde(rename_all = "lowercase")]
1177#[repr(u8)]
1178pub enum VisibilityTag {
1179 /// No visibility tag present.
1180 #[default]
1181 None = 0,
1182 /// `@public` or `@api public` -- part of the public API surface.
1183 Public = 1,
1184 /// `@internal` -- exported for internal use (sister packages, build tools).
1185 Internal = 2,
1186 /// `@beta` -- public but unstable, may change without notice.
1187 Beta = 3,
1188 /// `@alpha` -- early preview, may change drastically without notice.
1189 Alpha = 4,
1190 /// `@expected-unused` -- intentionally unused, should warn when it becomes used.
1191 ExpectedUnused = 5,
1192}
1193
1194impl VisibilityTag {
1195 /// Whether this tag permanently suppresses unused-export detection.
1196 /// `ExpectedUnused` is handled separately (conditionally suppresses,
1197 /// reports stale when the export becomes used).
1198 pub const fn suppresses_unused(self) -> bool {
1199 matches!(
1200 self,
1201 Self::Public | Self::Internal | Self::Beta | Self::Alpha
1202 )
1203 }
1204
1205 /// For serde `skip_serializing_if`.
1206 pub fn is_none(&self) -> bool {
1207 matches!(self, Self::None)
1208 }
1209}
1210
1211/// An export declaration.
1212#[derive(Debug, Clone, serde::Serialize)]
1213pub struct ExportInfo {
1214 /// The exported name (named or default).
1215 pub name: ExportName,
1216 /// The local binding name, if different from the exported name.
1217 pub local_name: Option<String>,
1218 /// Whether this is a type-only export (`export type`).
1219 pub is_type_only: bool,
1220 /// Whether this export is registered through a runtime side effect at module load time.
1221 #[serde(default, skip_serializing_if = "std::ops::Not::not")]
1222 pub is_side_effect_used: bool,
1223 /// Visibility tag from JSDoc/TSDoc comment.
1224 #[serde(default, skip_serializing_if = "VisibilityTag::is_none")]
1225 pub visibility: VisibilityTag,
1226 /// Human-authored reason on `@expected-unused -- <reason>`, when present.
1227 #[serde(default, skip_serializing_if = "Option::is_none")]
1228 pub expected_unused_reason: Option<String>,
1229 /// Source span of the export declaration.
1230 #[serde(serialize_with = "serialize_span")]
1231 pub span: Span,
1232 /// Members of this export (for enums, classes, and namespaces).
1233 #[serde(default, skip_serializing_if = "Vec::is_empty")]
1234 pub members: Vec<MemberInfo>,
1235 /// The local name of the parent class from `extends` clause, if any.
1236 #[serde(default, skip_serializing_if = "Option::is_none")]
1237 pub super_class: Option<String>,
1238}
1239
1240/// Additional heritage metadata for an exported class.
1241#[derive(
1242 Debug,
1243 Clone,
1244 serde::Serialize,
1245 serde::Deserialize,
1246 bitcode::Encode,
1247 bitcode::Decode,
1248 PartialEq,
1249 Eq,
1250)]
1251pub struct ClassHeritageInfo {
1252 /// Export name (`default` for default-exported classes).
1253 pub export_name: String,
1254 /// Parent class name from the `extends` clause, if any.
1255 pub super_class: Option<String>,
1256 /// Interface names from the class `implements` clause.
1257 pub implements: Vec<String>,
1258 /// Typed instance bindings used to resolve member-access chains in external templates.
1259 #[serde(default, skip_serializing_if = "Vec::is_empty")]
1260 pub instance_bindings: Vec<(String, String)>,
1261}
1262
1263/// An exported free-function factory proven to return one class instance.
1264///
1265/// `export function useApi() { return new RESTApi() }` records
1266/// `FactoryReturnExport { export_name: "useApi", class_local_name: "RESTApi" }`.
1267/// The `class_local_name` is the factory module's own LOCAL name, resolved at
1268/// analyze time through that module's imports/exports to the real class export,
1269/// so a cross-module `const x = useApi(); x.member` consumer credits the class
1270/// across the boundary. See issue #1441 (Part A).
1271#[derive(
1272 Debug,
1273 Clone,
1274 serde::Serialize,
1275 serde::Deserialize,
1276 bitcode::Encode,
1277 bitcode::Decode,
1278 PartialEq,
1279 Eq,
1280)]
1281pub struct FactoryReturnExport {
1282 /// Public export name (honors `export { useApi as useRestApi }`).
1283 pub export_name: String,
1284 /// The returned class's local name within the factory module.
1285 pub class_local_name: String,
1286}
1287
1288/// A module-scope declaration that can be used as a TypeScript type.
1289#[derive(Debug, Clone, serde::Serialize, PartialEq, Eq)]
1290pub struct LocalTypeDeclaration {
1291 /// Local declaration name.
1292 pub name: String,
1293 /// Declaration identifier span.
1294 #[serde(serialize_with = "serialize_span")]
1295 pub span: Span,
1296}
1297
1298/// A reference from an exported symbol's public signature to a type name.
1299#[derive(Debug, Clone, serde::Serialize, PartialEq, Eq)]
1300pub struct PublicSignatureTypeReference {
1301 /// Exported symbol whose signature contains the reference.
1302 pub export_name: String,
1303 /// Referenced type name. Qualified names are reduced to their root identifier.
1304 pub type_name: String,
1305 /// Reference span.
1306 #[serde(serialize_with = "serialize_span")]
1307 pub span: Span,
1308}
1309
1310/// A member of an enum, class, or namespace.
1311#[derive(Debug, Clone, serde::Serialize)]
1312pub struct MemberInfo {
1313 /// Member name.
1314 pub name: String,
1315 /// The kind of member (enum, class method/property, or namespace member).
1316 pub kind: MemberKind,
1317 /// Source span of the member declaration.
1318 #[serde(serialize_with = "serialize_span")]
1319 pub span: Span,
1320 /// Whether this member has decorators (e.g., `@Column()`, `@Inject()`).
1321 /// Decorated members are used by frameworks at runtime and should not be
1322 /// flagged as unused class members, unless every decorator on the member
1323 /// is opted out via `FallowConfig.ignore_decorators`.
1324 #[serde(default, skip_serializing_if = "std::ops::Not::not")]
1325 pub has_decorator: bool,
1326 /// Full dotted path of each decorator on this member, in source order.
1327 /// `@step("x")` stores `"step"`; `@ns.foo` stores `"ns.foo"`. Empty for
1328 /// undecorated members, Angular signal-initializer properties (which set
1329 /// `has_decorator` without a literal decorator AST node), and decorators
1330 /// whose expression is not an identifier ladder (the entry is the empty
1331 /// string in that case, treated as never-matching by the predicate).
1332 #[serde(default, skip_serializing_if = "Vec::is_empty")]
1333 pub decorator_names: Vec<String>,
1334 /// True when this is a static class method that returns a fresh instance
1335 /// of the same class: either via `return new this()` / `return new
1336 /// <SameClassName>()` in the body's last statement, or via a declared
1337 /// return type matching the class name. Consumers calling such a static
1338 /// method receive an instance, so the call result's member accesses are
1339 /// credited against the class. See issues #346, #387.
1340 #[serde(default, skip_serializing_if = "std::ops::Not::not")]
1341 pub is_instance_returning_static: bool,
1342 /// True when this is an instance class method whose call result is an
1343 /// instance of the same class. Qualifies when the declared return type
1344 /// matches the class name (`setX(): EventBuilder { ... }`) or when the
1345 /// body's last statement is `return this`. The analyze layer walks fluent
1346 /// chains (`Class.factory().setX().setY()`) only through methods carrying
1347 /// this flag, so the chain stops at a non-self-returning method like
1348 /// `.build()`. See issue #387.
1349 #[serde(default, skip_serializing_if = "std::ops::Not::not")]
1350 pub is_self_returning: bool,
1351}
1352
1353/// The kind of member.
1354#[derive(
1355 Debug,
1356 Clone,
1357 Copy,
1358 PartialEq,
1359 Eq,
1360 serde::Serialize,
1361 serde::Deserialize,
1362 bitcode::Encode,
1363 bitcode::Decode,
1364)]
1365#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1366#[serde(rename_all = "snake_case")]
1367pub enum MemberKind {
1368 /// A TypeScript enum member.
1369 EnumMember,
1370 /// A class method.
1371 ClassMethod,
1372 /// A class property.
1373 ClassProperty,
1374 /// A member exported from a TypeScript namespace.
1375 NamespaceMember,
1376 /// A member declared by a store object (Pinia `state` / `getters` /
1377 /// `actions` key, or a setup-store returned key). Cross-graph dead-member
1378 /// detection: a store member never accessed by any consumer project-wide.
1379 StoreMember,
1380}
1381
1382/// A static member access expression (e.g., `Status.Active`, `MyClass.create()`).
1383#[derive(Debug, Clone, serde::Serialize, serde::Deserialize, bitcode::Encode, bitcode::Decode)]
1384pub struct MemberAccess {
1385 /// The identifier being accessed (the import name).
1386 pub object: String,
1387 /// The member being accessed.
1388 pub member: String,
1389}
1390
1391/// A typed extraction fact for cross-layer analysis.
1392#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1393#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1394#[serde(tag = "kind", rename_all = "snake_case")]
1395pub enum SemanticFact {
1396 /// A class member referenced from an Angular template, host binding, or
1397 /// component metadata entry.
1398 AngularTemplateMemberAccess(AngularTemplateMemberAccessFact),
1399 /// An Angular component spreads `this` into an object literal, so component
1400 /// input/output usage is opaque.
1401 AngularThisSpread(AngularThisSpreadFact),
1402 /// A member access on a value returned by an imported static factory call.
1403 FactoryCallMemberAccess(FactoryCallMemberAccessFact),
1404 /// A member access on a value returned by an imported free-function factory
1405 /// (`const x = importedFactory(); x.member`). See issue #1441 (Part A).
1406 FactoryFnMemberAccess(FactoryFnMemberAccessFact),
1407 /// A member access on a fluent chain rooted at an imported static factory.
1408 FluentChainMemberAccess(FluentChainMemberAccessFact),
1409 /// A member access on a fluent chain rooted at a `new` expression.
1410 FluentChainNewMemberAccess(FluentChainNewMemberAccessFact),
1411 /// A member access on a Playwright fixture object inside a test callback.
1412 PlaywrightFixtureUse(PlaywrightFixtureUseFact),
1413 /// A Playwright fixture definition declared by a typed `test.extend<T>()`.
1414 PlaywrightFixtureDefinition(PlaywrightFixtureDefinitionFact),
1415 /// A Playwright fixture wrapper alias declared by `mergeTests` or `.extend`.
1416 PlaywrightFixtureAlias(PlaywrightFixtureAliasFact),
1417 /// A nested Playwright fixture binding declared by a fixture type alias.
1418 PlaywrightFixtureType(PlaywrightFixtureTypeFact),
1419 /// An exported value whose runtime instance targets a local class or interface.
1420 InstanceExportBinding(InstanceExportBindingFact),
1421 /// A dynamic custom-element tag render that makes static Lit tag credit opaque.
1422 DynamicCustomElementRender(DynamicCustomElementRenderFact),
1423}
1424
1425/// Iterate Angular template member names from typed semantic facts.
1426fn angular_template_member_names_from_parts(
1427 semantic_facts: &[SemanticFact],
1428) -> impl Iterator<Item = &str> {
1429 semantic_facts.iter().filter_map(|fact| {
1430 if let SemanticFact::AngularTemplateMemberAccess(access) = fact {
1431 Some(access.member.as_str())
1432 } else {
1433 None
1434 }
1435 })
1436}
1437
1438/// Iterate Angular template member names from a module's typed facts.
1439pub fn angular_template_member_names(module: &ModuleInfo) -> impl Iterator<Item = &str> {
1440 angular_template_member_names_from_parts(&module.semantic_facts)
1441}
1442
1443/// Return true when the fact slice contains any Angular template member
1444/// reference.
1445#[must_use]
1446fn has_angular_template_members_from_parts(semantic_facts: &[SemanticFact]) -> bool {
1447 angular_template_member_names_from_parts(semantic_facts)
1448 .next()
1449 .is_some()
1450}
1451
1452/// Return true when the module contains any Angular template member reference.
1453#[must_use]
1454pub fn has_angular_template_members(module: &ModuleInfo) -> bool {
1455 has_angular_template_members_from_parts(&module.semantic_facts)
1456}
1457
1458/// Return true when a module spreads `this` in Angular template context.
1459#[must_use]
1460pub fn has_angular_this_spread(module: &ModuleInfo) -> bool {
1461 SemanticFactView::new(&module.semantic_facts, &module.member_accesses).has_angular_this_spread()
1462}
1463
1464/// Return true when a module contains a dynamic custom-element render.
1465#[must_use]
1466pub fn has_dynamic_custom_element_render(module: &ModuleInfo) -> bool {
1467 module
1468 .semantic_facts
1469 .iter()
1470 .any(|fact| matches!(fact, SemanticFact::DynamicCustomElementRender(_)))
1471}
1472
1473/// Typed-first view over semantic extraction facts.
1474///
1475/// Extraction populates `semantic_facts` directly. The `member_accesses` slice
1476/// remains available for consumers that need ordinary source member accesses,
1477/// but it is no longer decoded as a string protocol for semantic facts.
1478#[derive(Debug, Clone, Copy)]
1479pub struct SemanticFactView<'a> {
1480 semantic_facts: &'a [SemanticFact],
1481 member_accesses: &'a [MemberAccess],
1482}
1483
1484impl<'a> SemanticFactView<'a> {
1485 /// Create a typed semantic fact view from current semantic facts plus
1486 /// ordinary source member accesses.
1487 #[must_use]
1488 pub const fn new(
1489 semantic_facts: &'a [SemanticFact],
1490 member_accesses: &'a [MemberAccess],
1491 ) -> Self {
1492 Self {
1493 semantic_facts,
1494 member_accesses,
1495 }
1496 }
1497
1498 /// Iterate typed semantic facts.
1499 pub fn facts(self) -> impl Iterator<Item = &'a SemanticFact> + 'a {
1500 self.semantic_facts.iter()
1501 }
1502
1503 /// Iterate Angular template member references.
1504 pub fn angular_template_member_names(self) -> impl Iterator<Item = &'a str> + 'a {
1505 angular_template_member_names_from_parts(self.semantic_facts)
1506 }
1507
1508 /// Return true when any Angular template member reference exists.
1509 #[must_use]
1510 pub fn has_angular_template_members(self) -> bool {
1511 self.angular_template_member_names().next().is_some()
1512 }
1513
1514 /// Return true when a module spreads `this` in Angular template context.
1515 #[must_use]
1516 pub fn has_angular_this_spread(self) -> bool {
1517 self.semantic_facts
1518 .iter()
1519 .any(|fact| matches!(fact, SemanticFact::AngularThisSpread(_)))
1520 }
1521
1522 /// Iterate ordinary source member accesses.
1523 pub fn ordinary_member_accesses(self) -> impl Iterator<Item = &'a MemberAccess> + 'a {
1524 self.member_accesses.iter()
1525 }
1526
1527 /// Collect instance-export binding facts.
1528 pub fn instance_export_bindings(self) -> Vec<InstanceExportBindingFact> {
1529 instance_export_binding_facts(self.semantic_facts)
1530 .cloned()
1531 .collect()
1532 }
1533
1534 /// Collect static factory call member facts.
1535 pub fn factory_call_member_accesses(self) -> Vec<FactoryCallMemberAccessFact> {
1536 factory_call_member_access_facts(self.semantic_facts)
1537 .cloned()
1538 .collect()
1539 }
1540
1541 /// Collect free-function factory-return member facts.
1542 pub fn factory_fn_member_accesses(self) -> Vec<FactoryFnMemberAccessFact> {
1543 factory_fn_member_access_facts(self.semantic_facts)
1544 .cloned()
1545 .collect()
1546 }
1547
1548 /// Collect static factory fluent-chain member facts.
1549 pub fn fluent_chain_member_accesses(self) -> Vec<FluentChainMemberAccessFact> {
1550 fluent_chain_member_access_facts(self.semantic_facts)
1551 .cloned()
1552 .collect()
1553 }
1554
1555 /// Collect constructor-rooted fluent-chain member facts.
1556 pub fn fluent_chain_new_member_accesses(self) -> Vec<FluentChainNewMemberAccessFact> {
1557 fluent_chain_new_member_access_facts(self.semantic_facts)
1558 .cloned()
1559 .collect()
1560 }
1561
1562 /// Collect Playwright fixture-use facts.
1563 pub fn playwright_fixture_uses(self) -> Vec<PlaywrightFixtureUseFact> {
1564 playwright_fixture_use_facts(self.semantic_facts)
1565 .cloned()
1566 .collect()
1567 }
1568
1569 /// Collect Playwright fixture-definition facts.
1570 pub fn playwright_fixture_definitions(self) -> Vec<PlaywrightFixtureDefinitionFact> {
1571 playwright_fixture_definition_facts(self.semantic_facts)
1572 .cloned()
1573 .collect()
1574 }
1575
1576 /// Collect Playwright fixture-alias facts.
1577 pub fn playwright_fixture_aliases(self) -> Vec<PlaywrightFixtureAliasFact> {
1578 playwright_fixture_alias_facts(self.semantic_facts)
1579 .cloned()
1580 .collect()
1581 }
1582
1583 /// Collect Playwright fixture-type facts.
1584 pub fn playwright_fixture_types(self) -> Vec<PlaywrightFixtureTypeFact> {
1585 playwright_fixture_type_facts(self.semantic_facts)
1586 .cloned()
1587 .collect()
1588 }
1589}
1590
1591/// Iterate ordinary whole-object uses.
1592pub fn ordinary_whole_object_uses(whole_object_uses: &[String]) -> impl Iterator<Item = &str> {
1593 whole_object_uses.iter().map(String::as_str)
1594}
1595
1596/// Iterate typed instance-export binding facts.
1597fn instance_export_binding_facts(
1598 semantic_facts: &[SemanticFact],
1599) -> impl Iterator<Item = &InstanceExportBindingFact> {
1600 semantic_facts.iter().filter_map(|fact| {
1601 if let SemanticFact::InstanceExportBinding(access) = fact {
1602 Some(access)
1603 } else {
1604 None
1605 }
1606 })
1607}
1608
1609/// Iterate typed factory-call member facts.
1610fn factory_call_member_access_facts(
1611 semantic_facts: &[SemanticFact],
1612) -> impl Iterator<Item = &FactoryCallMemberAccessFact> {
1613 semantic_facts.iter().filter_map(|fact| {
1614 if let SemanticFact::FactoryCallMemberAccess(access) = fact {
1615 Some(access)
1616 } else {
1617 None
1618 }
1619 })
1620}
1621
1622/// Iterate typed free-function factory-return member facts.
1623fn factory_fn_member_access_facts(
1624 semantic_facts: &[SemanticFact],
1625) -> impl Iterator<Item = &FactoryFnMemberAccessFact> {
1626 semantic_facts.iter().filter_map(|fact| {
1627 if let SemanticFact::FactoryFnMemberAccess(access) = fact {
1628 Some(access)
1629 } else {
1630 None
1631 }
1632 })
1633}
1634
1635/// Iterate typed fluent-chain member facts.
1636fn fluent_chain_member_access_facts(
1637 semantic_facts: &[SemanticFact],
1638) -> impl Iterator<Item = &FluentChainMemberAccessFact> {
1639 semantic_facts.iter().filter_map(|fact| {
1640 if let SemanticFact::FluentChainMemberAccess(access) = fact {
1641 Some(access)
1642 } else {
1643 None
1644 }
1645 })
1646}
1647
1648/// Iterate typed constructor-rooted fluent-chain member facts.
1649fn fluent_chain_new_member_access_facts(
1650 semantic_facts: &[SemanticFact],
1651) -> impl Iterator<Item = &FluentChainNewMemberAccessFact> {
1652 semantic_facts.iter().filter_map(|fact| {
1653 if let SemanticFact::FluentChainNewMemberAccess(access) = fact {
1654 Some(access)
1655 } else {
1656 None
1657 }
1658 })
1659}
1660
1661/// Iterate typed Playwright fixture-use facts.
1662fn playwright_fixture_use_facts(
1663 semantic_facts: &[SemanticFact],
1664) -> impl Iterator<Item = &PlaywrightFixtureUseFact> {
1665 semantic_facts.iter().filter_map(|fact| {
1666 if let SemanticFact::PlaywrightFixtureUse(access) = fact {
1667 Some(access)
1668 } else {
1669 None
1670 }
1671 })
1672}
1673
1674/// Iterate typed Playwright fixture-definition facts.
1675fn playwright_fixture_definition_facts(
1676 semantic_facts: &[SemanticFact],
1677) -> impl Iterator<Item = &PlaywrightFixtureDefinitionFact> {
1678 semantic_facts.iter().filter_map(|fact| {
1679 if let SemanticFact::PlaywrightFixtureDefinition(access) = fact {
1680 Some(access)
1681 } else {
1682 None
1683 }
1684 })
1685}
1686
1687/// Iterate typed Playwright fixture-alias facts.
1688fn playwright_fixture_alias_facts(
1689 semantic_facts: &[SemanticFact],
1690) -> impl Iterator<Item = &PlaywrightFixtureAliasFact> {
1691 semantic_facts.iter().filter_map(|fact| {
1692 if let SemanticFact::PlaywrightFixtureAlias(access) = fact {
1693 Some(access)
1694 } else {
1695 None
1696 }
1697 })
1698}
1699
1700/// Iterate typed Playwright fixture-type facts.
1701fn playwright_fixture_type_facts(
1702 semantic_facts: &[SemanticFact],
1703) -> impl Iterator<Item = &PlaywrightFixtureTypeFact> {
1704 semantic_facts.iter().filter_map(|fact| {
1705 if let SemanticFact::PlaywrightFixtureType(access) = fact {
1706 Some(access)
1707 } else {
1708 None
1709 }
1710 })
1711}
1712
1713/// A member name referenced from an Angular template surface.
1714#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1715#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1716pub struct AngularTemplateMemberAccessFact {
1717 /// Referenced class member name.
1718 pub member: String,
1719}
1720
1721/// Opaque Angular `{ ...this }` forwarding marker.
1722#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1723#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1724pub struct AngularThisSpreadFact;
1725
1726/// A member access on a static factory call result.
1727#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1728#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1729pub struct FactoryCallMemberAccessFact {
1730 /// Local imported class or namespace object used as the factory callee.
1731 pub callee_object: String,
1732 /// Static factory method invoked on the callee object.
1733 pub callee_method: String,
1734 /// Member accessed on the returned instance-like object.
1735 pub member: String,
1736}
1737
1738/// A member access on a value returned by an imported free-function factory.
1739///
1740/// `const x = importedFactory(); x.member` emits one fact per first-level read
1741/// on `x`. The analyze layer resolves `callee_name` through the consumer's
1742/// imports to the factory's origin module, reads that module's
1743/// `exported_factory_returns` to learn the returned class's local name, resolves
1744/// THAT through the factory module's own imports to the class export, and
1745/// credits `member` on the class. See issue #1441 (Part A).
1746#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1747#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1748pub struct FactoryFnMemberAccessFact {
1749 /// Local imported function used as the factory callee.
1750 pub callee_name: String,
1751 /// Member accessed on the returned instance-like object.
1752 pub member: String,
1753}
1754
1755/// A member access on a fluent chain rooted at a static factory call.
1756#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1757#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1758pub struct FluentChainMemberAccessFact {
1759 /// Local imported class or namespace object used as the chain root.
1760 pub root_object: String,
1761 /// Static factory method that starts the fluent chain.
1762 pub root_method: String,
1763 /// Intermediate fluent methods between the root method and final member.
1764 pub chain: Vec<String>,
1765 /// Member accessed at this chain step.
1766 pub member: String,
1767}
1768
1769/// A member access on a fluent chain rooted at a `new` expression.
1770#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1771#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1772pub struct FluentChainNewMemberAccessFact {
1773 /// Local imported class constructed by the `new` expression.
1774 pub class_name: String,
1775 /// Intermediate fluent methods between construction and final member.
1776 pub chain: Vec<String>,
1777 /// Member accessed at this chain step.
1778 pub member: String,
1779}
1780
1781/// A member access on a Playwright fixture object inside a test callback.
1782#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1783#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1784pub struct PlaywrightFixtureUseFact {
1785 /// Local test function or wrapper used as the callback callee.
1786 pub test_name: String,
1787 /// Fixture name or dotted fixture path referenced in the callback.
1788 pub fixture_name: String,
1789 /// Member accessed on the fixture target.
1790 pub member: String,
1791}
1792
1793/// A Playwright fixture definition declared by a typed `test.extend<T>()`.
1794#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1795#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1796pub struct PlaywrightFixtureDefinitionFact {
1797 /// Local test function or wrapper receiving the fixture definition.
1798 pub test_name: String,
1799 /// Fixture name or dotted fixture path declared by the fixture type.
1800 pub fixture_name: String,
1801 /// Local type symbol used as the fixture target.
1802 pub type_name: String,
1803}
1804
1805/// A Playwright fixture wrapper alias declared by `mergeTests` or `.extend`.
1806#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1807#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1808pub struct PlaywrightFixtureAliasFact {
1809 /// Local test function or wrapper that inherits fixture definitions.
1810 pub test_name: String,
1811 /// Local test function or wrapper inherited by `test_name`.
1812 pub base_name: String,
1813}
1814
1815/// A nested Playwright fixture binding declared by a fixture type alias.
1816#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1817#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1818pub struct PlaywrightFixtureTypeFact {
1819 /// Local type alias containing the nested fixture binding.
1820 pub alias_name: String,
1821 /// Fixture name or dotted fixture path declared inside the type alias.
1822 pub fixture_name: String,
1823 /// Local type symbol used as the nested fixture target.
1824 pub type_name: String,
1825}
1826
1827/// An exported value whose runtime instance targets a local class or interface.
1828#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1829#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1830pub struct InstanceExportBindingFact {
1831 /// Exported binding name.
1832 pub export_name: String,
1833 /// Local class or interface symbol used as the instance target.
1834 pub target_name: String,
1835}
1836
1837/// Opaque marker for a dynamic custom-element render site.
1838#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, bitcode::Encode, bitcode::Decode)]
1839#[cfg_attr(feature = "schema", derive(schemars::JsonSchema))]
1840pub struct DynamicCustomElementRenderFact;
1841
1842/// A statically flattenable callee path invoked in a module (e.g. `execSync`,
1843/// `child_process.exec`, `console.log`). One entry per unique `callee_path`
1844/// per module; the span anchors the first occurrence. Consumed by the
1845/// `boundaries.calls.forbidden` detector.
1846#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode)]
1847pub struct CalleeUse {
1848 /// The dotted or bare callee path as written at the call site.
1849 pub callee_path: String,
1850 /// Start byte offset of the first call site using this path.
1851 pub span_start: u32,
1852}
1853
1854/// A `"use client"` / `"use server"` directive string written as an expression
1855/// statement in `program.body` (NOT the leading prologue), so the RSC bundler
1856/// silently ignores it. One entry per offending occurrence. Consumed by the
1857/// `misplaced-directive` detector.
1858#[derive(Debug, Clone, PartialEq, Eq, bitcode::Encode, bitcode::Decode)]
1859pub struct MisplacedDirectiveSite {
1860 /// `true` for `"use server"`, `false` for `"use client"`.
1861 pub is_server: bool,
1862 /// Start byte offset of the misplaced directive statement.
1863 pub span_start: u32,
1864}
1865
1866/// Which side of a dependency-injection link a call site represents.
1867#[derive(Debug, Clone, Copy, PartialEq, Eq, bitcode::Encode, bitcode::Decode)]
1868pub enum DiRole {
1869 /// `provide(KEY, value)` / `app.provide(KEY, value)` / `setContext(KEY, value)`.
1870 Provide,
1871 /// `inject(KEY)` / `getContext(KEY)`.
1872 Inject,
1873}
1874
1875/// Which framework's DI API a call site came from (drives the finding message).
1876#[derive(Debug, Clone, Copy, PartialEq, Eq, bitcode::Encode, bitcode::Decode)]
1877pub enum DiFramework {
1878 /// Vue `provide` / `inject` (from `vue` / `@vue/runtime-core`).
1879 Vue,
1880 /// Svelte `setContext` / `getContext` (from `svelte`).
1881 Svelte,
1882 /// Angular `inject(TOKEN)` / `@Inject(TOKEN)` (from `@angular/core`),
1883 /// matched against `{ provide: TOKEN, ... }` provider objects.
1884 Angular,
1885}
1886
1887/// A Vue `provide`/`inject` or Svelte `setContext`/`getContext` call site keyed
1888/// by an identifier symbol. The `key_local` is resolved at analyze time through
1889/// the consuming module's import/export tables to a canonical defining-site
1890/// export key, so a provide and an inject of the same shared symbol unify even
1891/// across barrel re-exports. Consumed by the `unprovided-inject` detector.
1892#[derive(Debug, Clone, PartialEq, Eq, bitcode::Encode, bitcode::Decode)]
1893pub struct DiKeySite {
1894 /// The key identifier as written at the call site.
1895 pub key_local: String,
1896 /// Whether this is a provide or an inject.
1897 pub role: DiRole,
1898 /// Which framework's API this came from.
1899 pub framework: DiFramework,
1900 /// Start byte offset of the call expression (anchors the finding).
1901 pub span_start: u32,
1902}
1903
1904/// A component prop declared by Vue `<script setup>` `defineProps` or Svelte 5
1905/// `$props()`. `used_in_script` / `used_in_template` are set during extraction;
1906/// the `unused-component-prop` detector flags a prop where neither is true. See
1907/// `harvest_define_props` and `harvest_svelte_props` in `sfc_props.rs`.
1908#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode)]
1909pub struct ComponentProp {
1910 /// The declared prop name.
1911 pub name: String,
1912 /// The template/script-visible local binding name: the destructure alias for
1913 /// `const { name: alias } = defineProps()` or
1914 /// `let { name: alias } = $props()`, otherwise the prop name itself. A
1915 /// renamed prop is read through this local, so usage must be checked against
1916 /// it, not the declared name.
1917 pub local: String,
1918 /// Start byte offset of the prop declaration (anchors the finding).
1919 pub span_start: u32,
1920 /// Whether this prop is referenced in the component's `<script>` (a
1921 /// destructured local binding with a resolved reference, or a `props.<name>`
1922 /// member access). For React, this is set-in-body: a resolved reference to the
1923 /// destructured local anywhere in the component function body.
1924 pub used_in_script: bool,
1925 /// Whether this prop name is referenced in the component's `<template>`.
1926 /// Set by `apply_template_usage` when the template scanner credits the name.
1927 /// Always false for React (no template; React uses `used_in_script`).
1928 pub used_in_template: bool,
1929 /// The enclosing component name. Empty for Vue SFCs (one component per file,
1930 /// the file stem is the component, set by the detector). For React this is the
1931 /// component function/arrow name a prop was declared on, so the detector can
1932 /// emit the right `component_name` and apply the per-component abstain ladder
1933 /// (a file can declare several React components).
1934 pub component: String,
1935 /// React-only: `true` when the destructured prop local is referenced at least
1936 /// once OUTSIDE a child-JSX attribute value expression (a substantive
1937 /// consumption: a hook arg, a host-element child, a non-JSX-attr read). When
1938 /// `used_in_script` is true but this is false, the prop is referenced ONLY as
1939 /// the root of forwarded child attribute values, i.e. a pure pass-through.
1940 /// Always `false` for Vue (no forward-vs-consume distinction is computed).
1941 pub used_outside_forward: bool,
1942}
1943
1944/// A Vue `<script setup>` `defineEmits` declared event, harvested from the type
1945/// tuple-call form (`defineEmits<{ (e: 'foo'): void }>()`), the type object form
1946/// (`defineEmits<{ foo: [x: string] }>()`), or the runtime array form
1947/// (`defineEmits(['foo'])`). `used` is set during extraction when the bound emit
1948/// name is called as `emit('<name>')`. The `unused-component-emit` detector flags
1949/// an event where `used` is false. See `harvest_define_emits` in `sfc_props.rs`.
1950#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode, PartialEq, Eq)]
1951pub struct ComponentEmit {
1952 /// The declared emit event name.
1953 pub name: String,
1954 /// Start byte offset of the emit declaration (anchors the finding).
1955 pub span_start: u32,
1956 /// Whether this event is emitted via `emit('<name>')` somewhere in the
1957 /// component's `<script>`.
1958 pub used: bool,
1959}
1960
1961/// A Svelte custom event dispatched via `dispatch('<name>')`, where `dispatch`
1962/// is the binding from a `const dispatch = createEventDispatcher()` call. Only
1963/// literal-first-arg dispatches are recorded; a `dispatch(<nonLiteral>)` sets
1964/// `ModuleInfo::has_dynamic_dispatch` instead. Consumed by the
1965/// `unused-svelte-event` detector, which flags an event dispatched here but
1966/// listened to nowhere project-wide (the cross-file dead-output direction). The
1967/// span is a byte offset (not an `oxc_span::Span`) so the type round-trips
1968/// through the bitcode cache directly, mirroring `ComponentEmit::span_start`.
1969#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode, PartialEq, Eq)]
1970pub struct DispatchedEvent {
1971 /// The dispatched event name (the literal first argument).
1972 pub name: String,
1973 /// Start byte offset of the `dispatch(...)` call (anchors the finding).
1974 pub span_start: u32,
1975}
1976
1977/// A declared Angular component/directive input, harvested from an `@Input()`
1978/// decorator or a signal `input()` / `input.required()` / `model()` initializer
1979/// on an Angular-decorated class. Consumed by the `unused-component-input`
1980/// detector, which flags an input read nowhere in its own component (neither the
1981/// template nor the class body). The span is stored as a byte offset (not an
1982/// `oxc_span::Span`) so the type is cheap to mirror onto the cache, matching
1983/// `ComponentEmit::span_start`. `ModuleInfo` is not serialized, so no serde
1984/// attrs are derived here. `bitcode` derives let the type be mirrored directly
1985/// onto `CachedModule` (the same pattern as `ComponentEmit`).
1986#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode, PartialEq, Eq)]
1987pub struct AngularInputMember {
1988 /// The declared input name (the property key).
1989 pub name: String,
1990 /// Start byte offset of the property key (anchors the finding).
1991 pub span_start: u32,
1992}
1993
1994/// A declared Angular component/directive output, harvested from an `@Output()`
1995/// decorator or a signal `output()` / `outputFromObservable()` initializer on an
1996/// Angular-decorated class. Consumed by the `unused-component-output` detector,
1997/// which flags an output emitted nowhere in its own component. A `model()` is an
1998/// input and a framework-driven output, so it is recorded ONLY as an input and
1999/// never appears here (the implicit `update:` emit is framework-managed). The
2000/// span is a byte offset for the same reason as `AngularInputMember`.
2001#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode, PartialEq, Eq)]
2002pub struct AngularOutputMember {
2003 /// The declared output name (the property key).
2004 pub name: String,
2005 /// Start byte offset of the property key (anchors the finding).
2006 pub span_start: u32,
2007}
2008
2009/// A declared Angular `@Component` and its `selector` value(s), harvested from a
2010/// `@Component({ selector: '...' })` decorator. Consumed by the Angular arm of
2011/// the `unrendered-component` detector, which flags a component whose every
2012/// element selector is used in NO template project-wide (and that is not
2013/// referenced by class name anywhere, e.g. routed / bootstrapped / dynamically
2014/// rendered). A multi-selector string (`'app-foo, [appBar]'`) is split into the
2015/// `selectors` list. The span is stored as a byte offset (not an
2016/// `oxc_span::Span`) so the type round-trips through the bitcode cache directly,
2017/// mirroring `AngularInputMember::span_start`. `@Directive` is intentionally NOT
2018/// harvested here (directives have no template render). `ModuleInfo` is not
2019/// serialized, so no serde attrs are derived.
2020#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode, PartialEq, Eq)]
2021pub struct AngularComponentSelector {
2022 /// The declared selector strings for this component, split on `,`. A purely
2023 /// element-selector component has only `app-foo`-shaped entries; attribute
2024 /// (`[appFoo]`) and class (`.foo`) selectors are retained verbatim so the
2025 /// detector can abstain when ANY non-element selector is present.
2026 pub selectors: Vec<String>,
2027 /// Start byte offset of the component class declaration (anchors the
2028 /// finding).
2029 pub span_start: u32,
2030 /// The component class name (used to credit routed / bootstrapped / dynamic
2031 /// class-name references project-wide).
2032 pub class_name: String,
2033}
2034
2035/// A Lit / web-component custom element registered in a module via
2036/// `@customElement('x-foo')` or `customElements.define('x-foo', C)`. Consumed by
2037/// the Lit arm of the `unrendered-component` detector. The span is stored as a
2038/// byte offset (not an `oxc_span::Span`) so the type round-trips through the
2039/// bitcode cache directly, mirroring `AngularComponentSelector::span_start`.
2040#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode, PartialEq, Eq)]
2041pub struct RegisteredCustomElement {
2042 /// The registered custom-element tag name (`x-foo`).
2043 pub tag: String,
2044 /// The registering class's local name, used for the public-API / export
2045 /// abstain (an exported / published element is rendered by a downstream
2046 /// consumer the scan cannot see). Empty for an anonymous
2047 /// `export default @customElement('x-foo') class extends LitElement {}`.
2048 pub class_local_name: String,
2049 /// Start byte offset of the registering class declaration (anchors the
2050 /// finding at the element, NOT line 1, since a `.ts` file can register
2051 /// several custom elements).
2052 pub span_start: u32,
2053}
2054
2055/// A key returned from a SvelteKit route `load()` function's terminal return
2056/// object literal. Harvested from `+page.{ts,server.ts,js,server.js}` files
2057/// exporting a `load` function. Consumed by the `unused-load-data-key` detector,
2058/// which flags a key read by no consumer. The span is stored as byte offsets
2059/// (not an `oxc_span::Span`) so the type round-trips through the bitcode cache
2060/// directly, mirroring `DiKeySite::span_start` / `ComponentEmit::span_start`.
2061#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode, PartialEq, Eq)]
2062pub struct LoadReturnKey {
2063 /// The returned-object property key name.
2064 pub name: String,
2065 /// Start byte offset of the key (anchors the finding).
2066 pub span_start: u32,
2067 /// End byte offset of the key.
2068 pub span_end: u32,
2069}
2070
2071/// The syntactic shape of an identified React component definition. Drives the
2072/// abstain ladder later phases apply: a `forwardRef` / `memo` wrapper whose
2073/// props come from an imported interface fallow cannot resolve must abstain
2074/// (ADR-001), not guess.
2075#[derive(Debug, Clone, Copy, PartialEq, Eq, bitcode::Encode, bitcode::Decode)]
2076pub enum ComponentFunctionKind {
2077 /// A `function Foo() { return <.../> }` declaration.
2078 FnDecl,
2079 /// A `const Foo = () => <.../>` arrow (or function-expression) binding.
2080 Arrow,
2081 /// A `const Foo = forwardRef((props, ref) => <.../>)` wrapper.
2082 ForwardRefWrapper,
2083 /// A `const Foo = memo((props) => <.../>)` wrapper.
2084 MemoWrapper,
2085}
2086
2087/// An identified React component: a function/arrow whose body returns JSX.
2088/// Captured by `visit_jsx_element`'s enclosing-component tracking. The
2089/// `unused-component-prop` (React arm) and complexity-fold phases consume this;
2090/// the abstain flags keep zero-FP on the cases ADR-001 cannot resolve.
2091#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode)]
2092pub struct ComponentFunction {
2093 /// The component name (the binding or declaration identifier).
2094 pub name: String,
2095 /// Start byte offset of the component definition (anchors findings).
2096 pub span_start: u32,
2097 /// The syntactic shape of the definition.
2098 pub kind: ComponentFunctionKind,
2099 /// Whether the component is exported from its module (a named export, a
2100 /// `export default`, or re-exported in the same module). Public-API
2101 /// components abstain in the prop phase.
2102 pub is_exported: bool,
2103 /// `true` when the component's props are not statically harvestable: a
2104 /// rest/spread in the signature (`{ ...rest }`), props passed wholesale to a
2105 /// hook/helper, or a `forwardRef` / `memo` wrapper whose props come from an
2106 /// imported interface generic fallow cannot resolve (ADR-001). The prop
2107 /// phase abstains on the whole component when set.
2108 pub has_unharvestable_props: bool,
2109 /// `true` when the component body calls `cloneElement` / `React.cloneElement`.
2110 /// `cloneElement` injects props by reflection, so the static forward-set is
2111 /// incomplete; the prop-drilling phase abstains on any chain through this
2112 /// component (ADR-001, zero-FP).
2113 pub uses_clone_element: bool,
2114 /// `true` when the component renders a `*.Provider` member-expression tag
2115 /// (`<FooContext.Provider>`). A context provider in the subtree means the
2116 /// drilling may be a deliberate non-context choice (or the prop is about to
2117 /// be provided); the prop-drilling phase downgrades/abstains.
2118 pub renders_provider: bool,
2119 /// `true` when the component passes a function as a child render value
2120 /// (render-props / children-as-function: `<Foo>{() => ...}</Foo>` or
2121 /// `<Foo render={() => ...}/>`). The forwarded shape is dynamic; the
2122 /// prop-drilling phase abstains on chains through this component.
2123 pub has_children_as_function: bool,
2124 /// `true` when the component body is pure structural indirection: a single
2125 /// statement returning exactly one capitalized/member-expression JSX element
2126 /// (no host wrapper, no extra children, optionally a fragment wrapping a
2127 /// single element) that forwards props via a bare spread of the component's
2128 /// own props binding / rest local (`<Child {...props}/>`), with NO named
2129 /// attributes alongside the spread and NO self-render. The cross-component
2130 /// `thin-wrapper` phase joins this with hook-density / cyclomatic checks and
2131 /// the resolved single render edge to flag a component that is a candidate
2132 /// for inlining. Computed from the component's own AST only, so it caches
2133 /// byte-identity-safe (ADR-001).
2134 pub is_pure_passthrough: bool,
2135}
2136
2137/// The kind of a React hook call. `Custom` covers any `use*`-named call that is
2138/// not one of the built-in hooks.
2139#[derive(Debug, Clone, Copy, PartialEq, Eq, bitcode::Encode, bitcode::Decode)]
2140pub enum HookUseKind {
2141 /// `useState(...)`.
2142 UseState,
2143 /// `useEffect(...)`.
2144 UseEffect,
2145 /// `useMemo(...)`.
2146 UseMemo,
2147 /// `useCallback(...)`.
2148 UseCallback,
2149 /// Any other `use*`-named call (a custom hook).
2150 Custom,
2151}
2152
2153/// A React hook call site inside a component. Consumed by the complexity-fold
2154/// phase (hook density) and surfaced as descriptive hotspot context.
2155#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode)]
2156pub struct HookUse {
2157 /// The hook kind.
2158 pub kind: HookUseKind,
2159 /// The dependency-array arity, recorded ONLY when a literal array is present
2160 /// at the dependency-array position (`[a, b]` -> `Some(2)`, `[]` ->
2161 /// `Some(0)`). `None` when the call has no dependency array argument or the
2162 /// argument is not a literal array (ADR-001: do not guess).
2163 pub dep_array_arity: Option<u32>,
2164 /// Start byte offset of the hook call (anchors findings).
2165 pub span_start: u32,
2166 /// The enclosing component name (the top of the visitor's component stack
2167 /// when the hook call was recorded). Lets the descriptive per-component hook
2168 /// summary attribute hooks exactly even when a file declares several
2169 /// components. A hook recorded outside any component carries an empty string
2170 /// (the visitor only records hooks inside a component, so this is the
2171 /// rare top-level / unattributed case).
2172 pub component: String,
2173}
2174
2175/// A render edge: one component rendering another (a capitalized or
2176/// member-expression JSX tag). Captured at extraction time with the child's
2177/// written name; resolution of `child_component_name` to a `FileId`/export is
2178/// deferred to graph build via the existing import map.
2179#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode)]
2180pub struct RenderEdge {
2181 /// The name of the component that renders the child (the enclosing
2182 /// component). Empty when the JSX is not inside an identified component (a
2183 /// top-level render expression).
2184 pub parent_component: String,
2185 /// The rendered child component name as written (`Foo` or the full
2186 /// member-expression path `Foo.Bar`).
2187 pub child_component_name: String,
2188 /// The attribute (prop) names passed at the render site, in source order.
2189 pub attr_names: Vec<String>,
2190 /// `true` when the render site contains a JSX spread (`{...x}`), so the
2191 /// passed-prop set is not statically complete.
2192 pub has_spread: bool,
2193 /// The forwarded attributes at this render site: each pairs the child
2194 /// attribute NAME with the identifier ROOT of its value expression
2195 /// (`userName={user.name}` -> `{ attr: "userName", root: "user" }`;
2196 /// `value={x}` -> `{ attr: "value", root: "x" }`). ONLY plain identifier or
2197 /// member-root access values are recorded (`{x}`, `{x.y}`, `{x.y.z}`); a value
2198 /// that is a call, an arrow/function, a conditional, a JSX element, or any
2199 /// other complex expression is NOT recorded here (its root would not be a pure
2200 /// forward) and sets `has_complex_forward` instead. The prop-drilling chain
2201 /// walk uses this pairing to map "this component forwards prop P" to "the
2202 /// child receives it as attribute A".
2203 pub forward_attrs: Vec<ForwardAttr>,
2204 /// `true` when at least one attribute value at this render site is a complex
2205 /// expression (a call, an arrow/function render-prop, a conditional, a JSX
2206 /// element-as-prop, a template literal, etc.) whose identifier root was NOT
2207 /// recorded in `forward_attrs`. The prop-drilling phase abstains on a chain
2208 /// whose forwarded prop flows through such a value (ADR-001, zero-FP).
2209 pub has_complex_forward: bool,
2210}
2211
2212/// One forwarded JSX attribute: the child attribute name plus the identifier
2213/// root of its value expression. See [`RenderEdge::forward_attrs`].
2214#[derive(Debug, Clone, bitcode::Encode, bitcode::Decode)]
2215pub struct ForwardAttr {
2216 /// The child attribute (prop) name as written (`userName`).
2217 pub attr: String,
2218 /// The identifier root of the attribute value expression (`user` for
2219 /// `userName={user.name}`).
2220 pub root: String,
2221}
2222
2223#[expect(
2224 clippy::trivially_copy_pass_by_ref,
2225 reason = "serde serialize_with requires &T"
2226)]
2227fn serialize_span<S: serde::Serializer>(span: &Span, serializer: S) -> Result<S::Ok, S::Error> {
2228 use serde::ser::SerializeMap;
2229 let mut map = serializer.serialize_map(Some(2))?;
2230 map.serialize_entry("start", &span.start)?;
2231 map.serialize_entry("end", &span.end)?;
2232 map.end()
2233}
2234
2235/// Export identifier.
2236#[derive(Debug, Clone, PartialEq, Eq, Hash, serde::Serialize, serde::Deserialize)]
2237pub enum ExportName {
2238 /// A named export (e.g., `export const foo`).
2239 Named(String),
2240 /// The default export.
2241 Default,
2242}
2243
2244impl ExportName {
2245 /// Compare against a string without allocating (avoids `to_string()`).
2246 #[must_use]
2247 pub fn matches_str(&self, s: &str) -> bool {
2248 match self {
2249 Self::Named(n) => n == s,
2250 Self::Default => s == "default",
2251 }
2252 }
2253}
2254
2255impl std::fmt::Display for ExportName {
2256 fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
2257 match self {
2258 Self::Named(n) => write!(f, "{n}"),
2259 Self::Default => write!(f, "default"),
2260 }
2261 }
2262}
2263
2264/// An import declaration.
2265#[derive(Debug, Clone)]
2266pub struct ImportInfo {
2267 /// The import specifier (e.g., `./utils` or `react`).
2268 pub source: String,
2269 /// How the symbol is imported (named, default, namespace, or side-effect).
2270 pub imported_name: ImportedName,
2271 /// The local binding name in the importing module.
2272 pub local_name: String,
2273 /// Whether this is a type-only import (`import type`).
2274 pub is_type_only: bool,
2275 /// Whether this import originated from a CSS-context.
2276 pub from_style: bool,
2277 /// Source span of the import declaration.
2278 pub span: Span,
2279 /// Span of the source string literal used by the LSP to highlight the specifier.
2280 pub source_span: Span,
2281}
2282
2283/// How a symbol is imported.
2284#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, serde::Deserialize)]
2285pub enum ImportedName {
2286 /// A named import (e.g., `import { foo }`).
2287 Named(String),
2288 /// A default import (e.g., `import React`).
2289 Default,
2290 /// A namespace import (e.g., `import * as utils`).
2291 Namespace,
2292 /// A side-effect import (e.g., `import './styles.css'`).
2293 SideEffect,
2294}
2295
2296#[cfg(target_pointer_width = "64")]
2297const _: () = assert!(std::mem::size_of::<ExportInfo>() == 136);
2298#[cfg(target_pointer_width = "64")]
2299const _: () = assert!(std::mem::size_of::<ImportInfo>() == 96);
2300#[cfg(target_pointer_width = "64")]
2301const _: () = assert!(std::mem::size_of::<ExportName>() == 24);
2302#[cfg(target_pointer_width = "64")]
2303const _: () = assert!(std::mem::size_of::<ImportedName>() == 24);
2304#[cfg(target_pointer_width = "64")]
2305const _: () = assert!(std::mem::size_of::<MemberAccess>() == 48);
2306#[cfg(target_pointer_width = "64")]
2307const _: () = assert!(std::mem::size_of::<SemanticFact>() == 96);
2308#[cfg(target_pointer_width = "64")]
2309const _: () = assert!(std::mem::size_of::<SinkSite>() == 216);
2310#[cfg(target_pointer_width = "64")]
2311const _: () = assert!(std::mem::size_of::<ModuleInfo>() == 1320);
2312
2313/// A re-export declaration.
2314#[derive(Debug, Clone)]
2315pub struct ReExportInfo {
2316 /// The module being re-exported from.
2317 pub source: String,
2318 /// The name imported from the source module (or `*` for star re-exports).
2319 pub imported_name: String,
2320 /// The name exported from this module.
2321 pub exported_name: String,
2322 /// Whether this is a type-only re-export.
2323 pub is_type_only: bool,
2324 /// Source span of the re-export declaration on this module.
2325 pub span: oxc_span::Span,
2326}
2327
2328/// A dynamic `import()` call.
2329#[derive(Debug, Clone)]
2330pub struct DynamicImportInfo {
2331 /// The import specifier.
2332 pub source: String,
2333 /// Source span of the `import()` expression.
2334 pub span: Span,
2335 /// Names destructured from the dynamic import result.
2336 /// Non-empty means `const { a, b } = await import(...)` -> Named imports.
2337 /// Empty means simple `import(...)` or `const x = await import(...)` -> Namespace.
2338 pub destructured_names: Vec<String>,
2339 /// The local variable name for `const x = await import(...)`.
2340 /// Used for namespace import narrowing via member access tracking.
2341 pub local_name: Option<String>,
2342 /// True when this dynamic import was synthesised by fallow rather than appearing in user source.
2343 pub is_speculative: bool,
2344}
2345
2346/// A `require()` call.
2347#[derive(Debug, Clone)]
2348pub struct RequireCallInfo {
2349 /// The require specifier.
2350 pub source: String,
2351 /// Source span of the `require()` call.
2352 pub span: Span,
2353 /// Source span of the specifier string-literal argument (including its
2354 /// quotes), e.g. the `'./x'` in `require('./x')`. Used to anchor an
2355 /// `unresolved-import` diagnostic squiggly under the specifier rather than
2356 /// the `require` keyword. `Span::default()` when the argument is not a
2357 /// plain string literal.
2358 pub source_span: Span,
2359 /// Names destructured from the `require()` result.
2360 pub destructured_names: Vec<String>,
2361 /// The local variable name for `const x = require(...)`.
2362 pub local_name: Option<String>,
2363}
2364
2365/// Result of parsing all files, including incremental cache statistics.
2366pub struct ParseResult {
2367 /// Extracted module information for all successfully parsed files.
2368 pub modules: Vec<ModuleInfo>,
2369 /// Number of files whose parse results were loaded from cache (unchanged).
2370 pub cache_hits: usize,
2371 /// Number of files that required a full parse (new or changed).
2372 pub cache_misses: usize,
2373 /// Summed wall-clock time of the actual AST parses across all rayon workers.
2374 pub parse_cpu_ms: f64,
2375}
2376
2377#[cfg(test)]
2378mod tests {
2379 use super::*;
2380
2381 fn span() -> Span {
2382 Span::new(0, 1)
2383 }
2384
2385 macro_rules! assert_released {
2386 ($values:expr) => {{
2387 assert!($values.is_empty());
2388 }};
2389 }
2390
2391 #[test]
2392 fn public_env_var_includes_public_ci_metadata() {
2393 for name in ["TAG_REF", "GITHUB_SHA", "CI_COMMIT_BRANCH", "APP_MODE"] {
2394 assert!(is_public_env_var(name), "{name} should be public metadata");
2395 }
2396 }
2397
2398 #[test]
2399 fn public_env_var_keeps_secret_shaped_names_source_backed() {
2400 for name in ["GITHUB_TOKEN", "REFRESH_TOKEN", "API_KEY", "SECRET_SHA"] {
2401 assert!(
2402 !is_public_env_var(name),
2403 "{name} should remain secret-shaped"
2404 );
2405 }
2406 }
2407
2408 #[test]
2409 fn ordinary_access_helpers_keep_source_accesses() {
2410 let member_accesses = vec![
2411 MemberAccess {
2412 object: "this".to_string(),
2413 member: "render".to_string(),
2414 },
2415 MemberAccess {
2416 object: "service".to_string(),
2417 member: "run".to_string(),
2418 },
2419 ];
2420 let ordinary = SemanticFactView::new(&[], &member_accesses)
2421 .ordinary_member_accesses()
2422 .map(|access| (access.object.as_str(), access.member.as_str()))
2423 .collect::<Vec<_>>();
2424
2425 assert_eq!(ordinary, vec![("this", "render"), ("service", "run")]);
2426
2427 let whole_object_uses = vec!["model".to_string(), "service".to_string()];
2428
2429 assert_eq!(
2430 ordinary_whole_object_uses(&whole_object_uses).collect::<Vec<_>>(),
2431 vec!["model", "service"]
2432 );
2433 }
2434
2435 #[test]
2436 fn angular_template_member_names_use_typed_facts() {
2437 let mut module = minimal_module_info();
2438 push_semantic_fact(
2439 &mut module,
2440 SemanticFact::AngularTemplateMemberAccess(AngularTemplateMemberAccessFact {
2441 member: "typed".to_string(),
2442 }),
2443 );
2444
2445 let names: Vec<&str> = angular_template_member_names(&module).collect();
2446
2447 assert_eq!(names, vec!["typed"]);
2448 assert!(has_angular_template_members(&module));
2449 }
2450
2451 #[test]
2452 fn angular_this_spread_uses_typed_fact() {
2453 let mut typed = minimal_module_info();
2454 push_semantic_fact(
2455 &mut typed,
2456 SemanticFact::AngularThisSpread(AngularThisSpreadFact),
2457 );
2458
2459 assert!(has_angular_this_spread(&typed));
2460 assert!(!has_angular_this_spread(&minimal_module_info()));
2461 }
2462
2463 #[test]
2464 fn semantic_fact_view_iterates_typed_facts() {
2465 let mut module = minimal_module_info();
2466 push_semantic_fact(
2467 &mut module,
2468 SemanticFact::FactoryCallMemberAccess(FactoryCallMemberAccessFact {
2469 callee_object: "Svc".to_string(),
2470 callee_method: "make".to_string(),
2471 member: "run".to_string(),
2472 }),
2473 );
2474
2475 let facts = SemanticFactView::new(&module.semantic_facts, &module.member_accesses)
2476 .facts()
2477 .collect::<Vec<_>>();
2478
2479 assert_eq!(
2480 facts[0],
2481 &SemanticFact::FactoryCallMemberAccess(FactoryCallMemberAccessFact {
2482 callee_object: "Svc".to_string(),
2483 callee_method: "make".to_string(),
2484 member: "run".to_string(),
2485 })
2486 );
2487 }
2488
2489 #[test]
2490 fn typed_fact_helpers_collect_each_family() {
2491 let mut module = minimal_module_info();
2492 push_semantic_fact(
2493 &mut module,
2494 SemanticFact::InstanceExportBinding(InstanceExportBindingFact {
2495 export_name: "exported".to_string(),
2496 target_name: "target".to_string(),
2497 }),
2498 );
2499 push_semantic_fact(
2500 &mut module,
2501 SemanticFact::FactoryCallMemberAccess(FactoryCallMemberAccessFact {
2502 callee_object: "Svc".to_string(),
2503 callee_method: "create".to_string(),
2504 member: "run".to_string(),
2505 }),
2506 );
2507 push_semantic_fact(
2508 &mut module,
2509 SemanticFact::FluentChainMemberAccess(FluentChainMemberAccessFact {
2510 root_object: "Builder".to_string(),
2511 root_method: "start".to_string(),
2512 chain: vec!["next".to_string()],
2513 member: "value".to_string(),
2514 }),
2515 );
2516 push_semantic_fact(
2517 &mut module,
2518 SemanticFact::FluentChainNewMemberAccess(FluentChainNewMemberAccessFact {
2519 class_name: "Builder".to_string(),
2520 chain: vec!["next".to_string(), "finish".to_string()],
2521 member: "done".to_string(),
2522 }),
2523 );
2524
2525 assert_eq!(
2526 SemanticFactView::new(&module.semantic_facts, &module.member_accesses)
2527 .instance_export_bindings(),
2528 vec![InstanceExportBindingFact {
2529 export_name: "exported".to_string(),
2530 target_name: "target".to_string(),
2531 }]
2532 );
2533 assert_eq!(
2534 SemanticFactView::new(&module.semantic_facts, &module.member_accesses)
2535 .factory_call_member_accesses(),
2536 vec![FactoryCallMemberAccessFact {
2537 callee_object: "Svc".to_string(),
2538 callee_method: "create".to_string(),
2539 member: "run".to_string(),
2540 }]
2541 );
2542 assert_eq!(
2543 SemanticFactView::new(&module.semantic_facts, &module.member_accesses)
2544 .fluent_chain_member_accesses(),
2545 vec![FluentChainMemberAccessFact {
2546 root_object: "Builder".to_string(),
2547 root_method: "start".to_string(),
2548 chain: vec!["next".to_string()],
2549 member: "value".to_string(),
2550 }]
2551 );
2552 assert_eq!(
2553 SemanticFactView::new(&module.semantic_facts, &module.member_accesses)
2554 .fluent_chain_new_member_accesses(),
2555 vec![FluentChainNewMemberAccessFact {
2556 class_name: "Builder".to_string(),
2557 chain: vec!["next".to_string(), "finish".to_string()],
2558 member: "done".to_string(),
2559 }]
2560 );
2561 }
2562
2563 #[test]
2564 fn semantic_fact_view_exposes_typed_first_contract() {
2565 let mut module = minimal_module_info();
2566 push_semantic_fact(
2567 &mut module,
2568 SemanticFact::FactoryCallMemberAccess(FactoryCallMemberAccessFact {
2569 callee_object: "Svc".to_string(),
2570 callee_method: "create".to_string(),
2571 member: "run".to_string(),
2572 }),
2573 );
2574 push_semantic_fact(
2575 &mut module,
2576 SemanticFact::PlaywrightFixtureUse(PlaywrightFixtureUseFact {
2577 test_name: "test".to_string(),
2578 fixture_name: "page".to_string(),
2579 member: "goto".to_string(),
2580 }),
2581 );
2582 push_semantic_fact(
2583 &mut module,
2584 SemanticFact::InstanceExportBinding(InstanceExportBindingFact {
2585 export_name: "exported".to_string(),
2586 target_name: "target".to_string(),
2587 }),
2588 );
2589
2590 let view = SemanticFactView::new(&module.semantic_facts, &module.member_accesses);
2591
2592 assert_eq!(
2593 view.factory_call_member_accesses(),
2594 vec![FactoryCallMemberAccessFact {
2595 callee_object: "Svc".to_string(),
2596 callee_method: "create".to_string(),
2597 member: "run".to_string(),
2598 }]
2599 );
2600 assert_eq!(
2601 view.playwright_fixture_uses(),
2602 vec![PlaywrightFixtureUseFact {
2603 test_name: "test".to_string(),
2604 fixture_name: "page".to_string(),
2605 member: "goto".to_string(),
2606 }]
2607 );
2608 assert_eq!(
2609 view.instance_export_bindings(),
2610 vec![InstanceExportBindingFact {
2611 export_name: "exported".to_string(),
2612 target_name: "target".to_string(),
2613 }]
2614 );
2615 }
2616
2617 #[test]
2618 fn playwright_fixture_fact_helpers_select_each_fact_family() {
2619 let mut module = minimal_module_info();
2620 push_semantic_fact(
2621 &mut module,
2622 SemanticFact::PlaywrightFixtureUse(PlaywrightFixtureUseFact {
2623 test_name: "test".to_string(),
2624 fixture_name: "page".to_string(),
2625 member: "goto".to_string(),
2626 }),
2627 );
2628 push_semantic_fact(
2629 &mut module,
2630 SemanticFact::PlaywrightFixtureDefinition(PlaywrightFixtureDefinitionFact {
2631 test_name: "test".to_string(),
2632 fixture_name: "adminPage".to_string(),
2633 type_name: "AdminPage".to_string(),
2634 }),
2635 );
2636 push_semantic_fact(
2637 &mut module,
2638 SemanticFact::PlaywrightFixtureAlias(PlaywrightFixtureAliasFact {
2639 test_name: "mergedTest".to_string(),
2640 base_name: "test".to_string(),
2641 }),
2642 );
2643 push_semantic_fact(
2644 &mut module,
2645 SemanticFact::PlaywrightFixtureType(PlaywrightFixtureTypeFact {
2646 alias_name: "Pages".to_string(),
2647 fixture_name: "adminPage".to_string(),
2648 type_name: "AdminPage".to_string(),
2649 }),
2650 );
2651
2652 assert_eq!(
2653 playwright_fixture_use_facts(&module.semantic_facts)
2654 .map(|fact| fact.member.as_str())
2655 .collect::<Vec<_>>(),
2656 vec!["goto"]
2657 );
2658 assert_eq!(
2659 playwright_fixture_definition_facts(&module.semantic_facts)
2660 .map(|fact| fact.type_name.as_str())
2661 .collect::<Vec<_>>(),
2662 vec!["AdminPage"]
2663 );
2664 assert_eq!(
2665 playwright_fixture_alias_facts(&module.semantic_facts)
2666 .map(|fact| fact.base_name.as_str())
2667 .collect::<Vec<_>>(),
2668 vec!["test"]
2669 );
2670 assert_eq!(
2671 playwright_fixture_type_facts(&module.semantic_facts)
2672 .map(|fact| fact.fixture_name.as_str())
2673 .collect::<Vec<_>>(),
2674 vec!["adminPage"]
2675 );
2676 }
2677
2678 #[test]
2679 fn line_offsets_empty_string() {
2680 assert_eq!(compute_line_offsets(""), vec![0]);
2681 }
2682
2683 #[test]
2684 #[expect(
2685 clippy::too_many_lines,
2686 reason = "exhaustive field-by-field construction + release assertions for every ModuleInfo field"
2687 )]
2688 fn release_resolution_payload_drops_copied_vectors_only() {
2689 let mut module = ModuleInfo {
2690 file_id: FileId(7),
2691 exports: vec![ExportInfo {
2692 name: ExportName::Named("kept".to_string()),
2693 local_name: None,
2694 is_type_only: false,
2695 is_side_effect_used: false,
2696 visibility: VisibilityTag::None,
2697 expected_unused_reason: None,
2698 span: span(),
2699 members: Vec::new(),
2700 super_class: None,
2701 }],
2702 imports: vec![ImportInfo {
2703 source: "node:child_process".to_string(),
2704 imported_name: ImportedName::Default,
2705 local_name: "childProcess".to_string(),
2706 is_type_only: false,
2707 from_style: false,
2708 span: span(),
2709 source_span: span(),
2710 }],
2711 re_exports: vec![ReExportInfo {
2712 source: "./kept".to_string(),
2713 imported_name: "kept".to_string(),
2714 exported_name: "kept".to_string(),
2715 is_type_only: false,
2716 span: span(),
2717 }],
2718 dynamic_imports: vec![DynamicImportInfo {
2719 source: "./dynamic".to_string(),
2720 span: span(),
2721 destructured_names: vec!["value".to_string()],
2722 local_name: None,
2723 is_speculative: false,
2724 }],
2725 dynamic_import_patterns: vec![DynamicImportPattern {
2726 prefix: "./pages/".to_string(),
2727 suffix: Some(".tsx".to_string()),
2728 span: span(),
2729 }],
2730 require_calls: vec![RequireCallInfo {
2731 source: "./required".to_string(),
2732 span: span(),
2733 source_span: span(),
2734 destructured_names: Vec::new(),
2735 local_name: Some("required".to_string()),
2736 }],
2737 package_path_references: vec!["react".to_string()].into(),
2738 member_accesses: vec![MemberAccess {
2739 object: "Status".to_string(),
2740 member: "Active".to_string(),
2741 }],
2742 semantic_facts: Box::default(),
2743 whole_object_uses: vec!["Status".to_string()].into(),
2744 has_cjs_exports: true,
2745 has_angular_component_template_url: true,
2746 content_hash: 42,
2747 suppressions: Vec::new(),
2748 unknown_suppression_kinds: Vec::new(),
2749 unused_import_bindings: vec!["unused".to_string()],
2750 type_referenced_import_bindings: vec!["TypeOnly".to_string()],
2751 value_referenced_import_bindings: vec!["Value".to_string()],
2752 line_offsets: vec![0, 8],
2753 complexity: vec![FunctionComplexity {
2754 name: "work".to_string(),
2755 line: 1,
2756 col: 0,
2757 cyclomatic: 2,
2758 cognitive: 3,
2759 line_count: 4,
2760 param_count: 1,
2761 react_hook_count: 0,
2762 react_jsx_max_depth: 0,
2763 react_prop_count: 0,
2764 source_hash: Some("hash".to_string()),
2765 contributions: Vec::new(),
2766 }],
2767 flag_uses: vec![FlagUse {
2768 flag_name: "FEATURE_X".to_string(),
2769 kind: FlagUseKind::EnvVar,
2770 line: 1,
2771 col: 0,
2772 guard_span_start: None,
2773 guard_span_end: None,
2774 sdk_name: None,
2775 }],
2776 class_heritage: vec![ClassHeritageInfo {
2777 export_name: "Child".to_string(),
2778 super_class: Some("Parent".to_string()),
2779 implements: vec!["Contract".to_string()],
2780 instance_bindings: Vec::new(),
2781 }],
2782 exported_factory_returns: Box::from([FactoryReturnExport {
2783 export_name: "useApi".to_string(),
2784 class_local_name: "RESTApi".to_string(),
2785 }]),
2786 injection_tokens: vec![("TOKEN".to_string(), "Contract".to_string())],
2787 local_type_declarations: vec![LocalTypeDeclaration {
2788 name: "Contract".to_string(),
2789 span: span(),
2790 }],
2791 public_signature_type_references: vec![PublicSignatureTypeReference {
2792 export_name: "kept".to_string(),
2793 type_name: "Contract".to_string(),
2794 span: span(),
2795 }],
2796 namespace_object_aliases: vec![NamespaceObjectAlias {
2797 via_export_name: "api".to_string(),
2798 suffix: "read".to_string(),
2799 namespace_local: "ns".to_string(),
2800 }],
2801 iconify_prefixes: vec!["hero".to_string()],
2802 iconify_icon_names: vec!["hero-home".to_string()],
2803 auto_import_candidates: vec!["useState".to_string()],
2804 directives: vec!["use client".to_string()],
2805 client_only_dynamic_import_spans: Vec::new(),
2806 security_sinks: Vec::new(),
2807 security_sinks_skipped: 1,
2808 security_unresolved_callee_sites: Vec::new(),
2809 tainted_bindings: Vec::new(),
2810 sanitized_sink_args: Vec::new(),
2811 security_control_sites: Vec::new(),
2812 callee_uses: Vec::new(),
2813 misplaced_directives: Vec::new(),
2814 inline_server_action_exports: Vec::new(),
2815 di_key_sites: Vec::new(),
2816 has_dynamic_provide: false,
2817 referenced_import_bindings: Vec::new(),
2818 component_props: Vec::new(),
2819 has_props_attrs_fallthrough: false,
2820 has_define_expose: false,
2821 has_define_model: false,
2822 has_unharvestable_props: false,
2823 component_emits: Vec::new(),
2824 angular_inputs: Vec::new(),
2825 angular_outputs: Vec::new(),
2826 angular_component_selectors: Vec::new(),
2827 registered_custom_elements: Vec::new(),
2828 used_custom_element_tags: Vec::new(),
2829 angular_used_selectors: Vec::new(),
2830 angular_entry_component_refs: Vec::new(),
2831 has_dynamic_component_render: false,
2832 has_unharvestable_emits: false,
2833 has_dynamic_emit: false,
2834 has_emit_whole_object_use: false,
2835 load_return_keys: Vec::new(),
2836 has_unharvestable_load: false,
2837 has_load_data_whole_use: false,
2838 has_page_data_store_whole_use: false,
2839 component_functions: Vec::new(),
2840 react_props: Vec::new(),
2841 hook_uses: Vec::new(),
2842 render_edges: Vec::new(),
2843 svelte_dispatched_events: Vec::new(),
2844 svelte_listened_events: Vec::new(),
2845 has_dynamic_dispatch: false,
2846 };
2847
2848 module.release_resolution_payload();
2849
2850 assert_eq!(module.file_id, FileId(7));
2851 assert_eq!(module.content_hash, 42);
2852 assert_eq!(module.line_offsets, vec![0, 8]);
2853 assert_eq!(module.imports.len(), 1);
2854 assert_eq!(module.exports.len(), 1);
2855 assert_eq!(module.re_exports.len(), 1);
2856 assert_eq!(module.dynamic_import_patterns.len(), 1);
2857 assert_eq!(module.member_accesses.len(), 1);
2858 assert_eq!(module.complexity.len(), 1);
2859 assert_eq!(module.flag_uses.len(), 1);
2860 assert_eq!(module.class_heritage.len(), 1);
2861 assert_eq!(module.exported_factory_returns.len(), 1);
2862 assert_eq!(module.injection_tokens.len(), 1);
2863 assert_eq!(module.local_type_declarations.len(), 1);
2864 assert_eq!(module.public_signature_type_references.len(), 1);
2865 assert_eq!(module.iconify_prefixes.len(), 1);
2866 assert_eq!(module.iconify_icon_names.len(), 1);
2867 assert_eq!(module.directives.len(), 1);
2868 assert_eq!(module.security_sinks_skipped, 1);
2869 assert_released!(module.dynamic_imports);
2870 assert_released!(module.require_calls);
2871 assert_released!(module.package_path_references);
2872 assert_released!(module.whole_object_uses);
2873 assert_released!(module.unused_import_bindings);
2874 assert_released!(module.type_referenced_import_bindings);
2875 assert_released!(module.value_referenced_import_bindings);
2876 assert_released!(module.namespace_object_aliases);
2877 assert_released!(module.auto_import_candidates);
2878 assert_eq!(
2879 module.referenced_import_bindings,
2880 vec!["childProcess".to_string()]
2881 );
2882 }
2883
2884 #[test]
2885 fn sink_shape_bitcode_roundtrip() {
2886 for shape in [
2887 SinkShape::Call,
2888 SinkShape::MemberCall,
2889 SinkShape::MemberAssign,
2890 SinkShape::TaggedTemplate,
2891 SinkShape::JsxAttr,
2892 SinkShape::NewExpression,
2893 SinkShape::SecretLiteral,
2894 ] {
2895 let encoded = bitcode::encode(&shape);
2896 let decoded: SinkShape = bitcode::decode(&encoded).expect("decode sink shape");
2897 assert_eq!(shape, decoded);
2898 }
2899 }
2900
2901 #[test]
2902 fn sink_arg_kind_bitcode_roundtrip() {
2903 for kind in [
2904 SinkArgKind::TemplateWithSubst,
2905 SinkArgKind::Concat,
2906 SinkArgKind::Object,
2907 SinkArgKind::Call,
2908 SinkArgKind::Literal,
2909 SinkArgKind::NoArg,
2910 SinkArgKind::Other,
2911 ] {
2912 let encoded = bitcode::encode(&kind);
2913 let decoded: SinkArgKind = bitcode::decode(&encoded).expect("decode sink arg kind");
2914 assert_eq!(kind, decoded);
2915 }
2916 }
2917
2918 #[test]
2919 fn security_url_shape_bitcode_roundtrip() {
2920 for shape in [
2921 SecurityUrlShape::FixedOriginDynamicPath,
2922 SecurityUrlShape::DynamicOrigin,
2923 ] {
2924 let encoded = bitcode::encode(&shape);
2925 let decoded: SecurityUrlShape =
2926 bitcode::decode(&encoded).expect("decode security url shape");
2927 assert_eq!(shape, decoded);
2928 }
2929 }
2930
2931 #[test]
2932 fn sink_site_bitcode_roundtrip() {
2933 let site = SinkSite {
2934 sink_shape: SinkShape::MemberAssign,
2935 callee_path: "el.innerHTML".to_string(),
2936 arg_index: 0,
2937 arg_is_non_literal: true,
2938 arg_kind: SinkArgKind::Other,
2939 arg_literal: Some(SinkLiteralValue::Integer(511)),
2940 regex_pattern: None,
2941 object_properties: vec![SinkObjectProperty {
2942 key: "origin".to_string(),
2943 value: SinkLiteralValue::String("*".to_string()),
2944 }],
2945 object_property_keys: vec!["origin".to_string()],
2946 object_property_keys_complete: true,
2947 arg_idents: vec!["userInput".to_string()],
2948 arg_source_paths: vec!["req.body.email".to_string(), "req.body".to_string()],
2949 span_start: 10,
2950 span_end: 20,
2951 url_arg_literal: Some("https://api.example.com".to_string()),
2952 url_shape: Some(SecurityUrlShape::FixedOriginDynamicPath),
2953 };
2954 let encoded = bitcode::encode(&site);
2955 let decoded: SinkSite = bitcode::decode(&encoded).expect("decode sink site");
2956 assert_eq!(decoded.sink_shape, site.sink_shape);
2957 assert_eq!(decoded.callee_path, site.callee_path);
2958 assert_eq!(decoded.arg_index, site.arg_index);
2959 assert_eq!(decoded.arg_is_non_literal, site.arg_is_non_literal);
2960 assert_eq!(decoded.arg_kind, site.arg_kind);
2961 assert_eq!(decoded.arg_literal, site.arg_literal);
2962 assert_eq!(decoded.object_properties, site.object_properties);
2963 assert_eq!(decoded.object_property_keys, site.object_property_keys);
2964 assert_eq!(
2965 decoded.object_property_keys_complete,
2966 site.object_property_keys_complete
2967 );
2968 assert_eq!(decoded.arg_idents, site.arg_idents);
2969 assert_eq!(decoded.arg_source_paths, site.arg_source_paths);
2970 assert_eq!(decoded.url_shape, site.url_shape);
2971 assert_eq!(decoded.span(), site.span());
2972 }
2973
2974 #[test]
2975 fn line_offsets_single_line_no_newline() {
2976 assert_eq!(compute_line_offsets("hello"), vec![0]);
2977 }
2978
2979 #[test]
2980 fn line_offsets_single_line_with_newline() {
2981 assert_eq!(compute_line_offsets("hello\n"), vec![0, 6]);
2982 }
2983
2984 #[test]
2985 fn line_offsets_multiple_lines() {
2986 assert_eq!(compute_line_offsets("abc\ndef\nghi"), vec![0, 4, 8]);
2987 }
2988
2989 #[test]
2990 fn line_offsets_trailing_newline() {
2991 assert_eq!(compute_line_offsets("abc\ndef\n"), vec![0, 4, 8]);
2992 }
2993
2994 #[test]
2995 fn line_offsets_consecutive_newlines() {
2996 assert_eq!(compute_line_offsets("\n\n\n"), vec![0, 1, 2, 3]);
2997 }
2998
2999 #[test]
3000 fn line_offsets_multibyte_utf8() {
3001 assert_eq!(compute_line_offsets("á\n"), vec![0, 3]);
3002 }
3003
3004 #[test]
3005 fn line_col_offset_zero() {
3006 let offsets = compute_line_offsets("abc\ndef\nghi");
3007 let (line, col) = byte_offset_to_line_col(&offsets, 0);
3008 assert_eq!((line, col), (1, 0));
3009 }
3010
3011 #[test]
3012 fn line_col_middle_of_first_line() {
3013 let offsets = compute_line_offsets("abc\ndef\nghi");
3014 let (line, col) = byte_offset_to_line_col(&offsets, 2);
3015 assert_eq!((line, col), (1, 2));
3016 }
3017
3018 #[test]
3019 fn line_col_start_of_second_line() {
3020 let offsets = compute_line_offsets("abc\ndef\nghi");
3021 let (line, col) = byte_offset_to_line_col(&offsets, 4);
3022 assert_eq!((line, col), (2, 0));
3023 }
3024
3025 #[test]
3026 fn line_col_middle_of_second_line() {
3027 let offsets = compute_line_offsets("abc\ndef\nghi");
3028 let (line, col) = byte_offset_to_line_col(&offsets, 5);
3029 assert_eq!((line, col), (2, 1));
3030 }
3031
3032 #[test]
3033 fn line_col_start_of_third_line() {
3034 let offsets = compute_line_offsets("abc\ndef\nghi");
3035 let (line, col) = byte_offset_to_line_col(&offsets, 8);
3036 assert_eq!((line, col), (3, 0));
3037 }
3038
3039 #[test]
3040 fn line_col_end_of_file() {
3041 let offsets = compute_line_offsets("abc\ndef\nghi");
3042 let (line, col) = byte_offset_to_line_col(&offsets, 10);
3043 assert_eq!((line, col), (3, 2));
3044 }
3045
3046 #[test]
3047 fn line_col_single_line() {
3048 let offsets = compute_line_offsets("hello");
3049 let (line, col) = byte_offset_to_line_col(&offsets, 3);
3050 assert_eq!((line, col), (1, 3));
3051 }
3052
3053 #[test]
3054 fn line_col_at_newline_byte() {
3055 let offsets = compute_line_offsets("abc\ndef");
3056 let (line, col) = byte_offset_to_line_col(&offsets, 3);
3057 assert_eq!((line, col), (1, 3));
3058 }
3059
3060 #[test]
3061 fn export_name_matches_str_named() {
3062 let name = ExportName::Named("foo".to_string());
3063 assert!(name.matches_str("foo"));
3064 assert!(!name.matches_str("bar"));
3065 assert!(!name.matches_str("default"));
3066 }
3067
3068 #[test]
3069 fn export_name_matches_str_default() {
3070 let name = ExportName::Default;
3071 assert!(name.matches_str("default"));
3072 assert!(!name.matches_str("foo"));
3073 }
3074
3075 #[test]
3076 fn export_name_display_named() {
3077 let name = ExportName::Named("myExport".to_string());
3078 assert_eq!(name.to_string(), "myExport");
3079 }
3080
3081 #[test]
3082 fn export_name_display_default() {
3083 let name = ExportName::Default;
3084 assert_eq!(name.to_string(), "default");
3085 }
3086
3087 #[test]
3088 fn export_name_equality_named() {
3089 let a = ExportName::Named("foo".to_string());
3090 let b = ExportName::Named("foo".to_string());
3091 let c = ExportName::Named("bar".to_string());
3092 assert_eq!(a, b);
3093 assert_ne!(a, c);
3094 }
3095
3096 #[test]
3097 fn export_name_equality_default() {
3098 let a = ExportName::Default;
3099 let b = ExportName::Default;
3100 assert_eq!(a, b);
3101 }
3102
3103 #[test]
3104 fn export_name_named_not_equal_to_default() {
3105 let named = ExportName::Named("default".to_string());
3106 let default = ExportName::Default;
3107 assert_ne!(named, default);
3108 }
3109
3110 #[test]
3111 fn export_name_hash_consistency() {
3112 use std::collections::hash_map::DefaultHasher;
3113 use std::hash::{Hash, Hasher};
3114
3115 let mut h1 = DefaultHasher::new();
3116 let mut h2 = DefaultHasher::new();
3117 ExportName::Named("foo".to_string()).hash(&mut h1);
3118 ExportName::Named("foo".to_string()).hash(&mut h2);
3119 assert_eq!(h1.finish(), h2.finish());
3120 }
3121
3122 #[test]
3123 fn export_name_matches_str_empty_string() {
3124 let name = ExportName::Named(String::new());
3125 assert!(name.matches_str(""));
3126 assert!(!name.matches_str("foo"));
3127 }
3128
3129 #[test]
3130 fn export_name_default_does_not_match_empty() {
3131 let name = ExportName::Default;
3132 assert!(!name.matches_str(""));
3133 }
3134
3135 #[test]
3136 fn imported_name_equality() {
3137 assert_eq!(
3138 ImportedName::Named("foo".to_string()),
3139 ImportedName::Named("foo".to_string())
3140 );
3141 assert_ne!(
3142 ImportedName::Named("foo".to_string()),
3143 ImportedName::Named("bar".to_string())
3144 );
3145 assert_eq!(ImportedName::Default, ImportedName::Default);
3146 assert_eq!(ImportedName::Namespace, ImportedName::Namespace);
3147 assert_eq!(ImportedName::SideEffect, ImportedName::SideEffect);
3148 assert_ne!(ImportedName::Default, ImportedName::Namespace);
3149 assert_ne!(
3150 ImportedName::Named("default".to_string()),
3151 ImportedName::Default
3152 );
3153 }
3154
3155 #[test]
3156 fn member_kind_equality() {
3157 assert_eq!(MemberKind::EnumMember, MemberKind::EnumMember);
3158 assert_eq!(MemberKind::ClassMethod, MemberKind::ClassMethod);
3159 assert_eq!(MemberKind::ClassProperty, MemberKind::ClassProperty);
3160 assert_eq!(MemberKind::NamespaceMember, MemberKind::NamespaceMember);
3161 assert_ne!(MemberKind::EnumMember, MemberKind::ClassMethod);
3162 assert_ne!(MemberKind::ClassMethod, MemberKind::ClassProperty);
3163 assert_ne!(MemberKind::NamespaceMember, MemberKind::EnumMember);
3164 }
3165
3166 #[test]
3167 fn member_kind_bitcode_roundtrip() {
3168 let kinds = [
3169 MemberKind::EnumMember,
3170 MemberKind::ClassMethod,
3171 MemberKind::ClassProperty,
3172 MemberKind::NamespaceMember,
3173 ];
3174 for kind in &kinds {
3175 let bytes = bitcode::encode(kind);
3176 let decoded: MemberKind = bitcode::decode(&bytes).unwrap();
3177 assert_eq!(&decoded, kind);
3178 }
3179 }
3180
3181 #[test]
3182 fn member_access_bitcode_roundtrip() {
3183 let access = MemberAccess {
3184 object: "Status".to_string(),
3185 member: "Active".to_string(),
3186 };
3187 let bytes = bitcode::encode(&access);
3188 let decoded: MemberAccess = bitcode::decode(&bytes).unwrap();
3189 assert_eq!(decoded.object, "Status");
3190 assert_eq!(decoded.member, "Active");
3191 }
3192
3193 #[test]
3194 fn line_offsets_crlf_only_counts_lf() {
3195 let offsets = compute_line_offsets("ab\r\ncd");
3196 assert_eq!(offsets, vec![0, 4]);
3197 }
3198
3199 #[test]
3200 fn line_col_empty_file_offset_zero() {
3201 let offsets = compute_line_offsets("");
3202 let (line, col) = byte_offset_to_line_col(&offsets, 0);
3203 assert_eq!((line, col), (1, 0));
3204 }
3205
3206 // --- VisibilityTag ---
3207
3208 #[test]
3209 fn visibility_tag_default_is_none_variant() {
3210 assert_eq!(VisibilityTag::default(), VisibilityTag::None);
3211 }
3212
3213 #[test]
3214 fn visibility_tag_is_none_only_for_none_variant() {
3215 assert!(VisibilityTag::None.is_none());
3216 assert!(!VisibilityTag::Public.is_none());
3217 assert!(!VisibilityTag::Internal.is_none());
3218 assert!(!VisibilityTag::Beta.is_none());
3219 assert!(!VisibilityTag::Alpha.is_none());
3220 assert!(!VisibilityTag::ExpectedUnused.is_none());
3221 }
3222
3223 #[test]
3224 fn visibility_tag_suppresses_unused_for_api_tags() {
3225 assert!(VisibilityTag::Public.suppresses_unused());
3226 assert!(VisibilityTag::Internal.suppresses_unused());
3227 assert!(VisibilityTag::Beta.suppresses_unused());
3228 assert!(VisibilityTag::Alpha.suppresses_unused());
3229 }
3230
3231 #[test]
3232 fn visibility_tag_does_not_suppress_none_or_expected_unused() {
3233 assert!(!VisibilityTag::None.suppresses_unused());
3234 assert!(!VisibilityTag::ExpectedUnused.suppresses_unused());
3235 }
3236
3237 // --- is_public_env_path ---
3238
3239 #[test]
3240 fn is_public_env_path_process_env_public_prefix() {
3241 assert!(is_public_env_path("process.env.NEXT_PUBLIC_API_URL"));
3242 assert!(is_public_env_path("process.env.VITE_APP_KEY"));
3243 assert!(is_public_env_path("process.env.REACT_APP_TITLE"));
3244 assert!(is_public_env_path("process.env.NODE_ENV"));
3245 }
3246
3247 #[test]
3248 fn is_public_env_path_import_meta_env_public_prefix() {
3249 assert!(is_public_env_path("import.meta.env.VITE_BASE_URL"));
3250 assert!(is_public_env_path("import.meta.env.PUBLIC_API"));
3251 }
3252
3253 #[test]
3254 fn is_public_env_path_secret_env_vars_are_not_public() {
3255 assert!(!is_public_env_path("process.env.SECRET_KEY"));
3256 assert!(!is_public_env_path("process.env.DATABASE_PASSWORD"));
3257 assert!(!is_public_env_path("import.meta.env.API_TOKEN"));
3258 }
3259
3260 #[test]
3261 fn is_public_env_path_non_env_paths_are_not_public() {
3262 assert!(!is_public_env_path("req.query.id"));
3263 assert!(!is_public_env_path("process.argv"));
3264 assert!(!is_public_env_path("window.location.href"));
3265 }
3266
3267 // --- is_public_env_var edge cases ---
3268
3269 #[test]
3270 fn is_public_env_var_exact_matches() {
3271 assert!(is_public_env_var("NODE_ENV"));
3272 }
3273
3274 #[test]
3275 fn is_public_env_var_all_known_prefixes() {
3276 assert!(is_public_env_var("NUXT_PUBLIC_API_URL"));
3277 assert!(is_public_env_var("PUBLIC_API_KEY"));
3278 assert!(is_public_env_var("GATSBY_APP_ID"));
3279 assert!(is_public_env_var("EXPO_PUBLIC_SENTRY_DSN"));
3280 assert!(is_public_env_var("STORYBOOK_ENV"));
3281 }
3282
3283 #[test]
3284 fn is_public_env_var_secret_token_beats_metadata_token() {
3285 // "SECRET_SHA": has SECRET (wins) and SHA (metadata); should NOT be public
3286 assert!(!is_public_env_var("SECRET_SHA"));
3287 // "REF_TOKEN": has TOKEN (secret) and REF (metadata); should NOT be public
3288 assert!(!is_public_env_var("REF_TOKEN"));
3289 }
3290
3291 #[test]
3292 fn is_public_env_var_plain_unknown_names_are_not_public() {
3293 assert!(!is_public_env_var("MY_SERVICE_URL"));
3294 assert!(!is_public_env_var("FEATURE_FLAG"));
3295 assert!(!is_public_env_var("DATABASE_URL"));
3296 }
3297
3298 // --- SinkSite::span ---
3299
3300 #[test]
3301 fn sink_site_span_reconstructs_from_offsets() {
3302 let site = SinkSite {
3303 sink_shape: SinkShape::Call,
3304 callee_path: "eval".to_string(),
3305 arg_index: 0,
3306 arg_is_non_literal: true,
3307 arg_kind: SinkArgKind::Other,
3308 arg_literal: None,
3309 regex_pattern: None,
3310 object_properties: Vec::new(),
3311 object_property_keys: Vec::new(),
3312 object_property_keys_complete: false,
3313 arg_idents: Vec::new(),
3314 arg_source_paths: Vec::new(),
3315 span_start: 5,
3316 span_end: 15,
3317 url_arg_literal: None,
3318 url_shape: None,
3319 };
3320 let s = site.span();
3321 assert_eq!(s.start, 5);
3322 assert_eq!(s.end, 15);
3323 }
3324
3325 // --- SecurityControlKind ---
3326
3327 #[test]
3328 fn security_control_kind_equality_and_ordering() {
3329 assert_eq!(
3330 SecurityControlKind::Sanitization,
3331 SecurityControlKind::Sanitization
3332 );
3333 assert_eq!(
3334 SecurityControlKind::Validation,
3335 SecurityControlKind::Validation
3336 );
3337 assert_ne!(
3338 SecurityControlKind::Sanitization,
3339 SecurityControlKind::Validation
3340 );
3341 assert!(SecurityControlKind::Sanitization < SecurityControlKind::Validation);
3342 assert!(SecurityControlKind::Authentication < SecurityControlKind::Authorization);
3343 }
3344
3345 // --- SanitizerScope ---
3346
3347 #[test]
3348 fn sanitizer_scope_equality_and_ordering() {
3349 assert_eq!(SanitizerScope::Html, SanitizerScope::Html);
3350 assert_eq!(SanitizerScope::Url, SanitizerScope::Url);
3351 assert_eq!(SanitizerScope::Path, SanitizerScope::Path);
3352 assert_eq!(SanitizerScope::SqlIdentifier, SanitizerScope::SqlIdentifier);
3353 assert_ne!(SanitizerScope::Html, SanitizerScope::Url);
3354 assert!(SanitizerScope::Html < SanitizerScope::Url);
3355 }
3356
3357 // --- SkippedSecurityCalleeReason ---
3358
3359 #[test]
3360 fn skipped_security_callee_reason_equality() {
3361 assert_eq!(
3362 SkippedSecurityCalleeReason::ComputedMember,
3363 SkippedSecurityCalleeReason::ComputedMember
3364 );
3365 assert_ne!(
3366 SkippedSecurityCalleeReason::ComputedMember,
3367 SkippedSecurityCalleeReason::DynamicDispatch
3368 );
3369 assert_ne!(
3370 SkippedSecurityCalleeReason::DynamicDispatch,
3371 SkippedSecurityCalleeReason::UnsupportedAssignmentObject
3372 );
3373 }
3374
3375 // --- SkippedSecurityCalleeExpressionKind ---
3376
3377 #[test]
3378 fn skipped_security_callee_expression_kind_equality() {
3379 use SkippedSecurityCalleeExpressionKind as K;
3380 assert_eq!(K::StaticMemberExpression, K::StaticMemberExpression);
3381 assert_eq!(K::ComputedMemberExpression, K::ComputedMemberExpression);
3382 assert_eq!(K::Identifier, K::Identifier);
3383 assert_eq!(K::Other, K::Other);
3384 assert_ne!(K::StaticMemberExpression, K::ComputedMemberExpression);
3385 assert_ne!(K::Identifier, K::Other);
3386 }
3387
3388 // --- SinkLiteralValue ---
3389
3390 #[test]
3391 fn sink_literal_value_equality() {
3392 assert_eq!(
3393 SinkLiteralValue::String("x".to_string()),
3394 SinkLiteralValue::String("x".to_string())
3395 );
3396 assert_ne!(
3397 SinkLiteralValue::String("x".to_string()),
3398 SinkLiteralValue::String("y".to_string())
3399 );
3400 assert_eq!(SinkLiteralValue::Integer(42), SinkLiteralValue::Integer(42));
3401 assert_ne!(SinkLiteralValue::Integer(1), SinkLiteralValue::Integer(2));
3402 assert_eq!(
3403 SinkLiteralValue::Boolean(true),
3404 SinkLiteralValue::Boolean(true)
3405 );
3406 assert_ne!(
3407 SinkLiteralValue::Boolean(true),
3408 SinkLiteralValue::Boolean(false)
3409 );
3410 assert_eq!(SinkLiteralValue::Null, SinkLiteralValue::Null);
3411 assert_ne!(SinkLiteralValue::Null, SinkLiteralValue::Boolean(false));
3412 }
3413
3414 // --- SecurityUrlShape ---
3415
3416 #[test]
3417 fn security_url_shape_equality() {
3418 assert_eq!(
3419 SecurityUrlShape::FixedOriginDynamicPath,
3420 SecurityUrlShape::FixedOriginDynamicPath
3421 );
3422 assert_eq!(
3423 SecurityUrlShape::DynamicOrigin,
3424 SecurityUrlShape::DynamicOrigin
3425 );
3426 assert_ne!(
3427 SecurityUrlShape::FixedOriginDynamicPath,
3428 SecurityUrlShape::DynamicOrigin
3429 );
3430 }
3431
3432 // --- FlagUseKind ---
3433
3434 #[test]
3435 fn flag_use_kind_equality() {
3436 assert_eq!(FlagUseKind::EnvVar, FlagUseKind::EnvVar);
3437 assert_eq!(FlagUseKind::SdkCall, FlagUseKind::SdkCall);
3438 assert_eq!(FlagUseKind::ConfigObject, FlagUseKind::ConfigObject);
3439 assert_ne!(FlagUseKind::EnvVar, FlagUseKind::SdkCall);
3440 assert_ne!(FlagUseKind::SdkCall, FlagUseKind::ConfigObject);
3441 }
3442
3443 // --- ComplexityMetric ---
3444
3445 #[test]
3446 fn complexity_metric_equality() {
3447 assert_eq!(ComplexityMetric::Cyclomatic, ComplexityMetric::Cyclomatic);
3448 assert_eq!(ComplexityMetric::Cognitive, ComplexityMetric::Cognitive);
3449 assert_ne!(ComplexityMetric::Cyclomatic, ComplexityMetric::Cognitive);
3450 }
3451
3452 // --- ComplexityContributionKind ---
3453
3454 #[test]
3455 fn complexity_contribution_kind_equality_spot_check() {
3456 use ComplexityContributionKind as K;
3457 assert_eq!(K::If, K::If);
3458 assert_eq!(K::Else, K::Else);
3459 assert_eq!(K::ElseIf, K::ElseIf);
3460 assert_eq!(K::Ternary, K::Ternary);
3461 assert_eq!(K::LogicalAnd, K::LogicalAnd);
3462 assert_eq!(K::LogicalOr, K::LogicalOr);
3463 assert_eq!(K::NullishCoalescing, K::NullishCoalescing);
3464 assert_eq!(K::LogicalAssignment, K::LogicalAssignment);
3465 assert_eq!(K::OptionalChain, K::OptionalChain);
3466 assert_eq!(K::For, K::For);
3467 assert_eq!(K::ForIn, K::ForIn);
3468 assert_eq!(K::ForOf, K::ForOf);
3469 assert_eq!(K::While, K::While);
3470 assert_eq!(K::DoWhile, K::DoWhile);
3471 assert_eq!(K::Switch, K::Switch);
3472 assert_eq!(K::Case, K::Case);
3473 assert_eq!(K::Catch, K::Catch);
3474 assert_eq!(K::LabeledBreak, K::LabeledBreak);
3475 assert_eq!(K::LabeledContinue, K::LabeledContinue);
3476 assert_eq!(K::JsxDepth, K::JsxDepth);
3477 assert_eq!(K::HookDensity, K::HookDensity);
3478 assert_eq!(K::PropCount, K::PropCount);
3479 assert_ne!(K::If, K::Else);
3480 assert_ne!(K::For, K::While);
3481 assert_ne!(K::Switch, K::Case);
3482 }
3483
3484 // --- MisplacedDirectiveSite ---
3485
3486 #[test]
3487 fn misplaced_directive_site_equality() {
3488 let client = MisplacedDirectiveSite {
3489 is_server: false,
3490 span_start: 10,
3491 };
3492 let server = MisplacedDirectiveSite {
3493 is_server: true,
3494 span_start: 10,
3495 };
3496 let client2 = MisplacedDirectiveSite {
3497 is_server: false,
3498 span_start: 10,
3499 };
3500 assert_eq!(client, client2);
3501 assert_ne!(client, server);
3502 }
3503
3504 #[test]
3505 fn misplaced_directive_site_is_server_flag() {
3506 let site = MisplacedDirectiveSite {
3507 is_server: true,
3508 span_start: 42,
3509 };
3510 assert!(site.is_server);
3511 assert_eq!(site.span_start, 42);
3512
3513 let client_site = MisplacedDirectiveSite {
3514 is_server: false,
3515 span_start: 0,
3516 };
3517 assert!(!client_site.is_server);
3518 }
3519
3520 // --- DiRole / DiFramework ---
3521
3522 #[test]
3523 fn di_role_equality() {
3524 assert_eq!(DiRole::Provide, DiRole::Provide);
3525 assert_eq!(DiRole::Inject, DiRole::Inject);
3526 assert_ne!(DiRole::Provide, DiRole::Inject);
3527 }
3528
3529 #[test]
3530 fn di_framework_equality() {
3531 assert_eq!(DiFramework::Vue, DiFramework::Vue);
3532 assert_eq!(DiFramework::Svelte, DiFramework::Svelte);
3533 assert_eq!(DiFramework::Angular, DiFramework::Angular);
3534 assert_ne!(DiFramework::Vue, DiFramework::Svelte);
3535 assert_ne!(DiFramework::Svelte, DiFramework::Angular);
3536 }
3537
3538 // --- ComponentEmit ---
3539
3540 #[test]
3541 fn component_emit_equality() {
3542 let a = ComponentEmit {
3543 name: "close".to_string(),
3544 span_start: 10,
3545 used: true,
3546 };
3547 let b = ComponentEmit {
3548 name: "close".to_string(),
3549 span_start: 10,
3550 used: true,
3551 };
3552 let different_used = ComponentEmit {
3553 name: "close".to_string(),
3554 span_start: 10,
3555 used: false,
3556 };
3557 let different_name = ComponentEmit {
3558 name: "open".to_string(),
3559 span_start: 10,
3560 used: true,
3561 };
3562 assert_eq!(a, b);
3563 assert_ne!(a, different_used);
3564 assert_ne!(a, different_name);
3565 }
3566
3567 // --- DispatchedEvent ---
3568
3569 #[test]
3570 fn dispatched_event_equality() {
3571 let a = DispatchedEvent {
3572 name: "myEvent".to_string(),
3573 span_start: 20,
3574 };
3575 let b = DispatchedEvent {
3576 name: "myEvent".to_string(),
3577 span_start: 20,
3578 };
3579 let c = DispatchedEvent {
3580 name: "otherEvent".to_string(),
3581 span_start: 20,
3582 };
3583 let d = DispatchedEvent {
3584 name: "myEvent".to_string(),
3585 span_start: 99,
3586 };
3587 assert_eq!(a, b);
3588 assert_ne!(a, c);
3589 assert_ne!(a, d);
3590 }
3591
3592 // --- AngularInputMember / AngularOutputMember ---
3593
3594 #[test]
3595 fn angular_input_member_equality() {
3596 let a = AngularInputMember {
3597 name: "title".to_string(),
3598 span_start: 5,
3599 };
3600 let b = AngularInputMember {
3601 name: "title".to_string(),
3602 span_start: 5,
3603 };
3604 let c = AngularInputMember {
3605 name: "label".to_string(),
3606 span_start: 5,
3607 };
3608 assert_eq!(a, b);
3609 assert_ne!(a, c);
3610 }
3611
3612 #[test]
3613 fn angular_output_member_equality() {
3614 let a = AngularOutputMember {
3615 name: "clicked".to_string(),
3616 span_start: 8,
3617 };
3618 let b = AngularOutputMember {
3619 name: "clicked".to_string(),
3620 span_start: 8,
3621 };
3622 let c = AngularOutputMember {
3623 name: "hovered".to_string(),
3624 span_start: 8,
3625 };
3626 assert_eq!(a, b);
3627 assert_ne!(a, c);
3628 }
3629
3630 // --- AngularComponentSelector ---
3631
3632 #[test]
3633 fn angular_component_selector_fields() {
3634 let s = AngularComponentSelector {
3635 selectors: vec!["app-foo".to_string(), "[appFoo]".to_string()],
3636 span_start: 100,
3637 class_name: "FooComponent".to_string(),
3638 };
3639 assert_eq!(s.selectors.len(), 2);
3640 assert_eq!(s.selectors[0], "app-foo");
3641 assert_eq!(s.selectors[1], "[appFoo]");
3642 assert_eq!(s.class_name, "FooComponent");
3643 }
3644
3645 #[test]
3646 fn angular_component_selector_equality() {
3647 let a = AngularComponentSelector {
3648 selectors: vec!["app-bar".to_string()],
3649 span_start: 0,
3650 class_name: "BarComponent".to_string(),
3651 };
3652 let b = AngularComponentSelector {
3653 selectors: vec!["app-bar".to_string()],
3654 span_start: 0,
3655 class_name: "BarComponent".to_string(),
3656 };
3657 let c = AngularComponentSelector {
3658 selectors: vec!["app-baz".to_string()],
3659 span_start: 0,
3660 class_name: "BazComponent".to_string(),
3661 };
3662 assert_eq!(a, b);
3663 assert_ne!(a, c);
3664 }
3665
3666 // --- LoadReturnKey ---
3667
3668 #[test]
3669 fn load_return_key_equality() {
3670 let a = LoadReturnKey {
3671 name: "user".to_string(),
3672 span_start: 50,
3673 span_end: 54,
3674 };
3675 let b = LoadReturnKey {
3676 name: "user".to_string(),
3677 span_start: 50,
3678 span_end: 54,
3679 };
3680 let c = LoadReturnKey {
3681 name: "posts".to_string(),
3682 span_start: 50,
3683 span_end: 55,
3684 };
3685 assert_eq!(a, b);
3686 assert_ne!(a, c);
3687 }
3688
3689 #[test]
3690 fn load_return_key_span_fields() {
3691 let key = LoadReturnKey {
3692 name: "data".to_string(),
3693 span_start: 10,
3694 span_end: 14,
3695 };
3696 assert_eq!(key.span_start, 10);
3697 assert_eq!(key.span_end, 14);
3698 assert_eq!(key.name, "data");
3699 }
3700
3701 // --- ComponentFunctionKind ---
3702
3703 #[test]
3704 fn component_function_kind_equality() {
3705 assert_eq!(ComponentFunctionKind::FnDecl, ComponentFunctionKind::FnDecl);
3706 assert_eq!(ComponentFunctionKind::Arrow, ComponentFunctionKind::Arrow);
3707 assert_eq!(
3708 ComponentFunctionKind::ForwardRefWrapper,
3709 ComponentFunctionKind::ForwardRefWrapper
3710 );
3711 assert_eq!(
3712 ComponentFunctionKind::MemoWrapper,
3713 ComponentFunctionKind::MemoWrapper
3714 );
3715 assert_ne!(ComponentFunctionKind::FnDecl, ComponentFunctionKind::Arrow);
3716 assert_ne!(
3717 ComponentFunctionKind::ForwardRefWrapper,
3718 ComponentFunctionKind::MemoWrapper
3719 );
3720 }
3721
3722 // --- HookUseKind ---
3723
3724 #[test]
3725 fn hook_use_kind_equality() {
3726 assert_eq!(HookUseKind::UseState, HookUseKind::UseState);
3727 assert_eq!(HookUseKind::UseEffect, HookUseKind::UseEffect);
3728 assert_eq!(HookUseKind::UseMemo, HookUseKind::UseMemo);
3729 assert_eq!(HookUseKind::UseCallback, HookUseKind::UseCallback);
3730 assert_eq!(HookUseKind::Custom, HookUseKind::Custom);
3731 assert_ne!(HookUseKind::UseState, HookUseKind::UseEffect);
3732 assert_ne!(HookUseKind::UseMemo, HookUseKind::Custom);
3733 }
3734
3735 // --- HookUse ---
3736
3737 #[test]
3738 fn hook_use_fields() {
3739 let h = HookUse {
3740 kind: HookUseKind::UseEffect,
3741 dep_array_arity: Some(2),
3742 span_start: 30,
3743 component: "Widget".to_string(),
3744 };
3745 assert_eq!(h.kind, HookUseKind::UseEffect);
3746 assert_eq!(h.dep_array_arity, Some(2));
3747 assert_eq!(h.span_start, 30);
3748 assert_eq!(h.component, "Widget");
3749 }
3750
3751 #[test]
3752 fn hook_use_no_dep_array() {
3753 let h = HookUse {
3754 kind: HookUseKind::UseCallback,
3755 dep_array_arity: None,
3756 span_start: 0,
3757 component: String::new(),
3758 };
3759 assert!(h.dep_array_arity.is_none());
3760 }
3761
3762 // --- MemberKind::StoreMember (missed in existing bitcode test) ---
3763
3764 #[test]
3765 fn member_kind_store_member_bitcode_roundtrip() {
3766 let kind = MemberKind::StoreMember;
3767 let bytes = bitcode::encode(&kind);
3768 let decoded: MemberKind = bitcode::decode(&bytes).unwrap();
3769 assert_eq!(decoded, kind);
3770 }
3771
3772 // --- RenderEdge / ForwardAttr ---
3773
3774 #[test]
3775 fn render_edge_fields() {
3776 let edge = RenderEdge {
3777 parent_component: "Parent".to_string(),
3778 child_component_name: "Child".to_string(),
3779 attr_names: vec!["title".to_string(), "onClick".to_string()],
3780 has_spread: false,
3781 forward_attrs: vec![ForwardAttr {
3782 attr: "title".to_string(),
3783 root: "props".to_string(),
3784 }],
3785 has_complex_forward: false,
3786 };
3787 assert_eq!(edge.parent_component, "Parent");
3788 assert_eq!(edge.child_component_name, "Child");
3789 assert_eq!(edge.attr_names.len(), 2);
3790 assert!(!edge.has_spread);
3791 assert_eq!(edge.forward_attrs.len(), 1);
3792 assert_eq!(edge.forward_attrs[0].attr, "title");
3793 assert_eq!(edge.forward_attrs[0].root, "props");
3794 assert!(!edge.has_complex_forward);
3795 }
3796
3797 #[test]
3798 fn render_edge_with_spread() {
3799 let edge = RenderEdge {
3800 parent_component: "Wrapper".to_string(),
3801 child_component_name: "Inner".to_string(),
3802 attr_names: Vec::new(),
3803 has_spread: true,
3804 forward_attrs: Vec::new(),
3805 has_complex_forward: true,
3806 };
3807 assert!(edge.has_spread);
3808 assert!(edge.has_complex_forward);
3809 }
3810
3811 // --- ComponentFunction ---
3812
3813 #[test]
3814 fn component_function_fields() {
3815 let cf = ComponentFunction {
3816 name: "MyButton".to_string(),
3817 span_start: 0,
3818 kind: ComponentFunctionKind::Arrow,
3819 is_exported: true,
3820 has_unharvestable_props: false,
3821 uses_clone_element: false,
3822 renders_provider: false,
3823 has_children_as_function: false,
3824 is_pure_passthrough: false,
3825 };
3826 assert_eq!(cf.name, "MyButton");
3827 assert_eq!(cf.kind, ComponentFunctionKind::Arrow);
3828 assert!(cf.is_exported);
3829 assert!(!cf.has_unharvestable_props);
3830 assert!(!cf.is_pure_passthrough);
3831 }
3832
3833 #[test]
3834 fn component_function_passthrough_flag() {
3835 let cf = ComponentFunction {
3836 name: "Passthrough".to_string(),
3837 span_start: 5,
3838 kind: ComponentFunctionKind::FnDecl,
3839 is_exported: false,
3840 has_unharvestable_props: false,
3841 uses_clone_element: false,
3842 renders_provider: false,
3843 has_children_as_function: false,
3844 is_pure_passthrough: true,
3845 };
3846 assert!(cf.is_pure_passthrough);
3847 assert!(!cf.is_exported);
3848 }
3849
3850 // --- DiKeySite ---
3851
3852 #[test]
3853 fn di_key_site_fields() {
3854 let site = DiKeySite {
3855 key_local: "MY_KEY".to_string(),
3856 role: DiRole::Provide,
3857 framework: DiFramework::Vue,
3858 span_start: 77,
3859 };
3860 assert_eq!(site.key_local, "MY_KEY");
3861 assert_eq!(site.role, DiRole::Provide);
3862 assert_eq!(site.framework, DiFramework::Vue);
3863 assert_eq!(site.span_start, 77);
3864 }
3865
3866 #[test]
3867 fn di_key_site_inject_svelte() {
3868 let site = DiKeySite {
3869 key_local: "ctx_key".to_string(),
3870 role: DiRole::Inject,
3871 framework: DiFramework::Svelte,
3872 span_start: 0,
3873 };
3874 assert_eq!(site.role, DiRole::Inject);
3875 assert_eq!(site.framework, DiFramework::Svelte);
3876 }
3877
3878 // --- release_resolution_payload: page data store whole-use derivation ---
3879
3880 #[test]
3881 fn release_payload_derives_page_data_store_whole_use_from_page_data() {
3882 let mut m = minimal_module_info();
3883 m.whole_object_uses = vec!["page.data".to_string()].into();
3884 m.release_resolution_payload();
3885 assert!(m.has_page_data_store_whole_use);
3886 }
3887
3888 #[test]
3889 fn release_payload_derives_page_data_store_whole_use_from_dollar_page_data() {
3890 let mut m = minimal_module_info();
3891 m.whole_object_uses = vec!["$page.data".to_string()].into();
3892 m.release_resolution_payload();
3893 assert!(m.has_page_data_store_whole_use);
3894 }
3895
3896 #[test]
3897 fn release_payload_does_not_set_page_data_store_whole_use_for_other_names() {
3898 let mut m = minimal_module_info();
3899 m.whole_object_uses = vec!["data".to_string(), "page".to_string()].into();
3900 m.release_resolution_payload();
3901 assert!(!m.has_page_data_store_whole_use);
3902 }
3903
3904 // --- release_resolution_payload: referenced_import_bindings derivation ---
3905
3906 #[test]
3907 fn release_payload_referenced_bindings_excludes_empty_local_names() {
3908 let mut m = minimal_module_info();
3909 m.imports = vec![
3910 ImportInfo {
3911 source: "./styles.css".to_string(),
3912 imported_name: ImportedName::SideEffect,
3913 local_name: String::new(), // empty = side-effect import
3914 is_type_only: false,
3915 from_style: true,
3916 span: span(),
3917 source_span: span(),
3918 },
3919 ImportInfo {
3920 source: "react".to_string(),
3921 imported_name: ImportedName::Default,
3922 local_name: "React".to_string(),
3923 is_type_only: false,
3924 from_style: false,
3925 span: span(),
3926 source_span: span(),
3927 },
3928 ];
3929 m.unused_import_bindings = vec!["React".to_string()];
3930 m.release_resolution_payload();
3931 // "React" was unused, empty local is filtered; result should be empty
3932 assert!(m.referenced_import_bindings.is_empty());
3933 }
3934
3935 #[test]
3936 fn release_payload_referenced_bindings_sorted_and_deduped() {
3937 let mut m = minimal_module_info();
3938 // Two imports with the same local name (unusual but possible via re-exports)
3939 m.imports = vec![
3940 ImportInfo {
3941 source: "a".to_string(),
3942 imported_name: ImportedName::Named("foo".to_string()),
3943 local_name: "foo".to_string(),
3944 is_type_only: false,
3945 from_style: false,
3946 span: span(),
3947 source_span: span(),
3948 },
3949 ImportInfo {
3950 source: "b".to_string(),
3951 imported_name: ImportedName::Named("bar".to_string()),
3952 local_name: "bar".to_string(),
3953 is_type_only: false,
3954 from_style: false,
3955 span: span(),
3956 source_span: span(),
3957 },
3958 ImportInfo {
3959 source: "c".to_string(),
3960 imported_name: ImportedName::Named("foo".to_string()),
3961 local_name: "foo".to_string(),
3962 is_type_only: false,
3963 from_style: false,
3964 span: span(),
3965 source_span: span(),
3966 },
3967 ];
3968 m.unused_import_bindings = Vec::new();
3969 m.release_resolution_payload();
3970 // sorted: ["bar", "foo"] with "foo" deduped
3971 assert_eq!(
3972 m.referenced_import_bindings,
3973 vec!["bar".to_string(), "foo".to_string()]
3974 );
3975 }
3976
3977 // --- CalleeUse ---
3978
3979 #[test]
3980 fn callee_use_fields() {
3981 let cu = CalleeUse {
3982 callee_path: "child_process.exec".to_string(),
3983 span_start: 100,
3984 };
3985 assert_eq!(cu.callee_path, "child_process.exec");
3986 assert_eq!(cu.span_start, 100);
3987 }
3988
3989 // --- Helper to build a minimal ModuleInfo for targeted tests ---
3990
3991 fn minimal_module_info() -> ModuleInfo {
3992 ModuleInfo {
3993 file_id: FileId(0),
3994 exports: Vec::new(),
3995 imports: Vec::new(),
3996 re_exports: Vec::new(),
3997 dynamic_imports: Vec::new(),
3998 dynamic_import_patterns: Vec::new(),
3999 require_calls: Vec::new(),
4000 package_path_references: Box::default(),
4001 member_accesses: Vec::new(),
4002 semantic_facts: Box::default(),
4003 whole_object_uses: Box::default(),
4004 has_cjs_exports: false,
4005 has_angular_component_template_url: false,
4006 content_hash: 0,
4007 suppressions: Vec::new(),
4008 unknown_suppression_kinds: Vec::new(),
4009 unused_import_bindings: Vec::new(),
4010 type_referenced_import_bindings: Vec::new(),
4011 value_referenced_import_bindings: Vec::new(),
4012 line_offsets: Vec::new(),
4013 complexity: Vec::new(),
4014 flag_uses: Vec::new(),
4015 class_heritage: Vec::new(),
4016 exported_factory_returns: Box::default(),
4017 injection_tokens: Vec::new(),
4018 local_type_declarations: Vec::new(),
4019 public_signature_type_references: Vec::new(),
4020 namespace_object_aliases: Vec::new(),
4021 iconify_prefixes: Vec::new(),
4022 iconify_icon_names: Vec::new(),
4023 auto_import_candidates: Vec::new(),
4024 directives: Vec::new(),
4025 client_only_dynamic_import_spans: Vec::new(),
4026 security_sinks: Vec::new(),
4027 security_sinks_skipped: 0,
4028 security_unresolved_callee_sites: Vec::new(),
4029 tainted_bindings: Vec::new(),
4030 sanitized_sink_args: Vec::new(),
4031 security_control_sites: Vec::new(),
4032 callee_uses: Vec::new(),
4033 misplaced_directives: Vec::new(),
4034 inline_server_action_exports: Vec::new(),
4035 di_key_sites: Vec::new(),
4036 has_dynamic_provide: false,
4037 referenced_import_bindings: Vec::new(),
4038 component_props: Vec::new(),
4039 has_props_attrs_fallthrough: false,
4040 has_define_expose: false,
4041 has_define_model: false,
4042 has_unharvestable_props: false,
4043 component_emits: Vec::new(),
4044 angular_inputs: Vec::new(),
4045 angular_outputs: Vec::new(),
4046 angular_component_selectors: Vec::new(),
4047 registered_custom_elements: Vec::new(),
4048 used_custom_element_tags: Vec::new(),
4049 angular_used_selectors: Vec::new(),
4050 angular_entry_component_refs: Vec::new(),
4051 has_dynamic_component_render: false,
4052 has_unharvestable_emits: false,
4053 has_dynamic_emit: false,
4054 has_emit_whole_object_use: false,
4055 load_return_keys: Vec::new(),
4056 has_unharvestable_load: false,
4057 has_load_data_whole_use: false,
4058 has_page_data_store_whole_use: false,
4059 component_functions: Vec::new(),
4060 react_props: Vec::new(),
4061 hook_uses: Vec::new(),
4062 render_edges: Vec::new(),
4063 svelte_dispatched_events: Vec::new(),
4064 svelte_listened_events: Vec::new(),
4065 has_dynamic_dispatch: false,
4066 }
4067 }
4068
4069 fn push_semantic_fact(module: &mut ModuleInfo, fact: SemanticFact) {
4070 let mut facts = std::mem::take(&mut module.semantic_facts).into_vec();
4071 facts.push(fact);
4072 module.semantic_facts = facts.into_boxed_slice();
4073 }
4074
4075 #[test]
4076 fn dynamic_custom_element_render_helper_prefers_typed_fact() {
4077 let mut module = minimal_module_info();
4078 push_semantic_fact(
4079 &mut module,
4080 SemanticFact::DynamicCustomElementRender(DynamicCustomElementRenderFact),
4081 );
4082
4083 assert!(has_dynamic_custom_element_render(&module));
4084 }
4085
4086 #[test]
4087 fn function_complexity_bitcode_roundtrip() {
4088 let fc = FunctionComplexity {
4089 name: "processData".to_string(),
4090 line: 42,
4091 col: 4,
4092 cyclomatic: 15,
4093 cognitive: 25,
4094 line_count: 80,
4095 param_count: 3,
4096 react_hook_count: 0,
4097 react_jsx_max_depth: 0,
4098 react_prop_count: 0,
4099 source_hash: Some("0123456789abcdef".to_string()),
4100 contributions: vec![
4101 ComplexityContribution {
4102 line: 43,
4103 col: 8,
4104 metric: ComplexityMetric::Cyclomatic,
4105 kind: ComplexityContributionKind::If,
4106 weight: 1,
4107 nesting: 0,
4108 },
4109 ComplexityContribution {
4110 line: 45,
4111 col: 12,
4112 metric: ComplexityMetric::Cognitive,
4113 kind: ComplexityContributionKind::ElseIf,
4114 weight: 3,
4115 nesting: 2,
4116 },
4117 ],
4118 };
4119 let bytes = bitcode::encode(&fc);
4120 let decoded: FunctionComplexity = bitcode::decode(&bytes).unwrap();
4121 assert_eq!(decoded.name, "processData");
4122 assert_eq!(decoded.line, 42);
4123 assert_eq!(decoded.col, 4);
4124 assert_eq!(decoded.cyclomatic, 15);
4125 assert_eq!(decoded.cognitive, 25);
4126 assert_eq!(decoded.line_count, 80);
4127 assert_eq!(decoded.source_hash.as_deref(), Some("0123456789abcdef"));
4128 assert_eq!(decoded.contributions.len(), 2);
4129 assert_eq!(
4130 decoded.contributions[1].kind,
4131 ComplexityContributionKind::ElseIf
4132 );
4133 assert_eq!(decoded.contributions[1].weight, 3);
4134 assert_eq!(decoded.contributions[1].nesting, 2);
4135 assert_eq!(decoded.contributions[1].metric, ComplexityMetric::Cognitive);
4136 }
4137}