use std::sync::Arc; use ra_db::{CrateId, SourceRootId, Edition, FileId}; use ra_syntax::{ast::{self, NameOwner, TypeAscriptionOwner}, TreeArc}; use crate::{ Name, AsName, AstId, Ty, HirFileId, Either, KnownName, HirDatabase, DefDatabase, AstDatabase, type_ref::TypeRef, nameres::{ModuleScope, Namespace, ImportId, CrateModuleId}, expr::{Body, BodySourceMap, validation::ExprValidator}, ty::{TraitRef, InferenceResult, primitive::{IntTy, FloatTy, Signedness, IntBitness, FloatBitness}}, adt::{EnumVariantId, StructFieldId, VariantDef}, generics::HasGenericParams, ids::{FunctionId, StructId, EnumId, AstItemDef, ConstId, StaticId, TraitId, TypeAliasId, MacroDefId}, impl_block::ImplBlock, resolve::Resolver, diagnostics::{DiagnosticSink}, traits::{TraitItem, TraitData}, type_ref::Mutability, }; /// hir::Crate describes a single crate. It's the main interface with which /// a crate's dependencies interact. Mostly, it should be just a proxy for the /// root module. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Crate { pub(crate) crate_id: CrateId, } #[derive(Debug)] pub struct CrateDependency { pub krate: Crate, pub name: Name, } impl Crate { pub fn crate_id(self) -> CrateId { self.crate_id } pub fn dependencies(self, db: &impl DefDatabase) -> Vec { db.crate_graph() .dependencies(self.crate_id) .map(|dep| { let krate = Crate { crate_id: dep.crate_id() }; let name = dep.as_name(); CrateDependency { krate, name } }) .collect() } pub fn root_module(self, db: &impl DefDatabase) -> Option { let module_id = db.crate_def_map(self).root(); let module = Module { krate: self, module_id }; Some(module) } pub fn edition(self, db: &impl DefDatabase) -> Edition { let crate_graph = db.crate_graph(); crate_graph.edition(self.crate_id) } // FIXME: should this be in source_binder? pub fn source_root_crates(db: &impl DefDatabase, source_root: SourceRootId) -> Vec { let crate_ids = db.source_root_crates(source_root); crate_ids.iter().map(|&crate_id| Crate { crate_id }).collect() } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Module { pub(crate) krate: Crate, pub(crate) module_id: CrateModuleId, } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub enum BuiltinType { Char, Bool, Str, Int(IntTy), Float(FloatTy), } impl BuiltinType { #[rustfmt::skip] pub(crate) const ALL: &'static [(KnownName, BuiltinType)] = &[ (KnownName::Char, BuiltinType::Char), (KnownName::Bool, BuiltinType::Bool), (KnownName::Str, BuiltinType::Str), (KnownName::Isize, BuiltinType::Int(IntTy { signedness: Signedness::Signed, bitness: IntBitness::Xsize })), (KnownName::I8, BuiltinType::Int(IntTy { signedness: Signedness::Signed, bitness: IntBitness::X8 })), (KnownName::I16, BuiltinType::Int(IntTy { signedness: Signedness::Signed, bitness: IntBitness::X16 })), (KnownName::I32, BuiltinType::Int(IntTy { signedness: Signedness::Signed, bitness: IntBitness::X32 })), (KnownName::I64, BuiltinType::Int(IntTy { signedness: Signedness::Signed, bitness: IntBitness::X64 })), (KnownName::I128, BuiltinType::Int(IntTy { signedness: Signedness::Signed, bitness: IntBitness::X128 })), (KnownName::Usize, BuiltinType::Int(IntTy { signedness: Signedness::Unsigned, bitness: IntBitness::Xsize })), (KnownName::U8, BuiltinType::Int(IntTy { signedness: Signedness::Unsigned, bitness: IntBitness::X8 })), (KnownName::U16, BuiltinType::Int(IntTy { signedness: Signedness::Unsigned, bitness: IntBitness::X16 })), (KnownName::U32, BuiltinType::Int(IntTy { signedness: Signedness::Unsigned, bitness: IntBitness::X32 })), (KnownName::U64, BuiltinType::Int(IntTy { signedness: Signedness::Unsigned, bitness: IntBitness::X64 })), (KnownName::U128, BuiltinType::Int(IntTy { signedness: Signedness::Unsigned, bitness: IntBitness::X128 })), (KnownName::F32, BuiltinType::Float(FloatTy { bitness: FloatBitness::X32 })), (KnownName::F64, BuiltinType::Float(FloatTy { bitness: FloatBitness::X64 })), ]; } /// The defs which can be visible in the module. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub enum ModuleDef { Module(Module), Function(Function), Struct(Struct), Union(Union), Enum(Enum), // Can't be directly declared, but can be imported. EnumVariant(EnumVariant), Const(Const), Static(Static), Trait(Trait), TypeAlias(TypeAlias), BuiltinType(BuiltinType), } impl_froms!( ModuleDef: Module, Function, Struct, Union, Enum, EnumVariant, Const, Static, Trait, TypeAlias, BuiltinType ); pub enum ModuleSource { SourceFile(TreeArc), Module(TreeArc), } impl ModuleSource { pub(crate) fn new( db: &(impl DefDatabase + AstDatabase), file_id: Option, decl_id: Option>, ) -> ModuleSource { match (file_id, decl_id) { (Some(file_id), _) => { let source_file = db.parse(file_id).tree; ModuleSource::SourceFile(source_file) } (None, Some(item_id)) => { let module = item_id.to_node(db); assert!(module.item_list().is_some(), "expected inline module"); ModuleSource::Module(module.to_owned()) } (None, None) => panic!(), } } } impl Module { /// Name of this module. pub fn name(self, db: &impl DefDatabase) -> Option { let def_map = db.crate_def_map(self.krate); let parent = def_map[self.module_id].parent?; def_map[parent].children.iter().find_map(|(name, module_id)| { if *module_id == self.module_id { Some(name.clone()) } else { None } }) } /// Returns a node which defines this module. That is, a file or a `mod foo {}` with items. pub fn definition_source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, ModuleSource) { let def_map = db.crate_def_map(self.krate); let decl_id = def_map[self.module_id].declaration; let file_id = def_map[self.module_id].definition; let module_source = ModuleSource::new(db, file_id, decl_id); let file_id = file_id.map(HirFileId::from).unwrap_or_else(|| decl_id.unwrap().file_id()); (file_id, module_source) } /// Returns a node which declares this module, either a `mod foo;` or a `mod foo {}`. /// `None` for the crate root. pub fn declaration_source( self, db: &(impl DefDatabase + AstDatabase), ) -> Option<(HirFileId, TreeArc)> { let def_map = db.crate_def_map(self.krate); let decl = def_map[self.module_id].declaration?; let ast = decl.to_node(db); Some((decl.file_id(), ast)) } /// Returns the syntax of the last path segment corresponding to this import pub fn import_source( self, db: &impl HirDatabase, import: ImportId, ) -> Either, TreeArc> { let (file_id, source) = self.definition_source(db); let (_, source_map) = db.raw_items_with_source_map(file_id); source_map.get(&source, import) } /// Returns the crate this module is part of. pub fn krate(self, _db: &impl DefDatabase) -> Option { Some(self.krate) } /// Topmost parent of this module. Every module has a `crate_root`, but some /// might be missing `krate`. This can happen if a module's file is not included /// in the module tree of any target in `Cargo.toml`. pub fn crate_root(self, db: &impl DefDatabase) -> Module { let def_map = db.crate_def_map(self.krate); self.with_module_id(def_map.root()) } /// Finds a child module with the specified name. pub fn child(self, db: &impl HirDatabase, name: &Name) -> Option { let def_map = db.crate_def_map(self.krate); let child_id = def_map[self.module_id].children.get(name)?; Some(self.with_module_id(*child_id)) } /// Iterates over all child modules. pub fn children(self, db: &impl DefDatabase) -> impl Iterator { let def_map = db.crate_def_map(self.krate); let children = def_map[self.module_id] .children .iter() .map(|(_, module_id)| self.with_module_id(*module_id)) .collect::>(); children.into_iter() } /// Finds a parent module. pub fn parent(self, db: &impl DefDatabase) -> Option { let def_map = db.crate_def_map(self.krate); let parent_id = def_map[self.module_id].parent?; Some(self.with_module_id(parent_id)) } pub fn path_to_root(self, db: &impl HirDatabase) -> Vec { let mut res = vec![self.clone()]; let mut curr = self.clone(); while let Some(next) = curr.parent(db) { res.push(next.clone()); curr = next } res } /// Returns a `ModuleScope`: a set of items, visible in this module. pub fn scope(self, db: &impl HirDatabase) -> ModuleScope { db.crate_def_map(self.krate)[self.module_id].scope.clone() } pub fn diagnostics(self, db: &impl HirDatabase, sink: &mut DiagnosticSink) { db.crate_def_map(self.krate).add_diagnostics(db, self.module_id, sink); for decl in self.declarations(db) { match decl { crate::ModuleDef::Function(f) => f.diagnostics(db, sink), crate::ModuleDef::Module(f) => f.diagnostics(db, sink), _ => (), } } for impl_block in self.impl_blocks(db) { for item in impl_block.items(db) { if let crate::ImplItem::Method(f) = item { f.diagnostics(db, sink); } } } } pub(crate) fn resolver(self, db: &impl DefDatabase) -> Resolver { let def_map = db.crate_def_map(self.krate); Resolver::default().push_module_scope(def_map, self.module_id) } pub fn declarations(self, db: &impl DefDatabase) -> Vec { let def_map = db.crate_def_map(self.krate); def_map[self.module_id] .scope .entries() .filter_map(|(_name, res)| if res.import.is_none() { Some(res.def) } else { None }) .flat_map(|per_ns| { per_ns.take_types().into_iter().chain(per_ns.take_values().into_iter()) }) .collect() } pub fn impl_blocks(self, db: &impl HirDatabase) -> Vec { let module_impl_blocks = db.impls_in_module(self); module_impl_blocks .impls .iter() .map(|(impl_id, _)| ImplBlock::from_id(self, impl_id)) .collect() } fn with_module_id(&self, module_id: CrateModuleId) -> Module { Module { module_id, krate: self.krate } } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct StructField { pub(crate) parent: VariantDef, pub(crate) id: StructFieldId, } #[derive(Debug)] pub enum FieldSource { Named(TreeArc), Pos(TreeArc), } impl StructField { pub fn name(&self, db: &impl HirDatabase) -> Name { self.parent.variant_data(db).fields().unwrap()[self.id].name.clone() } pub fn source(&self, db: &(impl DefDatabase + AstDatabase)) -> (HirFileId, FieldSource) { self.source_impl(db) } pub fn ty(&self, db: &impl HirDatabase) -> Ty { db.type_for_field(*self) } pub fn parent_def(&self, _db: &impl HirDatabase) -> VariantDef { self.parent } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Struct { pub(crate) id: StructId, } impl Struct { pub fn source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn module(self, db: &impl HirDatabase) -> Module { self.id.module(db) } pub fn name(self, db: &impl DefDatabase) -> Option { db.struct_data(self).name.clone() } pub fn fields(self, db: &impl HirDatabase) -> Vec { db.struct_data(self) .variant_data .fields() .into_iter() .flat_map(|it| it.iter()) .map(|(id, _)| StructField { parent: self.into(), id }) .collect() } pub fn field(self, db: &impl HirDatabase, name: &Name) -> Option { db.struct_data(self) .variant_data .fields() .into_iter() .flat_map(|it| it.iter()) .find(|(_id, data)| data.name == *name) .map(|(id, _)| StructField { parent: self.into(), id }) } pub fn ty(self, db: &impl HirDatabase) -> Ty { db.type_for_def(self.into(), Namespace::Types) } pub fn constructor_ty(self, db: &impl HirDatabase) -> Ty { db.type_for_def(self.into(), Namespace::Values) } // FIXME move to a more general type /// Builds a resolver for type references inside this struct. pub(crate) fn resolver(self, db: &impl HirDatabase) -> Resolver { // take the outer scope... let r = self.module(db).resolver(db); // ...and add generic params, if present let p = self.generic_params(db); let r = if !p.params.is_empty() { r.push_generic_params_scope(p) } else { r }; r } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Union { pub(crate) id: StructId, } impl Union { pub fn source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn name(self, db: &impl DefDatabase) -> Option { db.struct_data(Struct { id: self.id }).name.clone() } pub fn module(self, db: &impl HirDatabase) -> Module { self.id.module(db) } // FIXME move to a more general type /// Builds a resolver for type references inside this union. pub(crate) fn resolver(self, db: &impl HirDatabase) -> Resolver { // take the outer scope... let r = self.module(db).resolver(db); // ...and add generic params, if present let p = self.generic_params(db); let r = if !p.params.is_empty() { r.push_generic_params_scope(p) } else { r }; r } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Enum { pub(crate) id: EnumId, } impl Enum { pub fn source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn module(self, db: &impl HirDatabase) -> Module { self.id.module(db) } pub fn name(self, db: &impl DefDatabase) -> Option { db.enum_data(self).name.clone() } pub fn variants(self, db: &impl DefDatabase) -> Vec { db.enum_data(self).variants.iter().map(|(id, _)| EnumVariant { parent: self, id }).collect() } pub fn variant(self, db: &impl DefDatabase, name: &Name) -> Option { db.enum_data(self) .variants .iter() .find(|(_id, data)| data.name.as_ref() == Some(name)) .map(|(id, _)| EnumVariant { parent: self, id }) } pub fn ty(self, db: &impl HirDatabase) -> Ty { db.type_for_def(self.into(), Namespace::Types) } // FIXME: move to a more general type /// Builds a resolver for type references inside this struct. pub(crate) fn resolver(self, db: &impl HirDatabase) -> Resolver { // take the outer scope... let r = self.module(db).resolver(db); // ...and add generic params, if present let p = self.generic_params(db); let r = if !p.params.is_empty() { r.push_generic_params_scope(p) } else { r }; r } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct EnumVariant { pub(crate) parent: Enum, pub(crate) id: EnumVariantId, } impl EnumVariant { pub fn source( &self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.source_impl(db) } pub fn module(&self, db: &impl HirDatabase) -> Module { self.parent.module(db) } pub fn parent_enum(&self, _db: &impl DefDatabase) -> Enum { self.parent } pub fn name(&self, db: &impl DefDatabase) -> Option { db.enum_data(self.parent).variants[self.id].name.clone() } pub fn fields(&self, db: &impl HirDatabase) -> Vec { self.variant_data(db) .fields() .into_iter() .flat_map(|it| it.iter()) .map(|(id, _)| StructField { parent: (*self).into(), id }) .collect() } pub fn field(&self, db: &impl HirDatabase, name: &Name) -> Option { self.variant_data(db) .fields() .into_iter() .flat_map(|it| it.iter()) .find(|(_id, data)| data.name == *name) .map(|(id, _)| StructField { parent: (*self).into(), id }) } } /// The defs which have a body. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub enum DefWithBody { Function(Function), Static(Static), Const(Const), } impl_froms!(DefWithBody: Function, Const, Static); impl DefWithBody { pub fn infer(self, db: &impl HirDatabase) -> Arc { db.infer(self) } pub fn body(self, db: &impl HirDatabase) -> Arc { db.body_hir(self) } pub fn body_source_map(self, db: &impl HirDatabase) -> Arc { db.body_with_source_map(self).1 } /// Builds a resolver for code inside this item. pub(crate) fn resolver(&self, db: &impl HirDatabase) -> Resolver { match *self { DefWithBody::Const(ref c) => c.resolver(db), DefWithBody::Function(ref f) => f.resolver(db), DefWithBody::Static(ref s) => s.resolver(db), } } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Function { pub(crate) id: FunctionId, } /// The declared signature of a function. #[derive(Debug, Clone, PartialEq, Eq)] pub struct FnSignature { pub(crate) name: Name, pub(crate) params: Vec, pub(crate) ret_type: TypeRef, /// True if the first param is `self`. This is relevant to decide whether this /// can be called as a method. pub(crate) has_self_param: bool, } impl FnSignature { pub(crate) fn fn_signature_query( db: &(impl DefDatabase + AstDatabase), func: Function, ) -> Arc { let (_, node) = func.source(db); let name = node.name().map(|n| n.as_name()).unwrap_or_else(Name::missing); let mut params = Vec::new(); let mut has_self_param = false; if let Some(param_list) = node.param_list() { if let Some(self_param) = param_list.self_param() { let self_type = if let Some(type_ref) = self_param.ascribed_type() { TypeRef::from_ast(type_ref) } else { let self_type = TypeRef::Path(Name::self_type().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(param.ascribed_type()); params.push(type_ref); } } let ret_type = if let Some(type_ref) = node.ret_type().and_then(|rt| rt.type_ref()) { TypeRef::from_ast(type_ref) } else { TypeRef::unit() }; let sig = FnSignature { name, params, ret_type, has_self_param }; Arc::new(sig) } pub fn name(&self) -> &Name { &self.name } pub fn params(&self) -> &[TypeRef] { &self.params } pub fn ret_type(&self) -> &TypeRef { &self.ret_type } /// True if the first arg is `self`. This is relevant to decide whether this /// can be called as a method. pub fn has_self_param(&self) -> bool { self.has_self_param } } impl Function { pub fn source(self, db: &(impl DefDatabase + AstDatabase)) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn module(self, db: &impl DefDatabase) -> Module { self.id.module(db) } pub fn name(self, db: &impl HirDatabase) -> Name { self.signature(db).name.clone() } pub(crate) fn body_source_map(self, db: &impl HirDatabase) -> Arc { db.body_with_source_map(self.into()).1 } pub fn body(self, db: &impl HirDatabase) -> Arc { db.body_hir(self.into()) } pub fn ty(self, db: &impl HirDatabase) -> Ty { db.type_for_def(self.into(), Namespace::Values) } pub fn signature(self, db: &impl HirDatabase) -> Arc { db.fn_signature(self) } pub fn infer(self, db: &impl HirDatabase) -> Arc { db.infer(self.into()) } /// The containing impl block, if this is a method. pub fn impl_block(self, db: &impl DefDatabase) -> Option { let module_impls = db.impls_in_module(self.module(db)); ImplBlock::containing(module_impls, self.into()) } /// The containing trait, if this is a trait method definition. pub fn parent_trait(self, db: &impl DefDatabase) -> Option { db.trait_items_index(self.module(db)).get_parent_trait(self.into()) } pub fn container(self, db: &impl DefDatabase) -> Option { if let Some(impl_block) = self.impl_block(db) { Some(impl_block.into()) } else if let Some(trait_) = self.parent_trait(db) { Some(trait_.into()) } else { None } } // FIXME: move to a more general type for 'body-having' items /// Builds a resolver for code inside this item. pub(crate) fn resolver(self, db: &impl HirDatabase) -> Resolver { // take the outer scope... let r = self.container(db).map_or_else(|| self.module(db).resolver(db), |c| c.resolver(db)); // ...and add generic params, if present let p = self.generic_params(db); let r = if !p.params.is_empty() { r.push_generic_params_scope(p) } else { r }; r } pub fn diagnostics(self, db: &impl HirDatabase, sink: &mut DiagnosticSink) { let infer = self.infer(db); infer.add_diagnostics(db, self, sink); let mut validator = ExprValidator::new(self, infer, sink); validator.validate_body(db); } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Const { pub(crate) id: ConstId, } impl Const { pub fn source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn module(self, db: &impl DefDatabase) -> Module { self.id.module(db) } pub fn signature(self, db: &impl HirDatabase) -> Arc { db.const_signature(self) } pub fn infer(self, db: &impl HirDatabase) -> Arc { db.infer(self.into()) } /// The containing impl block, if this is a method. pub fn impl_block(self, db: &impl DefDatabase) -> Option { let module_impls = db.impls_in_module(self.module(db)); ImplBlock::containing(module_impls, self.into()) } // FIXME: move to a more general type for 'body-having' items /// Builds a resolver for code inside this item. pub(crate) fn resolver(self, db: &impl HirDatabase) -> Resolver { // take the outer scope... let r = self .impl_block(db) .map(|ib| ib.resolver(db)) .unwrap_or_else(|| self.module(db).resolver(db)); r } } /// The declared signature of a const. #[derive(Debug, Clone, PartialEq, Eq)] pub struct ConstSignature { pub(crate) name: Name, pub(crate) type_ref: TypeRef, } impl ConstSignature { pub fn name(&self) -> &Name { &self.name } pub fn type_ref(&self) -> &TypeRef { &self.type_ref } pub(crate) fn const_signature_query( db: &(impl DefDatabase + AstDatabase), konst: Const, ) -> Arc { let (_, node) = konst.source(db); const_signature_for(&*node) } pub(crate) fn static_signature_query( db: &(impl DefDatabase + AstDatabase), konst: Static, ) -> Arc { let (_, node) = konst.source(db); const_signature_for(&*node) } } fn const_signature_for(node: &N) -> Arc { let name = node.name().map(|n| n.as_name()).unwrap_or_else(Name::missing); let type_ref = TypeRef::from_ast_opt(node.ascribed_type()); let sig = ConstSignature { name, type_ref }; Arc::new(sig) } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Static { pub(crate) id: StaticId, } impl Static { pub fn source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn module(self, db: &impl DefDatabase) -> Module { self.id.module(db) } pub fn signature(self, db: &impl HirDatabase) -> Arc { db.static_signature(self) } /// Builds a resolver for code inside this item. pub(crate) fn resolver(self, db: &impl HirDatabase) -> Resolver { // take the outer scope... self.module(db).resolver(db) } pub fn infer(self, db: &impl HirDatabase) -> Arc { db.infer(self.into()) } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Trait { pub(crate) id: TraitId, } impl Trait { pub fn source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn module(self, db: &impl DefDatabase) -> Module { self.id.module(db) } pub fn name(self, db: &impl DefDatabase) -> Option { self.trait_data(db).name().clone() } pub fn items(self, db: &impl DefDatabase) -> Vec { self.trait_data(db).items().to_vec() } pub(crate) fn trait_data(self, db: &impl DefDatabase) -> Arc { db.trait_data(self) } pub fn trait_ref(self, db: &impl HirDatabase) -> TraitRef { TraitRef::for_trait(db, self) } pub fn is_auto(self, db: &impl DefDatabase) -> bool { self.trait_data(db).is_auto() } pub(crate) fn resolver(self, db: &impl DefDatabase) -> Resolver { let r = self.module(db).resolver(db); // add generic params, if present let p = self.generic_params(db); let r = if !p.params.is_empty() { r.push_generic_params_scope(p) } else { r }; r } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct TypeAlias { pub(crate) id: TypeAliasId, } impl TypeAlias { pub fn source( self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { self.id.source(db) } pub fn module(self, db: &impl DefDatabase) -> Module { self.id.module(db) } /// The containing impl block, if this is a method. pub fn impl_block(self, db: &impl DefDatabase) -> Option { let module_impls = db.impls_in_module(self.module(db)); ImplBlock::containing(module_impls, self.into()) } /// The containing trait, if this is a trait method definition. pub fn parent_trait(self, db: &impl DefDatabase) -> Option { db.trait_items_index(self.module(db)).get_parent_trait(self.into()) } pub fn container(self, db: &impl DefDatabase) -> Option { if let Some(impl_block) = self.impl_block(db) { Some(impl_block.into()) } else if let Some(trait_) = self.parent_trait(db) { Some(trait_.into()) } else { None } } pub fn type_ref(self, db: &impl DefDatabase) -> Arc { db.type_alias_ref(self) } /// Builds a resolver for the type references in this type alias. pub(crate) fn resolver(self, db: &impl HirDatabase) -> Resolver { // take the outer scope... let r = self .impl_block(db) .map(|ib| ib.resolver(db)) .unwrap_or_else(|| self.module(db).resolver(db)); // ...and add generic params, if present let p = self.generic_params(db); let r = if !p.params.is_empty() { r.push_generic_params_scope(p) } else { r }; r } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct MacroDef { pub(crate) id: MacroDefId, } impl MacroDef { pub fn source( &self, db: &(impl DefDatabase + AstDatabase), ) -> (HirFileId, TreeArc) { (self.id.0.file_id(), self.id.0.to_node(db)) } } pub enum Container { Trait(Trait), ImplBlock(ImplBlock), } impl_froms!(Container: Trait, ImplBlock); impl Container { pub(crate) fn resolver(self, db: &impl DefDatabase) -> Resolver { match self { Container::Trait(trait_) => trait_.resolver(db), Container::ImplBlock(impl_block) => impl_block.resolver(db), } } }