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android / toolchain / rustc / b1d328019a485dc2e58d5dc46556067c927ec9f2 / . / src / tools / rust-analyzer / crates / ide-db / src / search.rs
blob: bd038cdaa068261e3738849a930ff0ec59c74e91 [file] [log] [blame]
//! Implementation of find-usages functionality.
//!
//! It is based on the standard ide trick: first, we run a fast text search to
//! get a super-set of matches. Then, we we confirm each match using precise
//! name resolution.
use std::{convert::TryInto, mem, sync::Arc};
use base_db::{FileId, FileRange, SourceDatabase, SourceDatabaseExt};
use hir::{DefWithBody, HasAttrs, HasSource, InFile, ModuleSource, Semantics, Visibility};
use once_cell::unsync::Lazy;
use rustc_hash::FxHashMap;
use syntax::{ast, match_ast, AstNode, TextRange, TextSize};
use crate::{
defs::{Definition, NameClass, NameRefClass},
traits::{as_trait_assoc_def, convert_to_def_in_trait},
RootDatabase,
};
#[derive(Debug, Default, Clone)]
pub struct UsageSearchResult {
pub references: FxHashMap<FileId, Vec<FileReference>>,
}
impl UsageSearchResult {
pub fn is_empty(&self) -> bool {
self.references.is_empty()
}
pub fn len(&self) -> usize {
self.references.len()
}
pub fn iter(&self) -> impl Iterator<Item = (&FileId, &[FileReference])> + '_ {
self.references.iter().map(|(file_id, refs)| (file_id, &**refs))
}
pub fn file_ranges(&self) -> impl Iterator<Item = FileRange> + '_ {
self.references.iter().flat_map(|(&file_id, refs)| {
refs.iter().map(move |&FileReference { range, .. }| FileRange { file_id, range })
})
}
}
impl IntoIterator for UsageSearchResult {
type Item = (FileId, Vec<FileReference>);
type IntoIter = <FxHashMap<FileId, Vec<FileReference>> as IntoIterator>::IntoIter;
fn into_iter(self) -> Self::IntoIter {
self.references.into_iter()
}
}
#[derive(Debug, Clone)]
pub struct FileReference {
/// The range of the reference in the original file
pub range: TextRange,
/// The node of the reference in the (macro-)file
pub name: ast::NameLike,
pub category: Option<ReferenceCategory>,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub enum ReferenceCategory {
// FIXME: Add this variant and delete the `retain_adt_literal_usages` function.
// Create
Write,
Read,
// FIXME: Some day should be able to search in doc comments. Would probably
// need to switch from enum to bitflags then?
// DocComment
}
/// Generally, `search_scope` returns files that might contain references for the element.
/// For `pub(crate)` things it's a crate, for `pub` things it's a crate and dependant crates.
/// In some cases, the location of the references is known to within a `TextRange`,
/// e.g. for things like local variables.
#[derive(Clone, Debug)]
pub struct SearchScope {
entries: FxHashMap<FileId, Option<TextRange>>,
}
impl SearchScope {
fn new(entries: FxHashMap<FileId, Option<TextRange>>) -> SearchScope {
SearchScope { entries }
}
/// Build a search scope spanning the entire crate graph of files.
fn crate_graph(db: &RootDatabase) -> SearchScope {
let mut entries = FxHashMap::default();
let graph = db.crate_graph();
for krate in graph.iter() {
let root_file = graph[krate].root_file_id;
let source_root_id = db.file_source_root(root_file);
let source_root = db.source_root(source_root_id);
entries.extend(source_root.iter().map(|id| (id, None)));
}
SearchScope { entries }
}
/// Build a search scope spanning all the reverse dependencies of the given crate.
fn reverse_dependencies(db: &RootDatabase, of: hir::Crate) -> SearchScope {
let mut entries = FxHashMap::default();
for rev_dep in of.transitive_reverse_dependencies(db) {
let root_file = rev_dep.root_file(db);
let source_root_id = db.file_source_root(root_file);
let source_root = db.source_root(source_root_id);
entries.extend(source_root.iter().map(|id| (id, None)));
}
SearchScope { entries }
}
/// Build a search scope spanning the given crate.
fn krate(db: &RootDatabase, of: hir::Crate) -> SearchScope {
let root_file = of.root_file(db);
let source_root_id = db.file_source_root(root_file);
let source_root = db.source_root(source_root_id);
SearchScope {
entries: source_root.iter().map(|id| (id, None)).collect::<FxHashMap<_, _>>(),
}
}
/// Build a search scope spanning the given module and all its submodules.
fn module_and_children(db: &RootDatabase, module: hir::Module) -> SearchScope {
let mut entries = FxHashMap::default();
let (file_id, range) = {
let InFile { file_id, value } = module.definition_source(db);
if let Some((file_id, call_source)) = file_id.original_call_node(db) {
(file_id, Some(call_source.text_range()))
} else {
(
file_id.original_file(db),
match value {
ModuleSource::SourceFile(_) => None,
ModuleSource::Module(it) => Some(it.syntax().text_range()),
ModuleSource::BlockExpr(it) => Some(it.syntax().text_range()),
},
)
}
};
entries.insert(file_id, range);
let mut to_visit: Vec<_> = module.children(db).collect();
while let Some(module) = to_visit.pop() {
if let InFile { file_id, value: ModuleSource::SourceFile(_) } =
module.definition_source(db)
{
entries.insert(file_id.original_file(db), None);
}
to_visit.extend(module.children(db));
}
SearchScope { entries }
}
/// Build an empty search scope.
pub fn empty() -> SearchScope {
SearchScope::new(FxHashMap::default())
}
/// Build a empty search scope spanning the given file.
pub fn single_file(file: FileId) -> SearchScope {
SearchScope::new(std::iter::once((file, None)).collect())
}
/// Build a empty search scope spanning the text range of the given file.
pub fn file_range(range: FileRange) -> SearchScope {
SearchScope::new(std::iter::once((range.file_id, Some(range.range))).collect())
}
/// Build a empty search scope spanning the given files.
pub fn files(files: &[FileId]) -> SearchScope {
SearchScope::new(files.iter().map(|f| (*f, None)).collect())
}
pub fn intersection(&self, other: &SearchScope) -> SearchScope {
let (mut small, mut large) = (&self.entries, &other.entries);
if small.len() > large.len() {
mem::swap(&mut small, &mut large)
}
let intersect_ranges =
|r1: Option<TextRange>, r2: Option<TextRange>| -> Option<Option<TextRange>> {
match (r1, r2) {
(None, r) | (r, None) => Some(r),
(Some(r1), Some(r2)) => r1.intersect(r2).map(Some),
}
};
let res = small
.iter()
.filter_map(|(&file_id, &r1)| {
let &r2 = large.get(&file_id)?;
let r = intersect_ranges(r1, r2)?;
Some((file_id, r))
})
.collect();
SearchScope::new(res)
}
}
impl IntoIterator for SearchScope {
type Item = (FileId, Option<TextRange>);
type IntoIter = std::collections::hash_map::IntoIter<FileId, Option<TextRange>>;
fn into_iter(self) -> Self::IntoIter {
self.entries.into_iter()
}
}
impl Definition {
fn search_scope(&self, db: &RootDatabase) -> SearchScope {
let _p = profile::span("search_scope");
if let Definition::BuiltinType(_) = self {
return SearchScope::crate_graph(db);
}
// def is crate root
// FIXME: We don't do searches for crates currently, as a crate does not actually have a single name
if let &Definition::Module(module) = self {
if module.is_crate_root(db) {
return SearchScope::reverse_dependencies(db, module.krate());
}
}
let module = match self.module(db) {
Some(it) => it,
None => return SearchScope::empty(),
};
let InFile { file_id, value: module_source } = module.definition_source(db);
let file_id = file_id.original_file(db);
if let Definition::Local(var) = self {
let def = match var.parent(db) {
DefWithBody::Function(f) => f.source(db).map(|src| src.syntax().cloned()),
DefWithBody::Const(c) => c.source(db).map(|src| src.syntax().cloned()),
DefWithBody::Static(s) => s.source(db).map(|src| src.syntax().cloned()),
};
return match def {
Some(def) => SearchScope::file_range(def.as_ref().original_file_range(db)),
None => SearchScope::single_file(file_id),
};
}
if let Definition::SelfType(impl_) = self {
return match impl_.source(db).map(|src| src.syntax().cloned()) {
Some(def) => SearchScope::file_range(def.as_ref().original_file_range(db)),
None => SearchScope::single_file(file_id),
};
}
if let Definition::GenericParam(hir::GenericParam::LifetimeParam(param)) = self {
let def = match param.parent(db) {
hir::GenericDef::Function(it) => it.source(db).map(|src| src.syntax().cloned()),
hir::GenericDef::Adt(it) => it.source(db).map(|src| src.syntax().cloned()),
hir::GenericDef::Trait(it) => it.source(db).map(|src| src.syntax().cloned()),
hir::GenericDef::TypeAlias(it) => it.source(db).map(|src| src.syntax().cloned()),
hir::GenericDef::Impl(it) => it.source(db).map(|src| src.syntax().cloned()),
hir::GenericDef::Variant(it) => it.source(db).map(|src| src.syntax().cloned()),
hir::GenericDef::Const(it) => it.source(db).map(|src| src.syntax().cloned()),
};
return match def {
Some(def) => SearchScope::file_range(def.as_ref().original_file_range(db)),
None => SearchScope::single_file(file_id),
};
}
if let Definition::Macro(macro_def) = self {
return match macro_def.kind(db) {
hir::MacroKind::Declarative => {
if macro_def.attrs(db).by_key("macro_export").exists() {
SearchScope::reverse_dependencies(db, module.krate())
} else {
SearchScope::krate(db, module.krate())
}
}
hir::MacroKind::BuiltIn => SearchScope::crate_graph(db),
hir::MacroKind::Derive | hir::MacroKind::Attr | hir::MacroKind::ProcMacro => {
SearchScope::reverse_dependencies(db, module.krate())
}
};
}
if let Definition::DeriveHelper(_) = self {
return SearchScope::reverse_dependencies(db, module.krate());
}
let vis = self.visibility(db);
if let Some(Visibility::Public) = vis {
return SearchScope::reverse_dependencies(db, module.krate());
}
if let Some(Visibility::Module(module)) = vis {
return SearchScope::module_and_children(db, module.into());
}
let range = match module_source {
ModuleSource::Module(m) => Some(m.syntax().text_range()),
ModuleSource::BlockExpr(b) => Some(b.syntax().text_range()),
ModuleSource::SourceFile(_) => None,
};
match range {
Some(range) => SearchScope::file_range(FileRange { file_id, range }),
None => SearchScope::single_file(file_id),
}
}
pub fn usages<'a>(self, sema: &'a Semantics<'_, RootDatabase>) -> FindUsages<'a> {
FindUsages {
local_repr: match self {
Definition::Local(local) => Some(local.representative(sema.db)),
_ => None,
},
def: self,
trait_assoc_def: as_trait_assoc_def(sema.db, self),
sema,
scope: None,
include_self_kw_refs: None,
search_self_mod: false,
}
}
}
#[derive(Clone)]
pub struct FindUsages<'a> {
def: Definition,
/// If def is an assoc item from a trait or trait impl, this is the corresponding item of the trait definition
trait_assoc_def: Option<Definition>,
sema: &'a Semantics<'a, RootDatabase>,
scope: Option<SearchScope>,
include_self_kw_refs: Option<hir::Type>,
local_repr: Option<hir::Local>,
search_self_mod: bool,
}
impl<'a> FindUsages<'a> {
/// Enable searching for `Self` when the definition is a type or `self` for modules.
pub fn include_self_refs(mut self) -> FindUsages<'a> {
self.include_self_kw_refs = def_to_ty(self.sema, &self.def);
self.search_self_mod = true;
self
}
/// Limit the search to a given [`SearchScope`].
pub fn in_scope(self, scope: SearchScope) -> FindUsages<'a> {
self.set_scope(Some(scope))
}
/// Limit the search to a given [`SearchScope`].
pub fn set_scope(mut self, scope: Option<SearchScope>) -> FindUsages<'a> {
assert!(self.scope.is_none());
self.scope = scope;
self
}
pub fn at_least_one(&self) -> bool {
let mut found = false;
self.search(&mut |_, _| {
found = true;
true
});
found
}
pub fn all(self) -> UsageSearchResult {
let mut res = UsageSearchResult::default();
self.search(&mut |file_id, reference| {
res.references.entry(file_id).or_default().push(reference);
false
});
res
}
fn search(&self, sink: &mut dyn FnMut(FileId, FileReference) -> bool) {
let _p = profile::span("FindUsages:search");
let sema = self.sema;
let search_scope = {
let base = self.trait_assoc_def.unwrap_or(self.def).search_scope(sema.db);
match &self.scope {
None => base,
Some(scope) => base.intersection(scope),
}
};
let name = match self.def {
// special case crate modules as these do not have a proper name
Definition::Module(module) if module.is_crate_root(self.sema.db) => {
// FIXME: This assumes the crate name is always equal to its display name when it really isn't
module
.krate()
.display_name(self.sema.db)
.map(|crate_name| crate_name.crate_name().as_smol_str().clone())
}
_ => {
let self_kw_refs = || {
self.include_self_kw_refs.as_ref().and_then(|ty| {
ty.as_adt()
.map(|adt| adt.name(self.sema.db))
.or_else(|| ty.as_builtin().map(|builtin| builtin.name()))
})
};
self.def.name(sema.db).or_else(self_kw_refs).map(|it| it.to_smol_str())
}
};
let name = match &name {
Some(s) => s.as_str(),
None => return,
};
// these can't be closures because rust infers the lifetimes wrong ...
fn match_indices<'a>(
text: &'a str,
name: &'a str,
search_range: TextRange,
) -> impl Iterator<Item = TextSize> + 'a {
text.match_indices(name).filter_map(move |(idx, _)| {
let offset: TextSize = idx.try_into().unwrap();
if !search_range.contains_inclusive(offset) {
return None;
}
Some(offset)
})
}
fn scope_files<'a>(
sema: &'a Semantics<'_, RootDatabase>,
scope: &'a SearchScope,
) -> impl Iterator<Item = (Arc<String>, FileId, TextRange)> + 'a {
scope.entries.iter().map(|(&file_id, &search_range)| {
let text = sema.db.file_text(file_id);
let search_range =
search_range.unwrap_or_else(|| TextRange::up_to(TextSize::of(text.as_str())));
(text, file_id, search_range)
})
}
// FIXME: There should be optimization potential here
// Currently we try to descend everything we find which
// means we call `Semantics::descend_into_macros` on
// every textual hit. That function is notoriously
// expensive even for things that do not get down mapped
// into macros.
for (text, file_id, search_range) in scope_files(sema, &search_scope) {
let tree = Lazy::new(move || sema.parse(file_id).syntax().clone());
// Search for occurrences of the items name
for offset in match_indices(&text, name, search_range) {
for name in sema.find_nodes_at_offset_with_descend(&tree, offset) {
if match name {
ast::NameLike::NameRef(name_ref) => self.found_name_ref(&name_ref, sink),
ast::NameLike::Name(name) => self.found_name(&name, sink),
ast::NameLike::Lifetime(lifetime) => self.found_lifetime(&lifetime, sink),
} {
return;
}
}
}
// Search for occurrences of the `Self` referring to our type
if let Some(self_ty) = &self.include_self_kw_refs {
for offset in match_indices(&text, "Self", search_range) {
for name_ref in sema.find_nodes_at_offset_with_descend(&tree, offset) {
if self.found_self_ty_name_ref(self_ty, &name_ref, sink) {
return;
}
}
}
}
}
// Search for `super` and `crate` resolving to our module
match self.def {
Definition::Module(module) => {
let scope = search_scope
.intersection(&SearchScope::module_and_children(self.sema.db, module));
let is_crate_root = module.is_crate_root(self.sema.db);
for (text, file_id, search_range) in scope_files(sema, &scope) {
let tree = Lazy::new(move || sema.parse(file_id).syntax().clone());
for offset in match_indices(&text, "super", search_range) {
for name_ref in sema.find_nodes_at_offset_with_descend(&tree, offset) {
if self.found_name_ref(&name_ref, sink) {
return;
}
}
}
if is_crate_root {
for offset in match_indices(&text, "crate", search_range) {
for name_ref in sema.find_nodes_at_offset_with_descend(&tree, offset) {
if self.found_name_ref(&name_ref, sink) {
return;
}
}
}
}
}
}
_ => (),
}
// search for module `self` references in our module's definition source
match self.def {
Definition::Module(module) if self.search_self_mod => {
let src = module.definition_source(sema.db);
let file_id = src.file_id.original_file(sema.db);
let (file_id, search_range) = match src.value {
ModuleSource::Module(m) => (file_id, Some(m.syntax().text_range())),
ModuleSource::BlockExpr(b) => (file_id, Some(b.syntax().text_range())),
ModuleSource::SourceFile(_) => (file_id, None),
};
let search_range = if let Some(&range) = search_scope.entries.get(&file_id) {
match (range, search_range) {
(None, range) | (range, None) => range,
(Some(range), Some(search_range)) => match range.intersect(search_range) {
Some(range) => Some(range),
None => return,
},
}
} else {
return;
};
let text = sema.db.file_text(file_id);
let search_range =
search_range.unwrap_or_else(|| TextRange::up_to(TextSize::of(text.as_str())));
let tree = Lazy::new(|| sema.parse(file_id).syntax().clone());
for offset in match_indices(&text, "self", search_range) {
for name_ref in sema.find_nodes_at_offset_with_descend(&tree, offset) {
if self.found_self_module_name_ref(&name_ref, sink) {
return;
}
}
}
}
_ => {}
}
}
fn found_self_ty_name_ref(
&self,
self_ty: &hir::Type,
name_ref: &ast::NameRef,
sink: &mut dyn FnMut(FileId, FileReference) -> bool,
) -> bool {
match NameRefClass::classify(self.sema, name_ref) {
Some(NameRefClass::Definition(Definition::SelfType(impl_)))
if impl_.self_ty(self.sema.db) == *self_ty =>
{
let FileRange { file_id, range } = self.sema.original_range(name_ref.syntax());
let reference = FileReference {
range,
name: ast::NameLike::NameRef(name_ref.clone()),
category: None,
};
sink(file_id, reference)
}
_ => false,
}
}
fn found_self_module_name_ref(
&self,
name_ref: &ast::NameRef,
sink: &mut dyn FnMut(FileId, FileReference) -> bool,
) -> bool {
match NameRefClass::classify(self.sema, name_ref) {
Some(NameRefClass::Definition(def @ Definition::Module(_))) if def == self.def => {
let FileRange { file_id, range } = self.sema.original_range(name_ref.syntax());
let reference = FileReference {
range,
name: ast::NameLike::NameRef(name_ref.clone()),
category: None,
};
sink(file_id, reference)
}
_ => false,
}
}
fn found_lifetime(
&self,
lifetime: &ast::Lifetime,
sink: &mut dyn FnMut(FileId, FileReference) -> bool,
) -> bool {
match NameRefClass::classify_lifetime(self.sema, lifetime) {
Some(NameRefClass::Definition(def)) if def == self.def => {
let FileRange { file_id, range } = self.sema.original_range(lifetime.syntax());
let reference = FileReference {
range,
name: ast::NameLike::Lifetime(lifetime.clone()),
category: None,
};
sink(file_id, reference)
}
_ => false,
}
}
fn found_name_ref(
&self,
name_ref: &ast::NameRef,
sink: &mut dyn FnMut(FileId, FileReference) -> bool,
) -> bool {
match NameRefClass::classify(self.sema, name_ref) {
Some(NameRefClass::Definition(def @ Definition::Local(local)))
if matches!(
self.local_repr, Some(repr) if repr == local.representative(self.sema.db)
) =>
{
let FileRange { file_id, range } = self.sema.original_range(name_ref.syntax());
let reference = FileReference {
range,
name: ast::NameLike::NameRef(name_ref.clone()),
category: ReferenceCategory::new(&def, name_ref),
};
sink(file_id, reference)
}
Some(NameRefClass::Definition(def))
if match self.trait_assoc_def {
Some(trait_assoc_def) => {
// we have a trait assoc item, so force resolve all assoc items to their trait version
convert_to_def_in_trait(self.sema.db, def) == trait_assoc_def
}
None => self.def == def,
} =>
{
let FileRange { file_id, range } = self.sema.original_range(name_ref.syntax());
let reference = FileReference {
range,
name: ast::NameLike::NameRef(name_ref.clone()),
category: ReferenceCategory::new(&def, name_ref),
};
sink(file_id, reference)
}
Some(NameRefClass::Definition(def)) if self.include_self_kw_refs.is_some() => {
if self.include_self_kw_refs == def_to_ty(self.sema, &def) {
let FileRange { file_id, range } = self.sema.original_range(name_ref.syntax());
let reference = FileReference {
range,
name: ast::NameLike::NameRef(name_ref.clone()),
category: ReferenceCategory::new(&def, name_ref),
};
sink(file_id, reference)
} else {
false
}
}
Some(NameRefClass::FieldShorthand { local_ref: local, field_ref: field }) => {
let field = Definition::Field(field);
let FileRange { file_id, range } = self.sema.original_range(name_ref.syntax());
let access = match self.def {
Definition::Field(_) if field == self.def => {
ReferenceCategory::new(&field, name_ref)
}
Definition::Local(_) if matches!(self.local_repr, Some(repr) if repr == local.representative(self.sema.db)) => {
ReferenceCategory::new(&Definition::Local(local), name_ref)
}
_ => return false,
};
let reference = FileReference {
range,
name: ast::NameLike::NameRef(name_ref.clone()),
category: access,
};
sink(file_id, reference)
}
_ => false,
}
}
fn found_name(
&self,
name: &ast::Name,
sink: &mut dyn FnMut(FileId, FileReference) -> bool,
) -> bool {
match NameClass::classify(self.sema, name) {
Some(NameClass::PatFieldShorthand { local_def: _, field_ref })
if matches!(
self.def, Definition::Field(_) if Definition::Field(field_ref) == self.def
) =>
{
let FileRange { file_id, range } = self.sema.original_range(name.syntax());
let reference = FileReference {
range,
name: ast::NameLike::Name(name.clone()),
// FIXME: mutable patterns should have `Write` access
category: Some(ReferenceCategory::Read),
};
sink(file_id, reference)
}
Some(NameClass::ConstReference(def)) if self.def == def => {
let FileRange { file_id, range } = self.sema.original_range(name.syntax());
let reference = FileReference {
range,
name: ast::NameLike::Name(name.clone()),
category: None,
};
sink(file_id, reference)
}
Some(NameClass::Definition(def @ Definition::Local(local))) if def != self.def => {
if matches!(
self.local_repr,
Some(repr) if local.representative(self.sema.db) == repr
) {
let FileRange { file_id, range } = self.sema.original_range(name.syntax());
let reference = FileReference {
range,
name: ast::NameLike::Name(name.clone()),
category: None,
};
return sink(file_id, reference);
}
false
}
Some(NameClass::Definition(def)) if def != self.def => {
// if the def we are looking for is a trait (impl) assoc item, we'll have to resolve the items to trait definition assoc item
if !matches!(
self.trait_assoc_def,
Some(trait_assoc_def)
if convert_to_def_in_trait(self.sema.db, def) == trait_assoc_def
) {
return false;
}
let FileRange { file_id, range } = self.sema.original_range(name.syntax());
let reference = FileReference {
range,
name: ast::NameLike::Name(name.clone()),
category: None,
};
sink(file_id, reference)
}
_ => false,
}
}
}
fn def_to_ty(sema: &Semantics<'_, RootDatabase>, def: &Definition) -> Option<hir::Type> {
match def {
Definition::Adt(adt) => Some(adt.ty(sema.db)),
Definition::TypeAlias(it) => Some(it.ty(sema.db)),
Definition::BuiltinType(it) => Some(it.ty(sema.db)),
Definition::SelfType(it) => Some(it.self_ty(sema.db)),
_ => None,
}
}
impl ReferenceCategory {
fn new(def: &Definition, r: &ast::NameRef) -> Option<ReferenceCategory> {
// Only Locals and Fields have accesses for now.
if !matches!(def, Definition::Local(_) | Definition::Field(_)) {
return None;
}
let mode = r.syntax().ancestors().find_map(|node| {
match_ast! {
match node {
ast::BinExpr(expr) => {
if matches!(expr.op_kind()?, ast::BinaryOp::Assignment { .. }) {
// If the variable or field ends on the LHS's end then it's a Write (covers fields and locals).
// FIXME: This is not terribly accurate.
if let Some(lhs) = expr.lhs() {
if lhs.syntax().text_range().end() == r.syntax().text_range().end() {
return Some(ReferenceCategory::Write);
}
}
}
Some(ReferenceCategory::Read)
},
_ => None
}
}
});
// Default Locals and Fields to read
mode.or(Some(ReferenceCategory::Read))
}
}