//! Contains basic data about various HIR declarations. use std::sync::Arc; use hir_expand::{name::Name, InFile}; use syntax::ast; use crate::{ attr::Attrs, body::Expander, db::DefDatabase, item_tree::{AssocItem, FunctionQualifier, ItemTreeId, ModItem, Param}, type_ref::{TypeBound, TypeRef}, visibility::RawVisibility, AssocContainerId, AssocItemId, ConstId, ConstLoc, FunctionId, FunctionLoc, HasModule, ImplId, Intern, Lookup, ModuleId, StaticId, TraitId, TypeAliasId, TypeAliasLoc, }; #[derive(Debug, Clone, PartialEq, Eq)] pub struct FunctionData { pub name: Name, pub params: Vec, pub ret_type: TypeRef, pub attrs: Attrs, /// True if the first param is `self`. This is relevant to decide whether this /// can be called as a method. pub has_self_param: bool, pub has_body: bool, pub qualifier: FunctionQualifier, pub is_in_extern_block: bool, pub is_varargs: bool, pub visibility: RawVisibility, } impl FunctionData { pub(crate) fn fn_data_query(db: &dyn DefDatabase, func: FunctionId) -> Arc { let loc = func.lookup(db); let krate = loc.container.module(db).krate; let crate_graph = db.crate_graph(); let cfg_options = &crate_graph[krate].cfg_options; let item_tree = loc.id.item_tree(db); let func = &item_tree[loc.id.value]; let enabled_params = func .params .clone() .filter(|¶m| item_tree.attrs(db, krate, param.into()).is_cfg_enabled(cfg_options)); // If last cfg-enabled param is a `...` param, it's a varargs function. let is_varargs = enabled_params .clone() .next_back() .map_or(false, |param| matches!(item_tree[param], Param::Varargs)); Arc::new(FunctionData { name: func.name.clone(), params: enabled_params .clone() .filter_map(|id| match &item_tree[id] { Param::Normal(ty) => Some(item_tree[*ty].clone()), Param::Varargs => None, }) .collect(), ret_type: item_tree[func.ret_type].clone(), attrs: item_tree.attrs(db, krate, ModItem::from(loc.id.value).into()), has_self_param: func.has_self_param, has_body: func.has_body, qualifier: func.qualifier.clone(), is_in_extern_block: func.is_in_extern_block, is_varargs, visibility: item_tree[func.visibility].clone(), }) } } #[derive(Debug, Clone, PartialEq, Eq)] pub struct TypeAliasData { pub name: Name, pub type_ref: Option, pub visibility: RawVisibility, pub is_extern: bool, /// Bounds restricting the type alias itself (eg. `type Ty: Bound;` in a trait or impl). pub bounds: Vec, } impl TypeAliasData { pub(crate) fn type_alias_data_query( db: &dyn DefDatabase, typ: TypeAliasId, ) -> Arc { let loc = typ.lookup(db); let item_tree = loc.id.item_tree(db); let typ = &item_tree[loc.id.value]; Arc::new(TypeAliasData { name: typ.name.clone(), type_ref: typ.type_ref.map(|id| item_tree[id].clone()), visibility: item_tree[typ.visibility].clone(), is_extern: typ.is_extern, bounds: typ.bounds.to_vec(), }) } } #[derive(Debug, Clone, PartialEq, Eq)] pub struct TraitData { pub name: Name, pub items: Vec<(Name, AssocItemId)>, pub is_auto: bool, pub is_unsafe: bool, pub visibility: RawVisibility, pub bounds: Box<[TypeBound]>, } impl TraitData { pub(crate) fn trait_data_query(db: &dyn DefDatabase, tr: TraitId) -> Arc { let tr_loc = tr.lookup(db); let item_tree = tr_loc.id.item_tree(db); let tr_def = &item_tree[tr_loc.id.value]; let name = tr_def.name.clone(); let is_auto = tr_def.is_auto; let is_unsafe = tr_def.is_unsafe; let module_id = tr_loc.container; let container = AssocContainerId::TraitId(tr); let visibility = item_tree[tr_def.visibility].clone(); let bounds = tr_def.bounds.clone(); let mut expander = Expander::new(db, tr_loc.id.file_id(), module_id); let items = collect_items( db, module_id, &mut expander, tr_def.items.iter().copied(), tr_loc.id.file_id(), container, 100, ); Arc::new(TraitData { name, items, is_auto, is_unsafe, visibility, bounds }) } pub fn associated_types(&self) -> impl Iterator + '_ { self.items.iter().filter_map(|(_name, item)| match item { AssocItemId::TypeAliasId(t) => Some(*t), _ => None, }) } pub fn associated_type_by_name(&self, name: &Name) -> Option { self.items.iter().find_map(|(item_name, item)| match item { AssocItemId::TypeAliasId(t) if item_name == name => Some(*t), _ => None, }) } } #[derive(Debug, Clone, PartialEq, Eq)] pub struct ImplData { pub target_trait: Option, pub target_type: TypeRef, pub items: Vec, pub is_negative: bool, } impl ImplData { pub(crate) fn impl_data_query(db: &dyn DefDatabase, id: ImplId) -> Arc { let _p = profile::span("impl_data_query"); let impl_loc = id.lookup(db); let item_tree = impl_loc.id.item_tree(db); let impl_def = &item_tree[impl_loc.id.value]; let target_trait = impl_def.target_trait.map(|id| item_tree[id].clone()); let target_type = item_tree[impl_def.target_type].clone(); let is_negative = impl_def.is_negative; let module_id = impl_loc.container; let container = AssocContainerId::ImplId(id); let mut expander = Expander::new(db, impl_loc.id.file_id(), module_id); let items = collect_items( db, module_id, &mut expander, impl_def.items.iter().copied(), impl_loc.id.file_id(), container, 100, ); let items = items.into_iter().map(|(_, item)| item).collect(); Arc::new(ImplData { target_trait, target_type, items, is_negative }) } } #[derive(Debug, Clone, PartialEq, Eq)] pub struct ConstData { /// const _: () = (); pub name: Option, pub type_ref: TypeRef, pub visibility: RawVisibility, } impl ConstData { pub(crate) fn const_data_query(db: &dyn DefDatabase, konst: ConstId) -> Arc { let loc = konst.lookup(db); let item_tree = loc.id.item_tree(db); let konst = &item_tree[loc.id.value]; Arc::new(ConstData { name: konst.name.clone(), type_ref: item_tree[konst.type_ref].clone(), visibility: item_tree[konst.visibility].clone(), }) } } #[derive(Debug, Clone, PartialEq, Eq)] pub struct StaticData { pub name: Option, pub type_ref: TypeRef, pub visibility: RawVisibility, pub mutable: bool, pub is_extern: bool, } impl StaticData { pub(crate) fn static_data_query(db: &dyn DefDatabase, konst: StaticId) -> Arc { let node = konst.lookup(db); let item_tree = node.id.item_tree(db); let statik = &item_tree[node.id.value]; Arc::new(StaticData { name: Some(statik.name.clone()), type_ref: item_tree[statik.type_ref].clone(), visibility: item_tree[statik.visibility].clone(), mutable: statik.mutable, is_extern: statik.is_extern, }) } } fn collect_items( db: &dyn DefDatabase, module: ModuleId, expander: &mut Expander, assoc_items: impl Iterator, file_id: crate::HirFileId, container: AssocContainerId, limit: usize, ) -> Vec<(Name, AssocItemId)> { if limit == 0 { return Vec::new(); } let item_tree = db.item_tree(file_id); let crate_graph = db.crate_graph(); let cfg_options = &crate_graph[module.krate].cfg_options; let mut items = Vec::new(); for item in assoc_items { let attrs = item_tree.attrs(db, module.krate, ModItem::from(item).into()); if !attrs.is_cfg_enabled(cfg_options) { continue; } match item { AssocItem::Function(id) => { let item = &item_tree[id]; let def = FunctionLoc { container, id: ItemTreeId::new(file_id, id) }.intern(db); items.push((item.name.clone(), def.into())); } AssocItem::Const(id) => { let item = &item_tree[id]; let name = match item.name.clone() { Some(name) => name, None => continue, }; let def = ConstLoc { container, id: ItemTreeId::new(file_id, id) }.intern(db); items.push((name, def.into())); } AssocItem::TypeAlias(id) => { let item = &item_tree[id]; let def = TypeAliasLoc { container, id: ItemTreeId::new(file_id, id) }.intern(db); items.push((item.name.clone(), def.into())); } AssocItem::MacroCall(call) => { let call = &item_tree[call]; let ast_id_map = db.ast_id_map(file_id); let root = db.parse_or_expand(file_id).unwrap(); let call = ast_id_map.get(call.ast_id).to_node(&root); let res = expander.enter_expand(db, call); if let Ok(res) = res { if let Some((mark, mac)) = res.value { let src: InFile = expander.to_source(mac); let item_tree = db.item_tree(src.file_id); let iter = item_tree.top_level_items().iter().filter_map(ModItem::as_assoc_item); items.extend(collect_items( db, module, expander, iter, src.file_id, container, limit - 1, )); expander.exit(db, mark); } } } } } items }