//! `render` module provides utilities for rendering completion suggestions //! into code pieces that will be presented to user. pub(crate) mod macro_; pub(crate) mod function; pub(crate) mod enum_variant; pub(crate) mod const_; pub(crate) mod pattern; pub(crate) mod type_alias; mod builder_ext; use hir::{AsAssocItem, HasAttrs, HirDisplay}; use ide_db::{ helpers::{item_name, SnippetCap}, RootDatabase, SymbolKind, }; use syntax::TextRange; use crate::{ context::{PathCompletionContext, PathKind}, item::{CompletionRelevanceTypeMatch, ImportEdit}, render::{enum_variant::render_variant, function::render_fn, macro_::render_macro}, CompletionContext, CompletionItem, CompletionItemKind, CompletionKind, CompletionRelevance, }; pub(crate) fn render_field( ctx: RenderContext<'_>, receiver: Option, field: hir::Field, ty: &hir::Type, ) -> CompletionItem { render_field_(ctx, receiver, field, ty) } pub(crate) fn render_tuple_field( ctx: RenderContext<'_>, receiver: Option, field: usize, ty: &hir::Type, ) -> CompletionItem { render_tuple_field_(ctx, receiver, field, ty) } pub(crate) fn render_resolution( ctx: RenderContext<'_>, local_name: hir::Name, resolution: &hir::ScopeDef, ) -> Option { render_resolution_(ctx, local_name, None, resolution) } pub(crate) fn render_resolution_with_import( ctx: RenderContext<'_>, import_edit: ImportEdit, ) -> Option { let resolution = hir::ScopeDef::from(import_edit.import.original_item); if ctx.completion.expects_type() && resolution.is_value_def() { return None; } let local_name = match resolution { hir::ScopeDef::ModuleDef(hir::ModuleDef::Function(f)) => f.name(ctx.completion.db), hir::ScopeDef::ModuleDef(hir::ModuleDef::Const(c)) => c.name(ctx.completion.db)?, hir::ScopeDef::ModuleDef(hir::ModuleDef::TypeAlias(t)) => t.name(ctx.completion.db), _ => item_name(ctx.db(), import_edit.import.original_item)?, }; render_resolution_(ctx, local_name, Some(import_edit), &resolution).map(|mut item| { item.completion_kind = CompletionKind::Magic; item }) } /// Interface for data and methods required for items rendering. #[derive(Debug)] pub(crate) struct RenderContext<'a> { completion: &'a CompletionContext<'a>, } impl<'a> RenderContext<'a> { pub(crate) fn new(completion: &'a CompletionContext<'a>) -> RenderContext<'a> { RenderContext { completion } } fn snippet_cap(&self) -> Option { self.completion.config.snippet_cap } fn db(&self) -> &'a RootDatabase { &self.completion.db } fn source_range(&self) -> TextRange { self.completion.source_range() } fn is_deprecated(&self, node: impl HasAttrs) -> bool { let attrs = node.attrs(self.db()); attrs.by_key("deprecated").exists() || attrs.by_key("rustc_deprecated").exists() } fn is_deprecated_assoc_item(&self, as_assoc_item: impl AsAssocItem) -> bool { let db = self.db(); let assoc = match as_assoc_item.as_assoc_item(db) { Some(assoc) => assoc, None => return false, }; let is_assoc_deprecated = match assoc { hir::AssocItem::Function(it) => self.is_deprecated(it), hir::AssocItem::Const(it) => self.is_deprecated(it), hir::AssocItem::TypeAlias(it) => self.is_deprecated(it), }; is_assoc_deprecated || assoc.containing_trait(db).map(|trait_| self.is_deprecated(trait_)).unwrap_or(false) } fn docs(&self, node: impl HasAttrs) -> Option { node.docs(self.db()) } } fn render_field_( ctx: RenderContext<'_>, receiver: Option, field: hir::Field, ty: &hir::Type, ) -> CompletionItem { let is_deprecated = ctx.is_deprecated(field); let name = field.name(ctx.db()).to_string(); let mut item = CompletionItem::new( CompletionKind::Reference, ctx.source_range(), receiver.map_or_else(|| name.clone(), |receiver| format!("{}.{}", receiver, name)), ); item.set_relevance(CompletionRelevance { type_match: compute_type_match(ctx.completion, ty), exact_name_match: compute_exact_name_match(ctx.completion, &name), ..CompletionRelevance::default() }); item.kind(SymbolKind::Field) .detail(ty.display(ctx.db()).to_string()) .set_documentation(field.docs(ctx.db())) .set_deprecated(is_deprecated) .lookup_by(name); if let Some(_ref_match) = compute_ref_match(ctx.completion, ty) { // FIXME // For now we don't properly calculate the edits for ref match // completions on struct fields, so we've disabled them. See #8058. } item.build() } fn render_tuple_field_( ctx: RenderContext<'_>, receiver: Option, field: usize, ty: &hir::Type, ) -> CompletionItem { let mut item = CompletionItem::new( CompletionKind::Reference, ctx.source_range(), receiver.map_or_else(|| field.to_string(), |receiver| format!("{}.{}", receiver, field)), ); item.kind(SymbolKind::Field) .detail(ty.display(ctx.db()).to_string()) .lookup_by(field.to_string()); item.build() } fn render_resolution_( ctx: RenderContext<'_>, local_name: hir::Name, import_to_add: Option, resolution: &hir::ScopeDef, ) -> Option { let _p = profile::span("render_resolution"); use hir::ModuleDef::*; let completion_kind = match resolution { hir::ScopeDef::ModuleDef(BuiltinType(..)) => CompletionKind::BuiltinType, _ => CompletionKind::Reference, }; let kind = match resolution { hir::ScopeDef::ModuleDef(Function(func)) => { return render_fn(ctx, import_to_add, Some(local_name), *func); } hir::ScopeDef::ModuleDef(Variant(_)) if ctx.completion.is_pat_or_const.is_some() => { CompletionItemKind::SymbolKind(SymbolKind::Variant) } hir::ScopeDef::ModuleDef(Variant(var)) => { let item = render_variant(ctx, import_to_add, Some(local_name), *var, None); return Some(item); } hir::ScopeDef::MacroDef(mac) => { let item = render_macro(ctx, import_to_add, local_name, *mac); return item; } hir::ScopeDef::ModuleDef(Module(..)) => CompletionItemKind::SymbolKind(SymbolKind::Module), hir::ScopeDef::ModuleDef(Adt(adt)) => CompletionItemKind::SymbolKind(match adt { hir::Adt::Struct(_) => SymbolKind::Struct, hir::Adt::Union(_) => SymbolKind::Union, hir::Adt::Enum(_) => SymbolKind::Enum, }), hir::ScopeDef::ModuleDef(Const(..)) => CompletionItemKind::SymbolKind(SymbolKind::Const), hir::ScopeDef::ModuleDef(Static(..)) => CompletionItemKind::SymbolKind(SymbolKind::Static), hir::ScopeDef::ModuleDef(Trait(..)) => CompletionItemKind::SymbolKind(SymbolKind::Trait), hir::ScopeDef::ModuleDef(TypeAlias(..)) => { CompletionItemKind::SymbolKind(SymbolKind::TypeAlias) } hir::ScopeDef::ModuleDef(BuiltinType(..)) => CompletionItemKind::BuiltinType, hir::ScopeDef::GenericParam(param) => CompletionItemKind::SymbolKind(match param { hir::GenericParam::TypeParam(_) => SymbolKind::TypeParam, hir::GenericParam::LifetimeParam(_) => SymbolKind::LifetimeParam, hir::GenericParam::ConstParam(_) => SymbolKind::ConstParam, }), hir::ScopeDef::Local(..) => CompletionItemKind::SymbolKind(SymbolKind::Local), hir::ScopeDef::Label(..) => CompletionItemKind::SymbolKind(SymbolKind::Label), hir::ScopeDef::AdtSelfType(..) | hir::ScopeDef::ImplSelfType(..) => { CompletionItemKind::SymbolKind(SymbolKind::SelfParam) } hir::ScopeDef::Unknown => { let mut item = CompletionItem::new( CompletionKind::Reference, ctx.source_range(), local_name.to_string(), ); item.kind(CompletionItemKind::UnresolvedReference).add_import(import_to_add); return Some(item.build()); } }; let local_name = local_name.to_string(); let mut item = CompletionItem::new(completion_kind, ctx.source_range(), local_name.clone()); if let hir::ScopeDef::Local(local) = resolution { let ty = local.ty(ctx.db()); if !ty.is_unknown() { item.detail(ty.display(ctx.db()).to_string()); } item.set_relevance(CompletionRelevance { type_match: compute_type_match(ctx.completion, &ty), exact_name_match: compute_exact_name_match(ctx.completion, &local_name), is_local: true, ..CompletionRelevance::default() }); if let Some(ref_match) = compute_ref_match(ctx.completion, &ty) { item.ref_match(ref_match); } }; // Add `<>` for generic types if matches!( ctx.completion.path_context, Some(PathCompletionContext { kind: Some(PathKind::Type), has_type_args: false, .. }) ) && ctx.completion.config.add_call_parenthesis { if let Some(cap) = ctx.snippet_cap() { let has_non_default_type_params = match resolution { hir::ScopeDef::ModuleDef(Adt(it)) => it.has_non_default_type_params(ctx.db()), hir::ScopeDef::ModuleDef(TypeAlias(it)) => it.has_non_default_type_params(ctx.db()), _ => false, }; if has_non_default_type_params { cov_mark::hit!(inserts_angle_brackets_for_generics); item.lookup_by(local_name.clone()) .label(format!("{}<…>", local_name)) .insert_snippet(cap, format!("{}<$0>", local_name)); } } } item.kind(kind) .add_import(import_to_add) .set_documentation(scope_def_docs(ctx.db(), resolution)) .set_deprecated(scope_def_is_deprecated(&ctx, resolution)); Some(item.build()) } fn scope_def_docs(db: &RootDatabase, resolution: &hir::ScopeDef) -> Option { use hir::ModuleDef::*; match resolution { hir::ScopeDef::ModuleDef(Module(it)) => it.docs(db), hir::ScopeDef::ModuleDef(Adt(it)) => it.docs(db), hir::ScopeDef::ModuleDef(Variant(it)) => it.docs(db), hir::ScopeDef::ModuleDef(Const(it)) => it.docs(db), hir::ScopeDef::ModuleDef(Static(it)) => it.docs(db), hir::ScopeDef::ModuleDef(Trait(it)) => it.docs(db), hir::ScopeDef::ModuleDef(TypeAlias(it)) => it.docs(db), _ => None, } } fn scope_def_is_deprecated(ctx: &RenderContext<'_>, resolution: &hir::ScopeDef) -> bool { match resolution { hir::ScopeDef::ModuleDef(it) => ctx.is_deprecated_assoc_item(*it), hir::ScopeDef::MacroDef(it) => ctx.is_deprecated(*it), hir::ScopeDef::GenericParam(it) => ctx.is_deprecated(*it), hir::ScopeDef::AdtSelfType(it) => ctx.is_deprecated(*it), _ => false, } } fn compute_type_match( ctx: &CompletionContext, completion_ty: &hir::Type, ) -> Option { let expected_type = ctx.expected_type.as_ref()?; // We don't ever consider unit type to be an exact type match, since // nearly always this is not meaningful to the user. if expected_type.is_unit() { return None; } if completion_ty == expected_type { Some(CompletionRelevanceTypeMatch::Exact) } else if expected_type.could_unify_with(ctx.db, completion_ty) { Some(CompletionRelevanceTypeMatch::CouldUnify) } else { None } } fn compute_exact_name_match(ctx: &CompletionContext, completion_name: &str) -> bool { ctx.expected_name.as_ref().map_or(false, |name| name.text() == completion_name) } fn compute_ref_match( ctx: &CompletionContext, completion_ty: &hir::Type, ) -> Option { let expected_type = ctx.expected_type.as_ref()?; if completion_ty != expected_type { let expected_type_without_ref = expected_type.remove_ref()?; if completion_ty.autoderef(ctx.db).any(|deref_ty| deref_ty == expected_type_without_ref) { cov_mark::hit!(suggest_ref); let mutability = if expected_type.is_mutable_reference() { hir::Mutability::Mut } else { hir::Mutability::Shared }; return Some(mutability); }; } None } #[cfg(test)] mod tests { use expect_test::{expect, Expect}; use itertools::Itertools; use crate::{ item::CompletionRelevanceTypeMatch, test_utils::{check_edit, do_completion, get_all_items, TEST_CONFIG}, CompletionKind, CompletionRelevance, }; fn check(ra_fixture: &str, expect: Expect) { let actual = do_completion(ra_fixture, CompletionKind::Reference); expect.assert_debug_eq(&actual); } fn check_relevance(ra_fixture: &str, expect: Expect) { fn display_relevance(relevance: CompletionRelevance) -> String { let relevance_factors = vec![ (relevance.type_match == Some(CompletionRelevanceTypeMatch::Exact), "type"), ( relevance.type_match == Some(CompletionRelevanceTypeMatch::CouldUnify), "type_could_unify", ), (relevance.exact_name_match, "name"), (relevance.is_local, "local"), ] .into_iter() .filter_map(|(cond, desc)| if cond { Some(desc) } else { None }) .join("+"); format!("[{}]", relevance_factors) } let actual = get_all_items(TEST_CONFIG, ra_fixture) .into_iter() .filter(|it| it.completion_kind == CompletionKind::Reference) .flat_map(|it| { let mut items = vec![]; let tag = it.kind().unwrap().tag(); let relevance = display_relevance(it.relevance()); items.push(format!("{} {} {}\n", tag, it.label(), relevance)); if let Some((mutability, relevance)) = it.ref_match() { let label = format!("&{}{}", mutability.as_keyword_for_ref(), it.label()); let relevance = display_relevance(relevance); items.push(format!("{} {} {}\n", tag, label, relevance)); } items }) .collect::(); expect.assert_eq(&actual); } #[test] fn enum_detail_includes_record_fields() { check( r#" enum Foo { Foo { x: i32, y: i32 } } fn main() { Foo::Fo$0 } "#, expect![[r#" [ CompletionItem { label: "Foo", source_range: 54..56, delete: 54..56, insert: "Foo", kind: SymbolKind( Variant, ), detail: "{ x: i32, y: i32 }", }, ] "#]], ); } #[test] fn enum_detail_doesnt_include_tuple_fields() { check( r#" enum Foo { Foo (i32, i32) } fn main() { Foo::Fo$0 } "#, expect![[r#" [ CompletionItem { label: "Foo(…)", source_range: 46..48, delete: 46..48, insert: "Foo($0)", kind: SymbolKind( Variant, ), lookup: "Foo", detail: "(i32, i32)", trigger_call_info: true, }, ] "#]], ); } #[test] fn fn_detail_includes_args_and_return_type() { check( r#" fn foo(a: u32, b: u32, t: T) -> (u32, T) { (a, t) } fn main() { fo$0 } "#, expect![[r#" [ CompletionItem { label: "foo(…)", source_range: 68..70, delete: 68..70, insert: "foo(${1:a}, ${2:b}, ${3:t})$0", kind: SymbolKind( Function, ), lookup: "foo", detail: "fn(u32, u32, T) -> (u32, T)", trigger_call_info: true, }, CompletionItem { label: "main()", source_range: 68..70, delete: 68..70, insert: "main()$0", kind: SymbolKind( Function, ), lookup: "main", detail: "fn()", }, ] "#]], ); } #[test] fn enum_detail_just_parentheses_for_unit() { check( r#" enum Foo { Foo } fn main() { Foo::Fo$0 } "#, expect![[r#" [ CompletionItem { label: "Foo", source_range: 35..37, delete: 35..37, insert: "Foo", kind: SymbolKind( Variant, ), detail: "()", }, ] "#]], ); } #[test] fn lookup_enums_by_two_qualifiers() { check( r#" mod m { pub enum Spam { Foo, Bar(i32) } } fn main() { let _: m::Spam = S$0 } "#, expect![[r#" [ CompletionItem { label: "Spam::Bar(…)", source_range: 75..76, delete: 75..76, insert: "Spam::Bar($0)", kind: SymbolKind( Variant, ), lookup: "Spam::Bar", detail: "(i32)", relevance: CompletionRelevance { exact_name_match: false, type_match: Some( Exact, ), is_local: false, }, trigger_call_info: true, }, CompletionItem { label: "m", source_range: 75..76, delete: 75..76, insert: "m", kind: SymbolKind( Module, ), }, CompletionItem { label: "m::Spam::Foo", source_range: 75..76, delete: 75..76, insert: "m::Spam::Foo", kind: SymbolKind( Variant, ), lookup: "Spam::Foo", detail: "()", relevance: CompletionRelevance { exact_name_match: false, type_match: Some( Exact, ), is_local: false, }, }, CompletionItem { label: "main()", source_range: 75..76, delete: 75..76, insert: "main()$0", kind: SymbolKind( Function, ), lookup: "main", detail: "fn()", }, ] "#]], ) } #[test] fn sets_deprecated_flag_in_items() { check( r#" #[deprecated] fn something_deprecated() {} #[rustc_deprecated(since = "1.0.0")] fn something_else_deprecated() {} fn main() { som$0 } "#, expect![[r#" [ CompletionItem { label: "main()", source_range: 127..130, delete: 127..130, insert: "main()$0", kind: SymbolKind( Function, ), lookup: "main", detail: "fn()", }, CompletionItem { label: "something_deprecated()", source_range: 127..130, delete: 127..130, insert: "something_deprecated()$0", kind: SymbolKind( Function, ), lookup: "something_deprecated", detail: "fn()", deprecated: true, }, CompletionItem { label: "something_else_deprecated()", source_range: 127..130, delete: 127..130, insert: "something_else_deprecated()$0", kind: SymbolKind( Function, ), lookup: "something_else_deprecated", detail: "fn()", deprecated: true, }, ] "#]], ); check( r#" struct A { #[deprecated] the_field: u32 } fn foo() { A { the$0 } } "#, expect![[r#" [ CompletionItem { label: "the_field", source_range: 57..60, delete: 57..60, insert: "the_field", kind: SymbolKind( Field, ), detail: "u32", deprecated: true, relevance: CompletionRelevance { exact_name_match: false, type_match: Some( CouldUnify, ), is_local: false, }, }, ] "#]], ); } #[test] fn renders_docs() { check( r#" struct S { /// Field docs foo: } impl S { /// Method docs fn bar(self) { self.$0 } }"#, expect![[r#" [ CompletionItem { label: "bar()", source_range: 94..94, delete: 94..94, insert: "bar()$0", kind: Method, lookup: "bar", detail: "fn(self)", documentation: Documentation( "Method docs", ), }, CompletionItem { label: "foo", source_range: 94..94, delete: 94..94, insert: "foo", kind: SymbolKind( Field, ), detail: "{unknown}", documentation: Documentation( "Field docs", ), }, ] "#]], ); check( r#" use self::my$0; /// mod docs mod my { } /// enum docs enum E { /// variant docs V } use self::E::*; "#, expect![[r#" [ CompletionItem { label: "E", source_range: 10..12, delete: 10..12, insert: "E", kind: SymbolKind( Enum, ), documentation: Documentation( "enum docs", ), }, CompletionItem { label: "V", source_range: 10..12, delete: 10..12, insert: "V", kind: SymbolKind( Variant, ), detail: "()", documentation: Documentation( "variant docs", ), }, CompletionItem { label: "my", source_range: 10..12, delete: 10..12, insert: "my", kind: SymbolKind( Module, ), documentation: Documentation( "mod docs", ), }, ] "#]], ) } #[test] fn dont_render_attrs() { check( r#" struct S; impl S { #[inline] fn the_method(&self) { } } fn foo(s: S) { s.$0 } "#, expect![[r#" [ CompletionItem { label: "the_method()", source_range: 81..81, delete: 81..81, insert: "the_method()$0", kind: Method, lookup: "the_method", detail: "fn(&self)", }, ] "#]], ) } #[test] fn no_call_parens_if_fn_ptr_needed() { cov_mark::check!(no_call_parens_if_fn_ptr_needed); check_edit( "foo", r#" fn foo(foo: u8, bar: u8) {} struct ManualVtable { f: fn(u8, u8) } fn main() -> ManualVtable { ManualVtable { f: f$0 } } "#, r#" fn foo(foo: u8, bar: u8) {} struct ManualVtable { f: fn(u8, u8) } fn main() -> ManualVtable { ManualVtable { f: foo } } "#, ); } #[test] fn no_parens_in_use_item() { cov_mark::check!(no_parens_in_use_item); check_edit( "foo", r#" mod m { pub fn foo() {} } use crate::m::f$0; "#, r#" mod m { pub fn foo() {} } use crate::m::foo; "#, ); } #[test] fn no_parens_in_call() { check_edit( "foo", r#" fn foo(x: i32) {} fn main() { f$0(); } "#, r#" fn foo(x: i32) {} fn main() { foo(); } "#, ); check_edit( "foo", r#" struct Foo; impl Foo { fn foo(&self){} } fn f(foo: &Foo) { foo.f$0(); } "#, r#" struct Foo; impl Foo { fn foo(&self){} } fn f(foo: &Foo) { foo.foo(); } "#, ); } #[test] fn inserts_angle_brackets_for_generics() { cov_mark::check!(inserts_angle_brackets_for_generics); check_edit( "Vec", r#" struct Vec {} fn foo(xs: Ve$0) "#, r#" struct Vec {} fn foo(xs: Vec<$0>) "#, ); check_edit( "Vec", r#" type Vec = (T,); fn foo(xs: Ve$0) "#, r#" type Vec = (T,); fn foo(xs: Vec<$0>) "#, ); check_edit( "Vec", r#" struct Vec {} fn foo(xs: Ve$0) "#, r#" struct Vec {} fn foo(xs: Vec) "#, ); check_edit( "Vec", r#" struct Vec {} fn foo(xs: Ve$0) "#, r#" struct Vec {} fn foo(xs: Vec) "#, ); } #[test] fn active_param_relevance() { check_relevance( r#" struct S { foo: i64, bar: u32, baz: u32 } fn test(bar: u32) { } fn foo(s: S) { test(s.$0) } "#, expect![[r#" fd foo [] fd bar [type+name] fd baz [type] "#]], ); } #[test] fn record_field_relevances() { check_relevance( r#" struct A { foo: i64, bar: u32, baz: u32 } struct B { x: (), y: f32, bar: u32 } fn foo(a: A) { B { bar: a.$0 }; } "#, expect![[r#" fd foo [] fd bar [type+name] fd baz [type] "#]], ) } #[test] fn record_field_and_call_relevances() { check_relevance( r#" struct A { foo: i64, bar: u32, baz: u32 } struct B { x: (), y: f32, bar: u32 } fn f(foo: i64) { } fn foo(a: A) { B { bar: f(a.$0) }; } "#, expect![[r#" fd foo [type+name] fd bar [] fd baz [] "#]], ); check_relevance( r#" struct A { foo: i64, bar: u32, baz: u32 } struct B { x: (), y: f32, bar: u32 } fn f(foo: i64) { } fn foo(a: A) { f(B { bar: a.$0 }); } "#, expect![[r#" fd foo [] fd bar [type+name] fd baz [type] "#]], ); } #[test] fn prioritize_exact_ref_match() { check_relevance( r#" struct WorldSnapshot { _f: () }; fn go(world: &WorldSnapshot) { go(w$0) } "#, expect![[r#" lc world [type+name+local] st WorldSnapshot [] fn go(…) [] "#]], ); } #[test] fn too_many_arguments() { check_relevance( r#" struct Foo; fn f(foo: &Foo) { f(foo, w$0) } "#, expect![[r#" lc foo [local] st Foo [] fn f(…) [] "#]], ); } #[test] fn score_fn_type_and_name_match() { check_relevance( r#" struct A { bar: u8 } fn baz() -> u8 { 0 } fn bar() -> u8 { 0 } fn f() { A { bar: b$0 }; } "#, expect![[r#" fn baz() [type] st A [] fn bar() [type+name] fn f() [] "#]], ); } #[test] fn score_method_type_and_name_match() { check_relevance( r#" fn baz(aaa: u32){} struct Foo; impl Foo { fn aaa(&self) -> u32 { 0 } fn bbb(&self) -> u32 { 0 } fn ccc(&self) -> u64 { 0 } } fn f() { baz(Foo.$0 } "#, expect![[r#" me aaa() [type+name] me bbb() [type] me ccc() [] "#]], ); } #[test] fn score_method_name_match_only() { check_relevance( r#" fn baz(aaa: u32){} struct Foo; impl Foo { fn aaa(&self) -> u64 { 0 } } fn f() { baz(Foo.$0 } "#, expect![[r#" me aaa() [name] "#]], ); } #[test] fn suggest_ref_mut() { cov_mark::check!(suggest_ref); check( r#" struct S; fn foo(s: &mut S) {} fn main() { let mut s = S; foo($0); } "#, expect![[r#" [ CompletionItem { label: "S", source_range: 70..70, delete: 70..70, insert: "S", kind: SymbolKind( Struct, ), }, CompletionItem { label: "foo(…)", source_range: 70..70, delete: 70..70, insert: "foo(${1:&mut s})$0", kind: SymbolKind( Function, ), lookup: "foo", detail: "fn(&mut S)", trigger_call_info: true, }, CompletionItem { label: "main()", source_range: 70..70, delete: 70..70, insert: "main()$0", kind: SymbolKind( Function, ), lookup: "main", detail: "fn()", }, CompletionItem { label: "s", source_range: 70..70, delete: 70..70, insert: "s", kind: SymbolKind( Local, ), detail: "S", relevance: CompletionRelevance { exact_name_match: true, type_match: None, is_local: true, }, ref_match: "&mut ", }, ] "#]], ) } #[test] fn suggest_deref() { check_relevance( r#" #[lang = "deref"] trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct S; struct T(S); impl Deref for T { type Target = S; fn deref(&self) -> &Self::Target { &self.0 } } fn foo(s: &S) {} fn main() { let t = T(S); let m = 123; foo($0); } "#, expect![[r#" lc m [local] lc t [local] lc &t [type+local] st T [] st S [] fn main() [] tt Deref [] fn foo(…) [] "#]], ) } #[test] fn suggest_deref_mut() { check_relevance( r#" #[lang = "deref"] trait Deref { type Target; fn deref(&self) -> &Self::Target; } #[lang = "deref_mut"] pub trait DerefMut: Deref { fn deref_mut(&mut self) -> &mut Self::Target; } struct S; struct T(S); impl Deref for T { type Target = S; fn deref(&self) -> &Self::Target { &self.0 } } impl DerefMut for T { fn deref_mut(&mut self) -> &mut Self::Target { &mut self.0 } } fn foo(s: &mut S) {} fn main() { let t = T(S); let m = 123; foo($0); } "#, expect![[r#" lc m [local] lc t [local] lc &mut t [type+local] tt DerefMut [] tt Deref [] fn foo(…) [] st T [] st S [] fn main() [] "#]], ) } #[test] fn locals() { check_relevance( r#" fn foo(bar: u32) { let baz = 0; f$0 } "#, expect![[r#" lc baz [local] lc bar [local] fn foo(…) [] "#]], ); } #[test] fn enum_owned() { check_relevance( r#" enum Foo { A, B } fn foo() { bar($0); } fn bar(t: Foo) {} "#, expect![[r#" ev Foo::A [type] ev Foo::B [type] en Foo [] fn bar(…) [] fn foo() [] "#]], ); } #[test] fn enum_ref() { check_relevance( r#" enum Foo { A, B } fn foo() { bar($0); } fn bar(t: &Foo) {} "#, expect![[r#" ev Foo::A [] ev &Foo::A [type] ev Foo::B [] ev &Foo::B [type] en Foo [] fn bar(…) [] fn foo() [] "#]], ); } #[test] fn suggest_deref_fn_ret() { check_relevance( r#" #[lang = "deref"] trait Deref { type Target; fn deref(&self) -> &Self::Target; } struct S; struct T(S); impl Deref for T { type Target = S; fn deref(&self) -> &Self::Target { &self.0 } } fn foo(s: &S) {} fn bar() -> T {} fn main() { foo($0); } "#, expect![[r#" tt Deref [] fn bar() [] fn &bar() [type] fn foo(…) [] st T [] st S [] fn main() [] "#]], ) } #[test] fn struct_field_method_ref() { check( r#" struct Foo { bar: u32 } impl Foo { fn baz(&self) -> u32 { 0 } } fn foo(f: Foo) { let _: &u32 = f.b$0 } "#, // FIXME // Ideally we'd also suggest &f.bar and &f.baz() as exact // type matches. See #8058. expect![[r#" [ CompletionItem { label: "bar", source_range: 98..99, delete: 98..99, insert: "bar", kind: SymbolKind( Field, ), detail: "u32", }, CompletionItem { label: "baz()", source_range: 98..99, delete: 98..99, insert: "baz()$0", kind: Method, lookup: "baz", detail: "fn(&self) -> u32", }, ] "#]], ); } #[test] fn generic_enum() { check_relevance( r#" enum Foo { A(T), B } // bar() should not be an exact type match // because the generic parameters are different fn bar() -> Foo { Foo::B } // FIXME baz() should be an exact type match // because the types could unify, but it currently // is not. This is due to the T here being // TyKind::Placeholder rather than TyKind::Missing. fn baz() -> Foo { Foo::B } fn foo() { let foo: Foo = Foo::B; let _: Foo = f$0; } "#, expect![[r#" ev Foo::A(…) [type_could_unify] ev Foo::B [type_could_unify] lc foo [type+local] en Foo [] fn baz() [] fn bar() [] fn foo() [] "#]], ); } }