1use crate::{build_runtime_error, create_class_object, make_cell_with_shape, RuntimeError};
2use runmat_accelerate_api::{AccelProvider, GpuTensorHandle, GpuTensorStorage, HostTensorOwned};
3use runmat_builtins::{
4 builtin_functions, ComplexTensor, LogicalArray, NumericDType, Tensor, Value,
5};
6use std::cell::RefCell;
7
8thread_local! {
9 static CLASS_ACCESS_CONTEXT: RefCell<Option<String>> = const { RefCell::new(None) };
10}
11
12#[cfg(target_arch = "wasm32")]
13fn ensure_wasm_builtins_registered() {
14 crate::builtins::wasm_registry::register_all();
15}
16
17#[cfg(not(target_arch = "wasm32"))]
18fn ensure_wasm_builtins_registered() {}
19
20pub struct ClassAccessContextGuard {
21 previous: Option<String>,
22}
23
24impl Drop for ClassAccessContextGuard {
25 fn drop(&mut self) {
26 let previous = self.previous.take();
27 CLASS_ACCESS_CONTEXT.with(|slot| {
28 *slot.borrow_mut() = previous;
29 });
30 }
31}
32
33pub fn push_class_access_context(class_name: Option<String>) -> ClassAccessContextGuard {
34 let previous =
35 CLASS_ACCESS_CONTEXT.with(|slot| std::mem::replace(&mut *slot.borrow_mut(), class_name));
36 ClassAccessContextGuard { previous }
37}
38
39fn current_class_access_context() -> Option<String> {
40 CLASS_ACCESS_CONTEXT.with(|slot| slot.borrow().clone())
41}
42
43pub fn class_access_context() -> Option<String> {
44 current_class_access_context()
45}
46
47pub fn is_gpu_value(value: &Value) -> bool {
49 matches!(value, Value::GpuTensor(_))
50}
51
52pub fn value_contains_gpu(value: &Value) -> bool {
54 match value {
55 Value::GpuTensor(_) => true,
56 Value::Cell(ca) => ca.data.iter().any(|ptr| value_contains_gpu(ptr)),
57 Value::Struct(sv) => sv.fields.values().any(value_contains_gpu),
58 Value::Object(obj) => obj.properties.values().any(value_contains_gpu),
59 Value::Closure(closure) => closure.captures.iter().any(value_contains_gpu),
60 Value::OutputList(values) => values.iter().any(value_contains_gpu),
61 _ => false,
62 }
63}
64
65pub async fn gather_if_needed_async(value: &Value) -> Result<Value, RuntimeError> {
68 gather_if_needed_async_impl(value).await
69}
70
71pub async fn download_handle_async(
72 provider: &dyn AccelProvider,
73 handle: &GpuTensorHandle,
74) -> anyhow::Result<HostTensorOwned> {
75 provider.download(handle).await
76}
77
78fn gather_if_needed_async_impl<'a>(
79 value: &'a Value,
80) -> std::pin::Pin<Box<dyn std::future::Future<Output = Result<Value, RuntimeError>> + 'a>> {
81 Box::pin(async move {
82 match value {
83 Value::GpuTensor(handle) => {
84 #[cfg(all(test, feature = "wgpu"))]
86 {
87 if handle.device_id != 0 {
88 let _ = runmat_accelerate::backend::wgpu::provider::register_wgpu_provider(
89 runmat_accelerate::backend::wgpu::provider::WgpuProviderOptions::default(),
90 );
91 }
92 }
93 let provider =
94 runmat_accelerate_api::provider_for_handle(handle).ok_or_else(|| {
95 build_runtime_error("gather: no acceleration provider registered")
96 .with_identifier("RunMat:gather:ProviderUnavailable")
97 .build()
98 })?;
99 let is_logical = runmat_accelerate_api::handle_is_logical(handle);
100 let host = download_handle_async(provider, handle)
101 .await
102 .map_err(|err| {
103 build_runtime_error(format!("gather: {err}"))
104 .with_identifier("RunMat:gather:DownloadFailed")
105 .build()
106 })?;
107 runmat_accelerate_api::clear_residency(handle);
108 let runmat_accelerate_api::HostTensorOwned {
109 data,
110 shape,
111 storage,
112 } = host;
113 if is_logical {
114 let bits: Vec<u8> =
115 data.iter().map(|&v| if v != 0.0 { 1 } else { 0 }).collect();
116 let logical = LogicalArray::new(bits, shape).map_err(|e| {
117 build_runtime_error(format!("gather: {e}"))
118 .with_identifier("RunMat:gather:LogicalShapeError")
119 .build()
120 })?;
121 Ok(Value::LogicalArray(logical))
122 } else if storage == GpuTensorStorage::ComplexInterleaved {
123 let mut data = data;
124 let precision = runmat_accelerate_api::handle_precision(handle)
125 .unwrap_or_else(|| provider.precision());
126 if matches!(precision, runmat_accelerate_api::ProviderPrecision::F32) {
127 for value in &mut data {
128 *value = (*value as f32) as f64;
129 }
130 }
131 let mut complex = Vec::with_capacity(data.len() / 2);
132 for chunk in data.chunks_exact(2) {
133 complex.push((chunk[0], chunk[1]));
134 }
135 let tensor = ComplexTensor::new(complex, shape).map_err(|e| {
136 build_runtime_error(format!("gather: {e}"))
137 .with_identifier("RunMat:gather:TensorShapeError")
138 .build()
139 })?;
140 Ok(Value::ComplexTensor(tensor))
141 } else {
142 let mut data = data;
143 let precision = runmat_accelerate_api::handle_precision(handle)
144 .unwrap_or_else(|| provider.precision());
145 if matches!(precision, runmat_accelerate_api::ProviderPrecision::F32) {
146 for value in &mut data {
147 *value = (*value as f32) as f64;
148 }
149 }
150 let dtype = match precision {
151 runmat_accelerate_api::ProviderPrecision::F32 => NumericDType::F32,
152 runmat_accelerate_api::ProviderPrecision::F64 => NumericDType::F64,
153 };
154 let tensor = Tensor::new_with_dtype(data, shape, dtype).map_err(|e| {
155 build_runtime_error(format!("gather: {e}"))
156 .with_identifier("RunMat:gather:TensorShapeError")
157 .build()
158 })?;
159 Ok(Value::Tensor(tensor))
160 }
161 }
162 Value::Cell(ca) => {
163 let mut gathered = Vec::with_capacity(ca.data.len());
164 for ptr in &ca.data {
165 gathered.push(gather_if_needed_async_impl(ptr).await?);
166 }
167 make_cell_with_shape(gathered, ca.shape.clone()).map_err(|err| {
168 build_runtime_error(format!("gather: {err}"))
169 .with_identifier("RunMat:gather:CellShapeError")
170 .build()
171 })
172 }
173 Value::Struct(sv) => {
174 let mut gathered = sv.clone();
175 for value in gathered.fields.values_mut() {
176 let updated = gather_if_needed_async_impl(value).await?;
177 *value = updated;
178 }
179 Ok(Value::Struct(gathered))
180 }
181 Value::Object(obj) => {
182 let mut cloned = obj.clone();
183 for value in cloned.properties.values_mut() {
184 *value = gather_if_needed_async_impl(value).await?;
185 }
186 Ok(Value::Object(cloned))
187 }
188 Value::Closure(closure) => {
189 let mut cloned = closure.clone();
190 for value in &mut cloned.captures {
191 *value = gather_if_needed_async_impl(value).await?;
192 }
193 Ok(Value::Closure(cloned))
194 }
195 Value::OutputList(values) => {
196 let mut gathered = Vec::with_capacity(values.len());
197 for value in values {
198 gathered.push(gather_if_needed_async_impl(value).await?);
199 }
200 Ok(Value::OutputList(gathered))
201 }
202 other => Ok(other.clone()),
203 }
204 })
205}
206
207#[cfg(not(target_arch = "wasm32"))]
208pub fn gather_if_needed(value: &Value) -> Result<Value, RuntimeError> {
209 futures::executor::block_on(gather_if_needed_async(value))
210}
211
212#[cfg(target_arch = "wasm32")]
213pub fn gather_if_needed(_value: &Value) -> Result<Value, RuntimeError> {
214 Err(
215 build_runtime_error("gather: synchronous gather is unavailable on wasm")
216 .with_identifier("RunMat:gather:UnavailableOnWasm")
217 .build(),
218 )
219}
220
221pub fn call_builtin(name: &str, args: &[Value]) -> Result<Value, RuntimeError> {
225 futures::executor::block_on(call_builtin_async(name, args))
226}
227
228#[async_recursion::async_recursion(?Send)]
229async fn call_builtin_async_impl(
230 name: &str,
231 args: &[Value],
232 output_count: Option<usize>,
233) -> Result<Value, RuntimeError> {
234 ensure_wasm_builtins_registered();
235
236 let _output_guard = crate::output_count::push_output_count(output_count);
237 let mut matching_builtins = Vec::new();
238
239 for b in builtin_functions() {
241 if b.name == name {
242 matching_builtins.push(b);
243 }
244 }
245
246 if matching_builtins.is_empty() {
247 if let Some(result) = try_call_registered_instance_method(name, args, output_count).await? {
248 return Ok(result);
249 }
250 if let Some(result) = try_call_registered_static_method(name, args, output_count).await? {
251 return Ok(result);
252 }
253 if runmat_builtins::get_class(name).is_some() {
255 return call_registered_class_constructor(name, args, output_count).await;
256 }
257 return Err(build_runtime_error(format!("Undefined function: {name}"))
258 .with_identifier("RunMat:UndefinedFunction")
259 .build());
260 }
261
262 let mut no_category: Vec<&runmat_builtins::BuiltinFunction> = Vec::new();
264 let mut categorized: Vec<&runmat_builtins::BuiltinFunction> = Vec::new();
265 for b in matching_builtins {
266 if b.category.is_empty() {
267 no_category.push(b);
268 } else {
269 categorized.push(b);
270 }
271 }
272 let matching_count = no_category.len() + categorized.len();
273
274 let mut last_error = RuntimeError::new("unknown error");
277 for builtin in no_category
278 .into_iter()
279 .rev()
280 .chain(categorized.into_iter().rev())
281 {
282 let f = builtin.implementation;
283 match (f)(args).await {
284 Ok(mut result) => {
285 if matches!(name, "eq" | "ne" | "gt" | "ge" | "lt" | "le") {
289 if let Value::Bool(flag) = result {
290 result = Value::Num(if flag { 1.0 } else { 0.0 });
291 }
292 }
293 return Ok(result);
294 }
295 Err(err) => {
296 if should_retry_with_gpu_gather(&err, args) {
297 match gather_args_for_retry_async(args).await {
298 Ok(Some(gathered_args)) => match (f)(&gathered_args).await {
299 Ok(result) => return Ok(result),
300 Err(retry_err) => last_error = retry_err,
301 },
302 Ok(None) => last_error = err,
303 Err(gather_err) => last_error = gather_err,
304 }
305 } else {
306 last_error = err;
307 }
308 }
309 }
310 }
311
312 if matching_count == 1 || last_error.identifier().is_some() {
316 return Err(last_error);
317 }
318
319 let identifier = last_error
321 .identifier()
322 .unwrap_or("RunMat:NoMatchingOverload")
323 .to_string();
324 let mut builder = build_runtime_error(format!(
325 "No matching overload for `{}` with {} args: {}",
326 name,
327 args.len(),
328 last_error.message()
329 ))
330 .with_source(last_error);
331 builder = builder.with_identifier(identifier);
332 Err(builder.build())
333}
334
335async fn try_call_registered_instance_method(
336 method_name: &str,
337 args: &[Value],
338 output_count: Option<usize>,
339) -> Result<Option<Value>, RuntimeError> {
340 let Some(receiver) = args.first() else {
341 return Ok(None);
342 };
343 let class_name = match receiver {
344 Value::Object(obj) => obj.class_name.as_str(),
345 Value::HandleObject(handle) => handle.class_name.as_str(),
346 _ => return Ok(None),
347 };
348 let Some((method, owner)) = runmat_builtins::lookup_method(class_name, method_name) else {
349 return Ok(None);
350 };
351 if method.is_static {
352 return Ok(None);
353 }
354 let caller_class = current_class_access_context();
355 let access_allowed = match method.access {
356 runmat_builtins::Access::Public => true,
357 runmat_builtins::Access::Private => caller_class.as_deref() == Some(owner.as_str()),
358 runmat_builtins::Access::Protected => caller_class
359 .as_deref()
360 .is_some_and(|caller| runmat_builtins::is_class_or_subclass(caller, &owner)),
361 };
362 if !access_allowed {
363 return Err(build_runtime_error(format!(
364 "Method '{}' is not accessible from current context.",
365 method_name
366 ))
367 .with_identifier("RunMat:MethodPrivate")
368 .build());
369 }
370 if let Some(result) = crate::user_functions::try_call_semantic_function_by_name(
371 &method.function_name,
372 args,
373 output_count.unwrap_or(1),
374 )
375 .await
376 {
377 return result.map(Some);
378 }
379 let owner_qualified = format!("{owner}.{method_name}");
380 if owner_qualified != method.function_name {
381 if let Some(result) = crate::user_functions::try_call_semantic_function_by_name(
382 &owner_qualified,
383 args,
384 output_count.unwrap_or(1),
385 )
386 .await
387 {
388 return result.map(Some);
389 }
390 }
391 Ok(None)
392}
393
394async fn try_call_registered_static_method(
395 qualified_name: &str,
396 args: &[Value],
397 output_count: Option<usize>,
398) -> Result<Option<Value>, RuntimeError> {
399 let Some((class_name, method_name)) = qualified_name.rsplit_once('.') else {
400 return Ok(None);
401 };
402 if class_name.trim().is_empty() || method_name.trim().is_empty() {
403 return Ok(None);
404 }
405 if runmat_builtins::get_class(class_name).is_none() {
406 return Ok(None);
407 }
408 let Some((method, owner)) = runmat_builtins::lookup_method(class_name, method_name) else {
409 return Ok(None);
410 };
411 if !method.is_static || method.access != runmat_builtins::Access::Public {
412 return Ok(None);
413 }
414 if let Some(result) = crate::user_functions::try_call_semantic_function_by_name(
415 &method.function_name,
416 args,
417 output_count.unwrap_or(1),
418 )
419 .await
420 {
421 return result.map(Some);
422 }
423 let owner_qualified = format!("{owner}.{method_name}");
424 if owner_qualified != method.function_name {
425 if let Some(result) = crate::user_functions::try_call_semantic_function_by_name(
426 &owner_qualified,
427 args,
428 output_count.unwrap_or(1),
429 )
430 .await
431 {
432 return result.map(Some);
433 }
434 }
435 Ok(None)
436}
437
438async fn call_registered_class_constructor(
439 class_name: &str,
440 args: &[Value],
441 output_count: Option<usize>,
442) -> Result<Value, RuntimeError> {
443 let requested_outputs = output_count.unwrap_or(1);
444 let default_object = create_class_object(class_name.to_string()).await?;
445 let constructor_method_name = class_name.rsplit('.').next().unwrap_or(class_name);
446 let Some((ctor, owner)) = runmat_builtins::lookup_method(class_name, constructor_method_name)
447 .or_else(|| runmat_builtins::lookup_method(class_name, class_name))
448 else {
449 return Ok(default_object);
450 };
451 let owner_qualified = format!("{owner}.{constructor_method_name}");
452 let caller_class = current_class_access_context();
453 let ctor_access_allowed = match ctor.access {
454 runmat_builtins::Access::Public => true,
455 runmat_builtins::Access::Private => caller_class.as_deref() == Some(owner.as_str()),
456 runmat_builtins::Access::Protected => caller_class
457 .as_deref()
458 .is_some_and(|caller| runmat_builtins::is_class_or_subclass(caller, &owner)),
459 };
460 if !ctor_access_allowed {
461 return Err(build_runtime_error(format!(
462 "Constructor '{}' is not accessible from current context.",
463 class_name
464 ))
465 .with_identifier("RunMat:MethodPrivate")
466 .build());
467 }
468 let Some(result) = crate::user_functions::try_call_semantic_function_by_name(
469 &ctor.function_name,
470 args,
471 requested_outputs,
472 )
473 .await
474 else {
475 let Some(result) = crate::user_functions::try_call_semantic_function_by_name(
476 &owner_qualified,
477 args,
478 requested_outputs,
479 )
480 .await
481 else {
482 return Ok(default_object);
483 };
484 return normalize_constructor_result(default_object, result?, requested_outputs);
485 };
486 normalize_constructor_result(default_object, result?, requested_outputs)
487}
488
489fn normalize_constructor_result(
490 default_object: Value,
491 result: Value,
492 requested_outputs: usize,
493) -> Result<Value, RuntimeError> {
494 if requested_outputs != 1 {
495 return Ok(result);
496 }
497 match result {
498 Value::Struct(struct_value) => match default_object {
499 Value::Object(mut object) => {
500 for (field, value) in struct_value.fields {
501 object.properties.insert(field, value);
502 }
503 Ok(Value::Object(object))
504 }
505 Value::HandleObject(handle) => {
506 let raw = unsafe { handle.target.as_raw_mut() };
507 if raw.is_null() {
508 return Ok(Value::HandleObject(handle));
509 }
510 if let Value::Object(mut object) = unsafe { (&*raw).clone() } {
511 for (field, value) in struct_value.fields {
512 object.properties.insert(field, value);
513 }
514 unsafe {
515 *raw = Value::Object(object);
516 }
517 }
518 Ok(Value::HandleObject(handle))
519 }
520 _ => Ok(Value::Struct(struct_value)),
521 },
522 Value::Object(_) | Value::HandleObject(_) => Ok(result),
523 _ => Ok(default_object),
524 }
525}
526
527pub async fn call_builtin_async(name: &str, args: &[Value]) -> Result<Value, RuntimeError> {
528 call_builtin_async_impl(name, args, None).await
529}
530
531pub async fn call_builtin_async_with_outputs(
532 name: &str,
533 args: &[Value],
534 output_count: usize,
535) -> Result<Value, RuntimeError> {
536 call_builtin_async_impl(name, args, Some(output_count)).await
537}
538
539fn should_retry_with_gpu_gather(err: &RuntimeError, args: &[Value]) -> bool {
540 if !args.iter().any(value_contains_gpu) {
541 return false;
542 }
543 let lowered = err.message().to_ascii_lowercase();
544 lowered.contains("gpu")
545}
546
547async fn gather_args_for_retry_async(args: &[Value]) -> Result<Option<Vec<Value>>, RuntimeError> {
548 let mut gathered_any = false;
549 let mut gathered_args = Vec::with_capacity(args.len());
550 for arg in args {
551 if value_contains_gpu(arg) {
552 gathered_args.push(gather_if_needed_async(arg).await?);
553 gathered_any = true;
554 } else {
555 gathered_args.push(arg.clone());
556 }
557 }
558 if gathered_any {
559 Ok(Some(gathered_args))
560 } else {
561 Ok(None)
562 }
563}
564
565#[cfg(test)]
566mod tests {
567 use super::{call_builtin, gather_if_needed_async, value_contains_gpu};
568 use runmat_accelerate_api::{GpuTensorHandle, ThreadProviderGuard};
569 use runmat_builtins::{
570 register_class, Access, ClassDef, Closure, MethodDef, StructValue, Value,
571 };
572 use std::collections::HashMap;
573 use std::sync::atomic::{AtomicU64, Ordering};
574
575 static TEST_CLASS_COUNTER: AtomicU64 = AtomicU64::new(0);
576
577 fn unique_class_name(prefix: &str) -> String {
578 let id = TEST_CLASS_COUNTER.fetch_add(1, Ordering::Relaxed);
579 format!("{}_{}", prefix, id)
580 }
581
582 #[test]
583 fn value_contains_gpu_detects_nested_closure_captures() {
584 let value = Value::Closure(Closure {
585 function_name: "worker".to_string(),
586 bound_function: None,
587 captures: vec![Value::GpuTensor(GpuTensorHandle {
588 shape: vec![1],
589 device_id: 999,
590 buffer_id: 42,
591 })],
592 });
593 assert!(value_contains_gpu(&value));
594 }
595
596 #[test]
597 fn value_contains_gpu_detects_output_list_entries() {
598 let value = Value::OutputList(vec![
599 Value::Num(1.0),
600 Value::GpuTensor(GpuTensorHandle {
601 shape: vec![1],
602 device_id: 998,
603 buffer_id: 43,
604 }),
605 ]);
606 assert!(value_contains_gpu(&value));
607 }
608
609 #[test]
610 fn gather_if_needed_reports_provider_unavailable_for_nested_output_list_gpu() {
611 runmat_accelerate_api::clear_provider();
612 let _provider_guard = ThreadProviderGuard::set(None);
613 let value = Value::OutputList(vec![Value::GpuTensor(GpuTensorHandle {
614 shape: vec![1],
615 device_id: 0,
617 buffer_id: 44,
618 })]);
619 let err = futures::executor::block_on(gather_if_needed_async(&value))
620 .expect_err("missing provider should fail nested output-list gather");
621 assert_eq!(err.identifier(), Some("RunMat:gather:ProviderUnavailable"));
622 }
623
624 #[test]
625 fn gather_if_needed_reports_provider_unavailable_for_closure_capture_gpu() {
626 runmat_accelerate_api::clear_provider();
627 let _provider_guard = ThreadProviderGuard::set(None);
628 let value = Value::Closure(Closure {
629 function_name: "worker".to_string(),
630 bound_function: None,
631 captures: vec![Value::GpuTensor(GpuTensorHandle {
632 shape: vec![1],
633 device_id: 0,
635 buffer_id: 45,
636 })],
637 });
638 let err = futures::executor::block_on(gather_if_needed_async(&value))
639 .expect_err("missing provider should fail closure-captured gather");
640 assert_eq!(err.identifier(), Some("RunMat:gather:ProviderUnavailable"));
641 }
642
643 #[test]
644 fn constructor_fallback_uses_inherited_constructor_metadata_with_semantic_invoker() {
645 let parent_name = unique_class_name("runtime_ctor_parent");
646 let child_name = unique_class_name("runtime_ctor_child");
647 let ctor_fn_name = unique_class_name("runtime_ctor_fn");
648 let ctor_fn_name_for_resolver = ctor_fn_name.clone();
649 let ctor_fn_name_for_invoker = ctor_fn_name.clone();
650 let _resolver_guard = crate::user_functions::install_semantic_function_resolver(Some(
651 std::sync::Arc::new(move |name| (name == ctor_fn_name_for_resolver).then_some(10101)),
652 ));
653 let _invoker_guard = crate::user_functions::install_semantic_function_invoker(Some(
654 std::sync::Arc::new(move |function, _args, requested_outputs| {
655 assert_eq!(function, 10101);
656 assert_eq!(requested_outputs, 1);
657 let mut sv = StructValue::new();
658 sv.fields.insert("x".to_string(), Value::Num(12.0));
659 Box::pin(async move { Ok(Value::Struct(sv)) })
660 }),
661 ));
662
663 let mut parent_methods = HashMap::new();
664 parent_methods.insert(
665 child_name.clone(),
666 MethodDef {
667 name: child_name.clone(),
668 is_static: true,
669 is_abstract: false,
670 is_sealed: false,
671 access: Access::Public,
672 function_name: ctor_fn_name_for_invoker,
673 implicit_class_argument: None,
674 },
675 );
676 register_class(ClassDef {
677 name: parent_name.clone(),
678 parent: None,
679 properties: HashMap::new(),
680 methods: parent_methods,
681 });
682 register_class(ClassDef {
683 name: child_name.clone(),
684 parent: Some(parent_name),
685 properties: HashMap::new(),
686 methods: HashMap::new(),
687 });
688
689 let out =
690 call_builtin(&child_name, &[]).expect("inherited static constructor should dispatch");
691 let Value::Object(obj) = out else {
692 panic!("expected object from constructor dispatch");
693 };
694 assert_eq!(obj.class_name, child_name);
695 assert_eq!(obj.properties.get("x"), Some(&Value::Num(12.0)));
696 }
697
698 #[test]
699 fn constructor_fallback_defaults_when_constructor_is_private_or_unavailable() {
700 let private_class_name = unique_class_name("runtime_ctor_private");
701 let mut private_methods = HashMap::new();
702 private_methods.insert(
703 private_class_name.clone(),
704 MethodDef {
705 name: private_class_name.clone(),
706 is_static: true,
707 is_abstract: false,
708 is_sealed: false,
709 access: Access::Private,
710 function_name: "Point.origin".to_string(),
711 implicit_class_argument: None,
712 },
713 );
714 register_class(ClassDef {
715 name: private_class_name.clone(),
716 parent: None,
717 properties: HashMap::new(),
718 methods: private_methods,
719 });
720 let err = call_builtin(&private_class_name, &[])
721 .expect_err("private constructor should enforce access before default fallback");
722 assert_eq!(err.identifier(), Some("RunMat:MethodPrivate"));
723
724 let public_class_name = unique_class_name("runtime_ctor_public_no_semantic");
725 let mut public_methods = HashMap::new();
726 public_methods.insert(
727 public_class_name.clone(),
728 MethodDef {
729 name: public_class_name.clone(),
730 is_static: true,
731 is_abstract: false,
732 is_sealed: false,
733 access: Access::Public,
734 function_name: "Point.origin".to_string(),
735 implicit_class_argument: None,
736 },
737 );
738 register_class(ClassDef {
739 name: public_class_name.clone(),
740 parent: None,
741 properties: HashMap::new(),
742 methods: public_methods,
743 });
744
745 let out = call_builtin(&public_class_name, &[])
746 .expect("public ctor metadata without semantic body should default-construct");
747 let Value::Object(obj) = out else {
748 panic!("expected object result");
749 };
750 assert_eq!(obj.class_name, public_class_name);
751 }
752
753 #[test]
754 fn dotted_static_method_name_dispatches_to_registered_class_method() {
755 let class_name = unique_class_name("runtime_static_dispatch");
756 let fn_name = unique_class_name("runtime_static_fn");
757 register_class(ClassDef {
758 name: class_name.clone(),
759 parent: None,
760 properties: HashMap::new(),
761 methods: {
762 let mut methods = HashMap::new();
763 methods.insert(
764 "zero".to_string(),
765 MethodDef {
766 name: "zero".to_string(),
767 is_static: true,
768 is_abstract: false,
769 is_sealed: false,
770 access: Access::Public,
771 function_name: fn_name.clone(),
772 implicit_class_argument: None,
773 },
774 );
775 methods
776 },
777 });
778
779 let fn_name_for_resolver = fn_name.clone();
780 let _resolver_guard = crate::user_functions::install_semantic_function_resolver(Some(
781 std::sync::Arc::new(move |name| (name == fn_name_for_resolver).then_some(20202)),
782 ));
783 let _invoker_guard = crate::user_functions::install_semantic_function_invoker(Some(
784 std::sync::Arc::new(move |function, _args, requested_outputs| {
785 assert_eq!(function, 20202);
786 assert_eq!(requested_outputs, 1);
787 Box::pin(async { Ok(Value::Num(77.0)) })
788 }),
789 ));
790
791 let out = call_builtin(&format!("{class_name}.zero"), &[])
792 .expect("dotted static class method call should dispatch");
793 assert_eq!(out, Value::Num(77.0));
794 }
795}