//! AST -> `ItemTree` lowering code.
use super::*;
use crate::{
attr::Attrs,
generics::{GenericParams, TypeParamData, TypeParamProvenance},
};
use hir_expand::{ast_id_map::AstIdMap, hygiene::Hygiene, HirFileId};
use ra_arena::map::ArenaMap;
use ra_syntax::{
ast::{self, ModuleItemOwner},
SyntaxNode,
};
use smallvec::SmallVec;
use std::{collections::hash_map::Entry, mem, sync::Arc};
fn id<N: ItemTreeNode>(index: Idx<N>) -> FileItemTreeId<N> {
FileItemTreeId { index, _p: PhantomData }
}
struct ModItems(SmallVec<[ModItem; 1]>);
impl<T> From<T> for ModItems
where
T: Into<ModItem>,
{
fn from(t: T) -> Self {
ModItems(SmallVec::from_buf([t.into(); 1]))
}
}
pub(super) struct Ctx {
tree: ItemTree,
hygiene: Hygiene,
file: HirFileId,
source_ast_id_map: Arc<AstIdMap>,
body_ctx: crate::body::LowerCtx,
inner_items: Vec<ModItem>,
forced_visibility: Option<RawVisibilityId>,
}
impl Ctx {
pub(super) fn new(db: &dyn DefDatabase, hygiene: Hygiene, file: HirFileId) -> Self {
Self {
tree: ItemTree::empty(),
hygiene,
file,
source_ast_id_map: db.ast_id_map(file),
body_ctx: crate::body::LowerCtx::new(db, file),
inner_items: Vec::new(),
forced_visibility: None,
}
}
pub(super) fn lower_module_items(mut self, item_owner: &dyn ModuleItemOwner) -> ItemTree {
self.tree.top_level = item_owner
.items()
.flat_map(|item| self.lower_mod_item(&item, false))
.flat_map(|items| items.0)
.collect();
self.tree
}
pub(super) fn lower_inner_items(mut self, within: &SyntaxNode) -> ItemTree {
self.collect_inner_items(within);
self.tree
}
fn data(&mut self) -> &mut ItemTreeData {
self.tree.data_mut()
}
fn lower_mod_item(&mut self, item: &ast::ModuleItem, inner: bool) -> Option<ModItems> {
assert!(inner || self.inner_items.is_empty());
// Collect inner items for 1-to-1-lowered items.
match item {
ast::ModuleItem::StructDef(_)
| ast::ModuleItem::UnionDef(_)
| ast::ModuleItem::EnumDef(_)
| ast::ModuleItem::FnDef(_)
| ast::ModuleItem::TypeAliasDef(_)
| ast::ModuleItem::ConstDef(_)
| ast::ModuleItem::StaticDef(_)
| ast::ModuleItem::MacroCall(_) => {
// Skip this if we're already collecting inner items. We'll descend into all nodes
// already.
if !inner {
self.collect_inner_items(item.syntax());
}
}
// These are handled in their respective `lower_X` method (since we can't just blindly
// walk them).
ast::ModuleItem::TraitDef(_)
| ast::ModuleItem::ImplDef(_)
| ast::ModuleItem::ExternBlock(_) => {}
// These don't have inner items.
ast::ModuleItem::Module(_)
| ast::ModuleItem::ExternCrateItem(_)
| ast::ModuleItem::UseItem(_) => {}
};
let attrs = Attrs::new(item, &self.hygiene);
let items = match item {
ast::ModuleItem::StructDef(ast) => self.lower_struct(ast).map(Into::into),
ast::ModuleItem::UnionDef(ast) => self.lower_union(ast).map(Into::into),
ast::ModuleItem::EnumDef(ast) => self.lower_enum(ast).map(Into::into),
ast::ModuleItem::FnDef(ast) => self.lower_function(ast).map(Into::into),
ast::ModuleItem::TypeAliasDef(ast) => self.lower_type_alias(ast).map(Into::into),
ast::ModuleItem::StaticDef(ast) => self.lower_static(ast).map(Into::into),
ast::ModuleItem::ConstDef(ast) => Some(self.lower_const(ast).into()),
ast::ModuleItem::Module(ast) => self.lower_module(ast).map(Into::into),
ast::ModuleItem::TraitDef(ast) => self.lower_trait(ast).map(Into::into),
ast::ModuleItem::ImplDef(ast) => self.lower_impl(ast).map(Into::into),
ast::ModuleItem::UseItem(ast) => Some(ModItems(
self.lower_use(ast).into_iter().map(Into::into).collect::<SmallVec<_>>(),
)),
ast::ModuleItem::ExternCrateItem(ast) => self.lower_extern_crate(ast).map(Into::into),
ast::ModuleItem::MacroCall(ast) => self.lower_macro_call(ast).map(Into::into),
ast::ModuleItem::ExternBlock(ast) => {
Some(ModItems(self.lower_extern_block(ast).into_iter().collect::<SmallVec<_>>()))
}
};
if !attrs.is_empty() {
for item in items.iter().flat_map(|items| &items.0) {
self.add_attrs((*item).into(), attrs.clone());
}
}
items
}
fn add_attrs(&mut self, item: AttrOwner, attrs: Attrs) {
match self.tree.attrs.entry(item) {
Entry::Occupied(mut entry) => {
*entry.get_mut() = entry.get().merge(attrs);
}
Entry::Vacant(entry) => {
entry.insert(attrs);
}
}
}
fn collect_inner_items(&mut self, container: &SyntaxNode) {
let forced_vis = self.forced_visibility.take();
let mut inner_items = mem::take(&mut self.tree.inner_items);
inner_items.extend(
container.descendants().skip(1).filter_map(ast::ModuleItem::cast).filter_map(|item| {
let ast_id = self.source_ast_id_map.ast_id(&item);
Some((ast_id, self.lower_mod_item(&item, true)?.0))
}),
);
self.tree.inner_items = inner_items;
self.forced_visibility = forced_vis;
}
fn lower_assoc_item(&mut self, item: &ast::ModuleItem) -> Option<AssocItem> {
match item {
ast::ModuleItem::FnDef(ast) => self.lower_function(ast).map(Into::into),
ast::ModuleItem::TypeAliasDef(ast) => self.lower_type_alias(ast).map(Into::into),
ast::ModuleItem::ConstDef(ast) => Some(self.lower_const(ast).into()),
ast::ModuleItem::MacroCall(ast) => self.lower_macro_call(ast).map(Into::into),
_ => None,
}
}
fn lower_struct(&mut self, strukt: &ast::StructDef) -> Option<FileItemTreeId<Struct>> {
let visibility = self.lower_visibility(strukt);
let name = strukt.name()?.as_name();
let generic_params = self.lower_generic_params(GenericsOwner::Struct, strukt);
let fields = self.lower_fields(&strukt.kind());
let ast_id = self.source_ast_id_map.ast_id(strukt);
let kind = match strukt.kind() {
ast::StructKind::Record(_) => StructDefKind::Record,
ast::StructKind::Tuple(_) => StructDefKind::Tuple,
ast::StructKind::Unit => StructDefKind::Unit,
};
let res = Struct { name, visibility, generic_params, fields, ast_id, kind };
Some(id(self.data().structs.alloc(res)))
}
fn lower_fields(&mut self, strukt_kind: &ast::StructKind) -> Fields {
match strukt_kind {
ast::StructKind::Record(it) => {
let range = self.lower_record_fields(it);
Fields::Record(range)
}
ast::StructKind::Tuple(it) => {
let range = self.lower_tuple_fields(it);
Fields::Tuple(range)
}
ast::StructKind::Unit => Fields::Unit,
}
}
fn lower_record_fields(&mut self, fields: &ast::RecordFieldDefList) -> IdRange<Field> {
let start = self.next_field_idx();
for field in fields.fields() {
if let Some(data) = self.lower_record_field(&field) {
let idx = self.data().fields.alloc(data);
self.add_attrs(idx.into(), Attrs::new(&field, &self.hygiene));
}
}
let end = self.next_field_idx();
IdRange::new(start..end)
}
fn lower_record_field(&mut self, field: &ast::RecordFieldDef) -> Option<Field> {
let name = field.name()?.as_name();
let visibility = self.lower_visibility(field);
let type_ref = self.lower_type_ref_opt(field.ascribed_type());
let res = Field { name, type_ref, visibility };
Some(res)
}
fn lower_tuple_fields(&mut self, fields: &ast::TupleFieldDefList) -> IdRange<Field> {
let start = self.next_field_idx();
for (i, field) in fields.fields().enumerate() {
let data = self.lower_tuple_field(i, &field);
let idx = self.data().fields.alloc(data);
self.add_attrs(idx.into(), Attrs::new(&field, &self.hygiene));
}
let end = self.next_field_idx();
IdRange::new(start..end)
}
fn lower_tuple_field(&mut self, idx: usize, field: &ast::TupleFieldDef) -> Field {
let name = Name::new_tuple_field(idx);
let visibility = self.lower_visibility(field);
let type_ref = self.lower_type_ref_opt(field.type_ref());
let res = Field { name, type_ref, visibility };
res
}
fn lower_union(&mut self, union: &ast::UnionDef) -> Option<FileItemTreeId<Union>> {
let visibility = self.lower_visibility(union);
let name = union.name()?.as_name();
let generic_params = self.lower_generic_params(GenericsOwner::Union, union);
let fields = match union.record_field_def_list() {
Some(record_field_def_list) => {
self.lower_fields(&StructKind::Record(record_field_def_list))
}
None => Fields::Record(IdRange::new(self.next_field_idx()..self.next_field_idx())),
};
let ast_id = self.source_ast_id_map.ast_id(union);
let res = Union { name, visibility, generic_params, fields, ast_id };
Some(id(self.data().unions.alloc(res)))
}
fn lower_enum(&mut self, enum_: &ast::EnumDef) -> Option<FileItemTreeId<Enum>> {
let visibility = self.lower_visibility(enum_);
let name = enum_.name()?.as_name();
let generic_params = self.lower_generic_params(GenericsOwner::Enum, enum_);
let variants = match &enum_.variant_list() {
Some(variant_list) => self.lower_variants(variant_list),
None => IdRange::new(self.next_variant_idx()..self.next_variant_idx()),
};
let ast_id = self.source_ast_id_map.ast_id(enum_);
let res = Enum { name, visibility, generic_params, variants, ast_id };
Some(id(self.data().enums.alloc(res)))
}
fn lower_variants(&mut self, variants: &ast::EnumVariantList) -> IdRange<Variant> {
let start = self.next_variant_idx();
for variant in variants.variants() {
if let Some(data) = self.lower_variant(&variant) {
let idx = self.data().variants.alloc(data);
self.add_attrs(idx.into(), Attrs::new(&variant, &self.hygiene));
}
}
let end = self.next_variant_idx();
IdRange::new(start..end)
}
fn lower_variant(&mut self, variant: &ast::EnumVariant) -> Option<Variant> {
let name = variant.name()?.as_name();
let fields = self.lower_fields(&variant.kind());
let res = Variant { name, fields };
Some(res)
}
fn lower_function(&mut self, func: &ast::FnDef) -> Option<FileItemTreeId<Function>> {
let visibility = self.lower_visibility(func);
let name = func.name()?.as_name();
let mut params = Vec::new();
let mut has_self_param = false;
if let Some(param_list) = func.param_list() {
if let Some(self_param) = param_list.self_param() {
let self_type = match self_param.ascribed_type() {
Some(type_ref) => TypeRef::from_ast(&self.body_ctx, type_ref),
None => {
let self_type = TypeRef::Path(name![Self].into());
match self_param.kind() {
ast::SelfParamKind::Owned => self_type,
ast::SelfParamKind::Ref => {
TypeRef::Reference(Box::new(self_type), Mutability::Shared)
}
ast::SelfParamKind::MutRef => {
TypeRef::Reference(Box::new(self_type), Mutability::Mut)
}
}
}
};
params.push(self_type);
has_self_param = true;
}
for param in param_list.params() {
let type_ref = TypeRef::from_ast_opt(&self.body_ctx, param.ascribed_type());
params.push(type_ref);
}
}
let mut is_varargs = false;
if let Some(params) = func.param_list() {
if let Some(last) = params.params().last() {
is_varargs = last.dotdotdot_token().is_some();
}
}
let ret_type = match func.ret_type().and_then(|rt| rt.type_ref()) {
Some(type_ref) => TypeRef::from_ast(&self.body_ctx, type_ref),
_ => TypeRef::unit(),
};
let ret_type = if func.async_token().is_some() {
let future_impl = desugar_future_path(ret_type);
let ty_bound = TypeBound::Path(future_impl);
TypeRef::ImplTrait(vec![ty_bound])
} else {
ret_type
};
let ast_id = self.source_ast_id_map.ast_id(func);
let mut res = Function {
name,
visibility,
generic_params: GenericParamsId::EMPTY,
has_self_param,
is_unsafe: func.unsafe_token().is_some(),
params: params.into_boxed_slice(),
is_varargs,
ret_type,
ast_id,
};
res.generic_params = self.lower_generic_params(GenericsOwner::Function(&res), func);
Some(id(self.data().functions.alloc(res)))
}
fn lower_type_alias(
&mut self,
type_alias: &ast::TypeAliasDef,
) -> Option<FileItemTreeId<TypeAlias>> {
let name = type_alias.name()?.as_name();
let type_ref = type_alias.type_ref().map(|it| self.lower_type_ref(&it));
let visibility = self.lower_visibility(type_alias);
let bounds = self.lower_type_bounds(type_alias);
let generic_params = self.lower_generic_params(GenericsOwner::TypeAlias, type_alias);
let ast_id = self.source_ast_id_map.ast_id(type_alias);
let res = TypeAlias {
name,
visibility,
bounds: bounds.into_boxed_slice(),
generic_params,
type_ref,
ast_id,
};
Some(id(self.data().type_aliases.alloc(res)))
}
fn lower_static(&mut self, static_: &ast::StaticDef) -> Option<FileItemTreeId<Static>> {
let name = static_.name()?.as_name();
let type_ref = self.lower_type_ref_opt(static_.ascribed_type());
let visibility = self.lower_visibility(static_);
let mutable = static_.mut_token().is_some();
let ast_id = self.source_ast_id_map.ast_id(static_);
let res = Static { name, visibility, mutable, type_ref, ast_id };
Some(id(self.data().statics.alloc(res)))
}
fn lower_const(&mut self, konst: &ast::ConstDef) -> FileItemTreeId<Const> {
let name = konst.name().map(|it| it.as_name());
let type_ref = self.lower_type_ref_opt(konst.ascribed_type());
let visibility = self.lower_visibility(konst);
let ast_id = self.source_ast_id_map.ast_id(konst);
let res = Const { name, visibility, type_ref, ast_id };
id(self.data().consts.alloc(res))
}
fn lower_module(&mut self, module: &ast::Module) -> Option<FileItemTreeId<Mod>> {
let name = module.name()?.as_name();
let visibility = self.lower_visibility(module);
let kind = if module.semicolon_token().is_some() {
ModKind::Outline {}
} else {
ModKind::Inline {
items: module
.item_list()
.map(|list| {
list.items()
.flat_map(|item| self.lower_mod_item(&item, false))
.flat_map(|items| items.0)
.collect()
})
.unwrap_or_else(|| {
mark::hit!(name_res_works_for_broken_modules);
Box::new([]) as Box<[_]>
}),
}
};
let ast_id = self.source_ast_id_map.ast_id(module);
let res = Mod { name, visibility, kind, ast_id };
Some(id(self.data().mods.alloc(res)))
}
fn lower_trait(&mut self, trait_def: &ast::TraitDef) -> Option<FileItemTreeId<Trait>> {
let name = trait_def.name()?.as_name();
let visibility = self.lower_visibility(trait_def);
let generic_params =
self.lower_generic_params_and_inner_items(GenericsOwner::Trait(trait_def), trait_def);
let auto = trait_def.auto_token().is_some();
let items = trait_def.item_list().map(|list| {
self.with_inherited_visibility(visibility, |this| {
list.items()
.filter_map(|item| {
let attrs = Attrs::new(&item, &this.hygiene);
this.collect_inner_items(item.syntax());
this.lower_assoc_item(&item).map(|item| {
this.add_attrs(ModItem::from(item).into(), attrs);
item
})
})
.collect()
})
});
let ast_id = self.source_ast_id_map.ast_id(trait_def);
let res = Trait {
name,
visibility,
generic_params,
auto,
items: items.unwrap_or_default(),
ast_id,
};
Some(id(self.data().traits.alloc(res)))
}
fn lower_impl(&mut self, impl_def: &ast::ImplDef) -> Option<FileItemTreeId<Impl>> {
let generic_params =
self.lower_generic_params_and_inner_items(GenericsOwner::Impl, impl_def);
let target_trait = impl_def.target_trait().map(|tr| self.lower_type_ref(&tr));
let target_type = self.lower_type_ref(&impl_def.target_type()?);
let is_negative = impl_def.excl_token().is_some();
// We cannot use `assoc_items()` here as that does not include macro calls.
let items = impl_def
.item_list()
.into_iter()
.flat_map(|it| it.items())
.filter_map(|item| {
self.collect_inner_items(item.syntax());
let assoc = self.lower_assoc_item(&item)?;
let attrs = Attrs::new(&item, &self.hygiene);
self.add_attrs(ModItem::from(assoc).into(), attrs);
Some(assoc)
})
.collect();
let ast_id = self.source_ast_id_map.ast_id(impl_def);
let res = Impl { generic_params, target_trait, target_type, is_negative, items, ast_id };
Some(id(self.data().impls.alloc(res)))
}
fn lower_use(&mut self, use_item: &ast::UseItem) -> Vec<FileItemTreeId<Import>> {
// FIXME: cfg_attr
let is_prelude = use_item.has_atom_attr("prelude_import");
let visibility = self.lower_visibility(use_item);
let ast_id = self.source_ast_id_map.ast_id(use_item);
// Every use item can expand to many `Import`s.
let mut imports = Vec::new();
let tree = self.tree.data_mut();
ModPath::expand_use_item(
InFile::new(self.file, use_item.clone()),
&self.hygiene,
|path, _tree, is_glob, alias| {
imports.push(id(tree.imports.alloc(Import {
path,
alias,
visibility,
is_glob,
is_prelude,
ast_id,
})));
},
);
imports
}
fn lower_extern_crate(
&mut self,
extern_crate: &ast::ExternCrateItem,
) -> Option<FileItemTreeId<ExternCrate>> {
let path = ModPath::from_name_ref(&extern_crate.name_ref()?);
let alias = extern_crate.alias().map(|a| {
a.name().map(|it| it.as_name()).map_or(ImportAlias::Underscore, ImportAlias::Alias)
});
let visibility = self.lower_visibility(extern_crate);
let ast_id = self.source_ast_id_map.ast_id(extern_crate);
// FIXME: cfg_attr
let is_macro_use = extern_crate.has_atom_attr("macro_use");
let res = ExternCrate { path, alias, visibility, is_macro_use, ast_id };
Some(id(self.data().extern_crates.alloc(res)))
}
fn lower_macro_call(&mut self, m: &ast::MacroCall) -> Option<FileItemTreeId<MacroCall>> {
let name = m.name().map(|it| it.as_name());
let attrs = Attrs::new(m, &self.hygiene);
let path = ModPath::from_src(m.path()?, &self.hygiene)?;
let ast_id = self.source_ast_id_map.ast_id(m);
// FIXME: cfg_attr
let export_attr = attrs.by_key("macro_export");
let is_export = export_attr.exists();
let is_local_inner = if is_export {
export_attr.tt_values().map(|it| &it.token_trees).flatten().any(|it| match it {
tt::TokenTree::Leaf(tt::Leaf::Ident(ident)) => {
ident.text.contains("local_inner_macros")
}
_ => false,
})
} else {
false
};
let is_builtin = attrs.by_key("rustc_builtin_macro").exists();
let res = MacroCall { name, path, is_export, is_builtin, is_local_inner, ast_id };
Some(id(self.data().macro_calls.alloc(res)))
}
fn lower_extern_block(&mut self, block: &ast::ExternBlock) -> Vec<ModItem> {
block.extern_item_list().map_or(Vec::new(), |list| {
list.extern_items()
.filter_map(|item| {
self.collect_inner_items(item.syntax());
let attrs = Attrs::new(&item, &self.hygiene);
let id: ModItem = match item {
ast::ExternItem::FnDef(ast) => {
let func = self.lower_function(&ast)?;
self.data().functions[func.index].is_unsafe = true;
func.into()
}
ast::ExternItem::StaticDef(ast) => {
let statik = self.lower_static(&ast)?;
statik.into()
}
};
self.add_attrs(id.into(), attrs);
Some(id)
})
.collect()
})
}
/// Lowers generics defined on `node` and collects inner items defined within.
fn lower_generic_params_and_inner_items(
&mut self,
owner: GenericsOwner<'_>,
node: &impl ast::TypeParamsOwner,
) -> GenericParamsId {
// Generics are part of item headers and may contain inner items we need to collect.
if let Some(params) = node.type_param_list() {
self.collect_inner_items(params.syntax());
}
if let Some(clause) = node.where_clause() {
self.collect_inner_items(clause.syntax());
}
self.lower_generic_params(owner, node)
}
fn lower_generic_params(
&mut self,
owner: GenericsOwner<'_>,
node: &impl ast::TypeParamsOwner,
) -> GenericParamsId {
let mut sm = &mut ArenaMap::default();
let mut generics = GenericParams::default();
match owner {
GenericsOwner::Function(func) => {
generics.fill(&self.body_ctx, sm, node);
// lower `impl Trait` in arguments
for param in &*func.params {
generics.fill_implicit_impl_trait_args(param);
}
}
GenericsOwner::Struct
| GenericsOwner::Enum
| GenericsOwner::Union
| GenericsOwner::TypeAlias => {
generics.fill(&self.body_ctx, sm, node);
}
GenericsOwner::Trait(trait_def) => {
// traits get the Self type as an implicit first type parameter
let self_param_id = generics.types.alloc(TypeParamData {
name: Some(name![Self]),
default: None,
provenance: TypeParamProvenance::TraitSelf,
});
sm.insert(self_param_id, Either::Left(trait_def.clone()));
// add super traits as bounds on Self
// i.e., trait Foo: Bar is equivalent to trait Foo where Self: Bar
let self_param = TypeRef::Path(name![Self].into());
generics.fill_bounds(&self.body_ctx, trait_def, self_param);
generics.fill(&self.body_ctx, &mut sm, node);
}
GenericsOwner::Impl => {
// Note that we don't add `Self` here: in `impl`s, `Self` is not a
// type-parameter, but rather is a type-alias for impl's target
// type, so this is handled by the resolver.
generics.fill(&self.body_ctx, &mut sm, node);
}
}
self.data().generics.alloc(generics)
}
fn lower_type_bounds(&mut self, node: &impl ast::TypeBoundsOwner) -> Vec<TypeBound> {
match node.type_bound_list() {
Some(bound_list) => {
bound_list.bounds().map(|it| TypeBound::from_ast(&self.body_ctx, it)).collect()
}
None => Vec::new(),
}
}
fn lower_visibility(&mut self, item: &impl ast::VisibilityOwner) -> RawVisibilityId {
let vis = match self.forced_visibility {
Some(vis) => return vis,
None => RawVisibility::from_ast_with_hygiene(item.visibility(), &self.hygiene),
};
self.data().vis.alloc(vis)
}
fn lower_type_ref(&self, type_ref: &ast::TypeRef) -> TypeRef {
TypeRef::from_ast(&self.body_ctx, type_ref.clone())
}
fn lower_type_ref_opt(&self, type_ref: Option<ast::TypeRef>) -> TypeRef {
type_ref.map(|ty| self.lower_type_ref(&ty)).unwrap_or(TypeRef::Error)
}
/// Forces the visibility `vis` to be used for all items lowered during execution of `f`.
fn with_inherited_visibility<R>(
&mut self,
vis: RawVisibilityId,
f: impl FnOnce(&mut Self) -> R,
) -> R {
let old = mem::replace(&mut self.forced_visibility, Some(vis));
let res = f(self);
self.forced_visibility = old;
res
}
fn next_field_idx(&self) -> Idx<Field> {
Idx::from_raw(RawId::from(
self.tree.data.as_ref().map_or(0, |data| data.fields.len() as u32),
))
}
fn next_variant_idx(&self) -> Idx<Variant> {
Idx::from_raw(RawId::from(
self.tree.data.as_ref().map_or(0, |data| data.variants.len() as u32),
))
}
}
fn desugar_future_path(orig: TypeRef) -> Path {
let path = path![core::future::Future];
let mut generic_args: Vec<_> = std::iter::repeat(None).take(path.segments.len() - 1).collect();
let mut last = GenericArgs::empty();
let binding =
AssociatedTypeBinding { name: name![Output], type_ref: Some(orig), bounds: Vec::new() };
last.bindings.push(binding);
generic_args.push(Some(Arc::new(last)));
Path::from_known_path(path, generic_args)
}
enum GenericsOwner<'a> {
/// We need access to the partially-lowered `Function` for lowering `impl Trait` in argument
/// position.
Function(&'a Function),
Struct,
Enum,
Union,
/// The `TraitDef` is needed to fill the source map for the implicit `Self` parameter.
Trait(&'a ast::TraitDef),
TypeAlias,
Impl,
}