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android / toolchain / rustc / refs/heads/main / . / src / tools / rust-analyzer / crates / ide-db / src / imports / import_assets.rs
blob: c597555a3bf661c037d7a3688b23621cff1e415f [file] [log] [blame]
//! Look up accessible paths for items.
use hir::{
db::HirDatabase, AsAssocItem, AssocItem, AssocItemContainer, Crate, HasCrate, ItemInNs,
ModPath, Module, ModuleDef, Name, PathResolution, PrefixKind, ScopeDef, Semantics,
SemanticsScope, Trait, Type,
};
use itertools::{EitherOrBoth, Itertools};
use rustc_hash::{FxHashMap, FxHashSet};
use syntax::{
ast::{self, make, HasName},
AstNode, SmolStr, SyntaxNode,
};
use crate::{
helpers::item_name,
items_locator::{self, AssocSearchMode, DEFAULT_QUERY_SEARCH_LIMIT},
RootDatabase,
};
/// A candidate for import, derived during various IDE activities:
/// * completion with imports on the fly proposals
/// * completion edit resolve requests
/// * assists
/// * etc.
#[derive(Debug)]
pub enum ImportCandidate {
/// A path, qualified (`std::collections::HashMap`) or not (`HashMap`).
Path(PathImportCandidate),
/// A trait associated function (with no self parameter) or an associated constant.
/// For 'test_mod::TestEnum::test_function', `ty` is the `test_mod::TestEnum` expression type
/// and `name` is the `test_function`
TraitAssocItem(TraitImportCandidate),
/// A trait method with self parameter.
/// For 'test_enum.test_method()', `ty` is the `test_enum` expression type
/// and `name` is the `test_method`
TraitMethod(TraitImportCandidate),
}
/// A trait import needed for a given associated item access.
/// For `some::path::SomeStruct::ASSOC_`, contains the
/// type of `some::path::SomeStruct` and `ASSOC_` as the item name.
#[derive(Debug)]
pub struct TraitImportCandidate {
/// A type of the item that has the associated item accessed at.
pub receiver_ty: Type,
/// The associated item name that the trait to import should contain.
pub assoc_item_name: NameToImport,
}
/// Path import for a given name, qualified or not.
#[derive(Debug)]
pub struct PathImportCandidate {
/// Optional qualifier before name.
pub qualifier: Option<Vec<SmolStr>>,
/// The name the item (struct, trait, enum, etc.) should have.
pub name: NameToImport,
}
/// A name that will be used during item lookups.
#[derive(Debug, Clone)]
pub enum NameToImport {
/// Requires items with names that exactly match the given string, bool indicates case-sensitivity.
Exact(String, bool),
/// Requires items with names that match the given string by prefix, bool indicates case-sensitivity.
Prefix(String, bool),
/// Requires items with names contain all letters from the string,
/// in the same order, but not necessary adjacent.
Fuzzy(String, bool),
}
impl NameToImport {
pub fn exact_case_sensitive(s: String) -> NameToImport {
NameToImport::Exact(s, true)
}
pub fn fuzzy(s: String) -> NameToImport {
// unless all chars are lowercase, we do a case sensitive search
let case_sensitive = s.chars().any(|c| c.is_uppercase());
NameToImport::Fuzzy(s, case_sensitive)
}
pub fn text(&self) -> &str {
match self {
NameToImport::Prefix(text, _)
| NameToImport::Exact(text, _)
| NameToImport::Fuzzy(text, _) => text.as_str(),
}
}
}
/// A struct to find imports in the project, given a certain name (or its part) and the context.
#[derive(Debug)]
pub struct ImportAssets {
import_candidate: ImportCandidate,
candidate_node: SyntaxNode,
module_with_candidate: Module,
}
impl ImportAssets {
pub fn for_method_call(
method_call: &ast::MethodCallExpr,
sema: &Semantics<'_, RootDatabase>,
) -> Option<Self> {
let candidate_node = method_call.syntax().clone();
Some(Self {
import_candidate: ImportCandidate::for_method_call(sema, method_call)?,
module_with_candidate: sema.scope(&candidate_node)?.module(),
candidate_node,
})
}
pub fn for_exact_path(
fully_qualified_path: &ast::Path,
sema: &Semantics<'_, RootDatabase>,
) -> Option<Self> {
let candidate_node = fully_qualified_path.syntax().clone();
if let Some(use_tree) = candidate_node.ancestors().find_map(ast::UseTree::cast) {
// Path is inside a use tree, then only continue if it is the first segment of a use statement.
if use_tree.syntax().parent().and_then(ast::Use::cast).is_none()
|| fully_qualified_path.qualifier().is_some()
{
return None;
}
}
Some(Self {
import_candidate: ImportCandidate::for_regular_path(sema, fully_qualified_path)?,
module_with_candidate: sema.scope(&candidate_node)?.module(),
candidate_node,
})
}
pub fn for_ident_pat(sema: &Semantics<'_, RootDatabase>, pat: &ast::IdentPat) -> Option<Self> {
if !pat.is_simple_ident() {
return None;
}
let name = pat.name()?;
let candidate_node = pat.syntax().clone();
Some(Self {
import_candidate: ImportCandidate::for_name(sema, &name)?,
module_with_candidate: sema.scope(&candidate_node)?.module(),
candidate_node,
})
}
pub fn for_fuzzy_path(
module_with_candidate: Module,
qualifier: Option<ast::Path>,
fuzzy_name: String,
sema: &Semantics<'_, RootDatabase>,
candidate_node: SyntaxNode,
) -> Option<Self> {
Some(Self {
import_candidate: ImportCandidate::for_fuzzy_path(qualifier, fuzzy_name, sema)?,
module_with_candidate,
candidate_node,
})
}
pub fn for_fuzzy_method_call(
module_with_method_call: Module,
receiver_ty: Type,
fuzzy_method_name: String,
candidate_node: SyntaxNode,
) -> Option<Self> {
Some(Self {
import_candidate: ImportCandidate::TraitMethod(TraitImportCandidate {
receiver_ty,
assoc_item_name: NameToImport::fuzzy(fuzzy_method_name),
}),
module_with_candidate: module_with_method_call,
candidate_node,
})
}
}
/// An import (not necessary the only one) that corresponds a certain given [`PathImportCandidate`].
/// (the structure is not entirely correct, since there can be situations requiring two imports, see FIXME below for the details)
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub struct LocatedImport {
/// The path to use in the `use` statement for a given candidate to be imported.
pub import_path: ModPath,
/// An item that will be imported with the import path given.
pub item_to_import: ItemInNs,
/// The path import candidate, resolved.
///
/// Not necessary matches the import:
/// For any associated constant from the trait, we try to access as `some::path::SomeStruct::ASSOC_`
/// the original item is the associated constant, but the import has to be a trait that
/// defines this constant.
pub original_item: ItemInNs,
}
impl LocatedImport {
pub fn new(import_path: ModPath, item_to_import: ItemInNs, original_item: ItemInNs) -> Self {
Self { import_path, item_to_import, original_item }
}
}
impl ImportAssets {
pub fn import_candidate(&self) -> &ImportCandidate {
&self.import_candidate
}
pub fn search_for_imports(
&self,
sema: &Semantics<'_, RootDatabase>,
prefix_kind: PrefixKind,
prefer_no_std: bool,
prefer_prelude: bool,
) -> impl Iterator<Item = LocatedImport> {
let _p =
tracing::span!(tracing::Level::INFO, "import_assets::search_for_imports").entered();
self.search_for(sema, Some(prefix_kind), prefer_no_std, prefer_prelude)
}
/// This may return non-absolute paths if a part of the returned path is already imported into scope.
pub fn search_for_relative_paths(
&self,
sema: &Semantics<'_, RootDatabase>,
prefer_no_std: bool,
prefer_prelude: bool,
) -> impl Iterator<Item = LocatedImport> {
let _p = tracing::span!(tracing::Level::INFO, "import_assets::search_for_relative_paths")
.entered();
self.search_for(sema, None, prefer_no_std, prefer_prelude)
}
/// Requires imports to by prefix instead of fuzzily.
pub fn path_fuzzy_name_to_prefix(&mut self) {
if let ImportCandidate::Path(PathImportCandidate { name: to_import, .. }) =
&mut self.import_candidate
{
let (name, case_sensitive) = match to_import {
NameToImport::Fuzzy(name, case_sensitive) => {
(std::mem::take(name), *case_sensitive)
}
_ => return,
};
*to_import = NameToImport::Prefix(name, case_sensitive);
}
}
/// Requires imports to match exactly instead of fuzzily.
pub fn path_fuzzy_name_to_exact(&mut self) {
if let ImportCandidate::Path(PathImportCandidate { name: to_import, .. }) =
&mut self.import_candidate
{
let (name, case_sensitive) = match to_import {
NameToImport::Fuzzy(name, case_sensitive) => {
(std::mem::take(name), *case_sensitive)
}
_ => return,
};
*to_import = NameToImport::Exact(name, case_sensitive);
}
}
fn search_for(
&self,
sema: &Semantics<'_, RootDatabase>,
prefixed: Option<PrefixKind>,
prefer_no_std: bool,
prefer_prelude: bool,
) -> impl Iterator<Item = LocatedImport> {
let _p = tracing::span!(tracing::Level::INFO, "import_assets::search_for").entered();
let scope = match sema.scope(&self.candidate_node) {
Some(it) => it,
None => return <FxHashSet<_>>::default().into_iter(),
};
let krate = self.module_with_candidate.krate();
let scope_definitions = self.scope_definitions(sema);
let mod_path = |item| {
get_mod_path(
sema.db,
item_for_path_search(sema.db, item)?,
&self.module_with_candidate,
prefixed,
prefer_no_std,
prefer_prelude,
)
.filter(|path| path.len() > 1)
};
match &self.import_candidate {
ImportCandidate::Path(path_candidate) => {
path_applicable_imports(sema, krate, path_candidate, mod_path, |item_to_import| {
!scope_definitions.contains(&ScopeDef::from(item_to_import))
})
}
ImportCandidate::TraitAssocItem(trait_candidate)
| ImportCandidate::TraitMethod(trait_candidate) => trait_applicable_items(
sema,
krate,
&scope,
trait_candidate,
matches!(self.import_candidate, ImportCandidate::TraitAssocItem(_)),
mod_path,
|trait_to_import| {
!scope_definitions
.contains(&ScopeDef::ModuleDef(ModuleDef::Trait(trait_to_import)))
},
),
}
.into_iter()
}
fn scope_definitions(&self, sema: &Semantics<'_, RootDatabase>) -> FxHashSet<ScopeDef> {
let _p = tracing::span!(tracing::Level::INFO, "import_assets::scope_definitions").entered();
let mut scope_definitions = FxHashSet::default();
if let Some(scope) = sema.scope(&self.candidate_node) {
scope.process_all_names(&mut |_, scope_def| {
scope_definitions.insert(scope_def);
});
}
scope_definitions
}
}
fn path_applicable_imports(
sema: &Semantics<'_, RootDatabase>,
current_crate: Crate,
path_candidate: &PathImportCandidate,
mod_path: impl Fn(ItemInNs) -> Option<ModPath> + Copy,
scope_filter: impl Fn(ItemInNs) -> bool + Copy,
) -> FxHashSet<LocatedImport> {
let _p =
tracing::span!(tracing::Level::INFO, "import_assets::path_applicable_imports").entered();
match &path_candidate.qualifier {
None => {
items_locator::items_with_name(
sema,
current_crate,
path_candidate.name.clone(),
// FIXME: we could look up assoc items by the input and propose those in completion,
// but that requires more preparation first:
// * store non-trait assoc items in import_map to fully enable this lookup
// * ensure that does not degrade the performance (benchmark it)
// * write more logic to check for corresponding trait presence requirement (we're unable to flyimport multiple item right now)
// * improve the associated completion item matching and/or scoring to ensure no noisy completions appear
//
// see also an ignored test under FIXME comment in the qualify_path.rs module
AssocSearchMode::Exclude,
)
.filter_map(|item| {
if !scope_filter(item) {
return None;
}
let mod_path = mod_path(item)?;
Some(LocatedImport::new(mod_path, item, item))
})
.take(DEFAULT_QUERY_SEARCH_LIMIT.inner())
.collect()
}
Some(qualifier) => items_locator::items_with_name(
sema,
current_crate,
path_candidate.name.clone(),
AssocSearchMode::Include,
)
.filter_map(|item| import_for_item(sema.db, mod_path, qualifier, item, scope_filter))
.take(DEFAULT_QUERY_SEARCH_LIMIT.inner())
.collect(),
}
}
fn import_for_item(
db: &RootDatabase,
mod_path: impl Fn(ItemInNs) -> Option<ModPath>,
unresolved_qualifier: &[SmolStr],
original_item: ItemInNs,
scope_filter: impl Fn(ItemInNs) -> bool,
) -> Option<LocatedImport> {
let _p = tracing::span!(tracing::Level::INFO, "import_assets::import_for_item").entered();
let [first_segment, ..] = unresolved_qualifier else { return None };
let item_as_assoc = item_as_assoc(db, original_item);
let (original_item_candidate, trait_item_to_import) = match item_as_assoc {
Some(assoc_item) => match assoc_item.container(db) {
AssocItemContainer::Trait(trait_) => {
let trait_ = ItemInNs::from(ModuleDef::from(trait_));
(trait_, Some(trait_))
}
AssocItemContainer::Impl(impl_) => {
(ItemInNs::from(ModuleDef::from(impl_.self_ty(db).as_adt()?)), None)
}
},
None => (original_item, None),
};
let import_path_candidate = mod_path(original_item_candidate)?;
let mut import_path_candidate_segments = import_path_candidate.segments().iter().rev();
let predicate = |it: EitherOrBoth<&SmolStr, &Name>| match it {
// segments match, check next one
EitherOrBoth::Both(a, b) if b.as_str() == Some(&**a) => None,
// segments mismatch / qualifier is longer than the path, bail out
EitherOrBoth::Both(..) | EitherOrBoth::Left(_) => Some(false),
// all segments match and we have exhausted the qualifier, proceed
EitherOrBoth::Right(_) => Some(true),
};
if item_as_assoc.is_none() {
let item_name = item_name(db, original_item)?.as_text()?;
let last_segment = import_path_candidate_segments.next()?;
if last_segment.as_str() != Some(&*item_name) {
return None;
}
}
let ends_with = unresolved_qualifier
.iter()
.rev()
.zip_longest(import_path_candidate_segments)
.find_map(predicate)
.unwrap_or(true);
if !ends_with {
return None;
}
let segment_import = find_import_for_segment(db, original_item_candidate, first_segment)?;
Some(match (segment_import == original_item_candidate, trait_item_to_import) {
(true, Some(_)) => {
// FIXME we should be able to import both the trait and the segment,
// but it's unclear what to do with overlapping edits (merge imports?)
// especially in case of lazy completion edit resolutions.
return None;
}
(false, Some(trait_to_import)) if scope_filter(trait_to_import) => {
LocatedImport::new(mod_path(trait_to_import)?, trait_to_import, original_item)
}
(true, None) if scope_filter(original_item_candidate) => {
LocatedImport::new(import_path_candidate, original_item_candidate, original_item)
}
(false, None) if scope_filter(segment_import) => {
LocatedImport::new(mod_path(segment_import)?, segment_import, original_item)
}
_ => return None,
})
}
pub fn item_for_path_search(db: &RootDatabase, item: ItemInNs) -> Option<ItemInNs> {
Some(match item {
ItemInNs::Types(_) | ItemInNs::Values(_) => match item_as_assoc(db, item) {
Some(assoc_item) => item_for_path_search_assoc(db, assoc_item)?,
None => item,
},
ItemInNs::Macros(_) => item,
})
}
fn item_for_path_search_assoc(db: &RootDatabase, assoc_item: AssocItem) -> Option<ItemInNs> {
Some(match assoc_item.container(db) {
AssocItemContainer::Trait(trait_) => ItemInNs::from(ModuleDef::from(trait_)),
AssocItemContainer::Impl(impl_) => {
ItemInNs::from(ModuleDef::from(impl_.self_ty(db).as_adt()?))
}
})
}
fn find_import_for_segment(
db: &RootDatabase,
original_item: ItemInNs,
unresolved_first_segment: &str,
) -> Option<ItemInNs> {
let segment_is_name = item_name(db, original_item)
.map(|name| name.to_smol_str() == unresolved_first_segment)
.unwrap_or(false);
Some(if segment_is_name {
original_item
} else {
let matching_module =
module_with_segment_name(db, unresolved_first_segment, original_item)?;
ItemInNs::from(ModuleDef::from(matching_module))
})
}
fn module_with_segment_name(
db: &RootDatabase,
segment_name: &str,
candidate: ItemInNs,
) -> Option<Module> {
let mut current_module = match candidate {
ItemInNs::Types(module_def_id) => module_def_id.module(db),
ItemInNs::Values(module_def_id) => module_def_id.module(db),
ItemInNs::Macros(macro_def_id) => ModuleDef::from(macro_def_id).module(db),
};
while let Some(module) = current_module {
if let Some(module_name) = module.name(db) {
if module_name.to_smol_str() == segment_name {
return Some(module);
}
}
current_module = module.parent(db);
}
None
}
fn trait_applicable_items(
sema: &Semantics<'_, RootDatabase>,
current_crate: Crate,
scope: &SemanticsScope<'_>,
trait_candidate: &TraitImportCandidate,
trait_assoc_item: bool,
mod_path: impl Fn(ItemInNs) -> Option<ModPath>,
scope_filter: impl Fn(hir::Trait) -> bool,
) -> FxHashSet<LocatedImport> {
let _p =
tracing::span!(tracing::Level::INFO, "import_assets::trait_applicable_items").entered();
let db = sema.db;
let inherent_traits = trait_candidate.receiver_ty.applicable_inherent_traits(db);
let env_traits = trait_candidate.receiver_ty.env_traits(db);
let related_traits = inherent_traits.chain(env_traits).collect::<FxHashSet<_>>();
let mut required_assoc_items = FxHashSet::default();
let mut trait_candidates: FxHashSet<_> = items_locator::items_with_name(
sema,
current_crate,
trait_candidate.assoc_item_name.clone(),
AssocSearchMode::AssocItemsOnly,
)
.filter_map(|input| item_as_assoc(db, input))
.filter_map(|assoc| {
if !trait_assoc_item && matches!(assoc, AssocItem::Const(_) | AssocItem::TypeAlias(_)) {
return None;
}
let assoc_item_trait = assoc.container_trait(db)?;
if related_traits.contains(&assoc_item_trait) {
return None;
}
required_assoc_items.insert(assoc);
Some(assoc_item_trait.into())
})
.collect();
trait_candidates.retain(|&candidate_trait_id| {
// we care about the following cases:
// 1. Trait's definition crate
// 2. Definition crates for all trait's generic arguments
// a. This is recursive for fundamental types: `Into<Box<A>> for ()`` is OK, but
// `Into<Vec<A>> for ()`` is *not*.
// 3. Receiver type definition crate
// a. This is recursive for fundamental types
let defining_crate_for_trait = Trait::from(candidate_trait_id).krate(db);
let Some(receiver) = trait_candidate.receiver_ty.fingerprint_for_trait_impl() else {
return false;
};
let definitions_exist_in_trait_crate = db
.trait_impls_in_crate(defining_crate_for_trait.into())
.has_impls_for_trait_and_self_ty(candidate_trait_id, receiver);
// this is a closure for laziness: if `definitions_exist_in_trait_crate` is true,
// we can avoid a second db lookup.
let definitions_exist_in_receiver_crate = || {
db.trait_impls_in_crate(trait_candidate.receiver_ty.krate(db).into())
.has_impls_for_trait_and_self_ty(candidate_trait_id, receiver)
};
definitions_exist_in_trait_crate || definitions_exist_in_receiver_crate()
});
let mut located_imports = FxHashSet::default();
let mut trait_import_paths = FxHashMap::default();
if trait_assoc_item {
trait_candidate.receiver_ty.iterate_path_candidates(
db,
scope,
&trait_candidates,
None,
None,
|assoc| {
if required_assoc_items.contains(&assoc) {
let located_trait = assoc.container_trait(db).filter(|&it| scope_filter(it))?;
let trait_item = ItemInNs::from(ModuleDef::from(located_trait));
let import_path = trait_import_paths
.entry(trait_item)
.or_insert_with(|| mod_path(trait_item))
.clone()?;
located_imports.insert(LocatedImport::new(
import_path,
trait_item,
assoc_to_item(assoc),
));
}
None::<()>
},
)
} else {
trait_candidate.receiver_ty.iterate_method_candidates_with_traits(
db,
scope,
&trait_candidates,
None,
None,
|function| {
let assoc = function.as_assoc_item(db)?;
if required_assoc_items.contains(&assoc) {
let located_trait = assoc.container_trait(db).filter(|&it| scope_filter(it))?;
let trait_item = ItemInNs::from(ModuleDef::from(located_trait));
let import_path = trait_import_paths
.entry(trait_item)
.or_insert_with(|| mod_path(trait_item))
.clone()?;
located_imports.insert(LocatedImport::new(
import_path,
trait_item,
assoc_to_item(assoc),
));
}
None::<()>
},
)
};
located_imports
}
fn assoc_to_item(assoc: AssocItem) -> ItemInNs {
match assoc {
AssocItem::Function(f) => ItemInNs::from(ModuleDef::from(f)),
AssocItem::Const(c) => ItemInNs::from(ModuleDef::from(c)),
AssocItem::TypeAlias(t) => ItemInNs::from(ModuleDef::from(t)),
}
}
#[tracing::instrument(skip_all)]
fn get_mod_path(
db: &RootDatabase,
item_to_search: ItemInNs,
module_with_candidate: &Module,
prefixed: Option<PrefixKind>,
prefer_no_std: bool,
prefer_prelude: bool,
) -> Option<ModPath> {
if let Some(prefix_kind) = prefixed {
module_with_candidate.find_use_path_prefixed(
db,
item_to_search,
prefix_kind,
prefer_no_std,
prefer_prelude,
)
} else {
module_with_candidate.find_use_path(db, item_to_search, prefer_no_std, prefer_prelude)
}
}
impl ImportCandidate {
fn for_method_call(
sema: &Semantics<'_, RootDatabase>,
method_call: &ast::MethodCallExpr,
) -> Option<Self> {
match sema.resolve_method_call(method_call) {
Some(_) => None,
None => Some(Self::TraitMethod(TraitImportCandidate {
receiver_ty: sema.type_of_expr(&method_call.receiver()?)?.adjusted(),
assoc_item_name: NameToImport::exact_case_sensitive(
method_call.name_ref()?.to_string(),
),
})),
}
}
fn for_regular_path(sema: &Semantics<'_, RootDatabase>, path: &ast::Path) -> Option<Self> {
if sema.resolve_path(path).is_some() {
return None;
}
path_import_candidate(
sema,
path.qualifier(),
NameToImport::exact_case_sensitive(path.segment()?.name_ref()?.to_string()),
)
}
fn for_name(sema: &Semantics<'_, RootDatabase>, name: &ast::Name) -> Option<Self> {
if sema
.scope(name.syntax())?
.speculative_resolve(&make::ext::ident_path(&name.text()))
.is_some()
{
return None;
}
Some(ImportCandidate::Path(PathImportCandidate {
qualifier: None,
name: NameToImport::exact_case_sensitive(name.to_string()),
}))
}
fn for_fuzzy_path(
qualifier: Option<ast::Path>,
fuzzy_name: String,
sema: &Semantics<'_, RootDatabase>,
) -> Option<Self> {
path_import_candidate(sema, qualifier, NameToImport::fuzzy(fuzzy_name))
}
}
fn path_import_candidate(
sema: &Semantics<'_, RootDatabase>,
qualifier: Option<ast::Path>,
name: NameToImport,
) -> Option<ImportCandidate> {
Some(match qualifier {
Some(qualifier) => match sema.resolve_path(&qualifier) {
None => {
if qualifier.first_qualifier().map_or(true, |it| sema.resolve_path(&it).is_none()) {
let qualifier = qualifier
.segments()
.map(|seg| seg.name_ref().map(|name| SmolStr::new(name.text())))
.collect::<Option<Vec<_>>>()?;
ImportCandidate::Path(PathImportCandidate { qualifier: Some(qualifier), name })
} else {
return None;
}
}
Some(PathResolution::Def(ModuleDef::Adt(assoc_item_path))) => {
ImportCandidate::TraitAssocItem(TraitImportCandidate {
receiver_ty: assoc_item_path.ty(sema.db),
assoc_item_name: name,
})
}
Some(PathResolution::Def(ModuleDef::TypeAlias(alias))) => {
let ty = alias.ty(sema.db);
if ty.as_adt().is_some() {
ImportCandidate::TraitAssocItem(TraitImportCandidate {
receiver_ty: ty,
assoc_item_name: name,
})
} else {
return None;
}
}
Some(_) => return None,
},
None => ImportCandidate::Path(PathImportCandidate { qualifier: None, name }),
})
}
fn item_as_assoc(db: &RootDatabase, item: ItemInNs) -> Option<AssocItem> {
item.as_module_def().and_then(|module_def| module_def.as_assoc_item(db))
}