//! HIR for references to types. Paths in these are not yet resolved. They can //! be directly created from an ast::TypeRef, without further queries. use ra_syntax::ast::{self, TypeAscriptionOwner, TypeBoundsOwner}; use crate::path::Path; #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug)] pub enum Mutability { Shared, Mut, } impl Mutability { pub fn from_mutable(mutable: bool) -> Mutability { if mutable { Mutability::Mut } else { Mutability::Shared } } pub fn as_keyword_for_ref(self) -> &'static str { match self { Mutability::Shared => "", Mutability::Mut => "mut ", } } pub fn as_keyword_for_ptr(self) -> &'static str { match self { Mutability::Shared => "const ", Mutability::Mut => "mut ", } } } /// Compare ty::Ty #[derive(Clone, PartialEq, Eq, Hash, Debug)] pub enum TypeRef { Never, Placeholder, Tuple(Vec), Path(Path), RawPtr(Box, Mutability), Reference(Box, Mutability), Array(Box /*, Expr*/), Slice(Box), /// A fn pointer. Last element of the vector is the return type. Fn(Vec), // For ImplTrait(Vec), DynTrait(Vec), Error, } #[derive(Clone, PartialEq, Eq, Hash, Debug)] pub enum TypeBound { Path(Path), // also for<> bounds // also Lifetimes Error, } impl TypeRef { /// Converts an `ast::TypeRef` to a `hir::TypeRef`. pub fn from_ast(node: ast::TypeRef) -> Self { match node { ast::TypeRef::ParenType(inner) => TypeRef::from_ast_opt(inner.type_ref()), ast::TypeRef::TupleType(inner) => { TypeRef::Tuple(inner.fields().map(TypeRef::from_ast).collect()) } ast::TypeRef::NeverType(..) => TypeRef::Never, ast::TypeRef::PathType(inner) => { // FIXME: Use `Path::from_src` inner.path().and_then(Path::from_ast).map(TypeRef::Path).unwrap_or(TypeRef::Error) } ast::TypeRef::PointerType(inner) => { let inner_ty = TypeRef::from_ast_opt(inner.type_ref()); let mutability = Mutability::from_mutable(inner.is_mut()); TypeRef::RawPtr(Box::new(inner_ty), mutability) } ast::TypeRef::ArrayType(inner) => { TypeRef::Array(Box::new(TypeRef::from_ast_opt(inner.type_ref()))) } ast::TypeRef::SliceType(inner) => { TypeRef::Slice(Box::new(TypeRef::from_ast_opt(inner.type_ref()))) } ast::TypeRef::ReferenceType(inner) => { let inner_ty = TypeRef::from_ast_opt(inner.type_ref()); let mutability = Mutability::from_mutable(inner.is_mut()); TypeRef::Reference(Box::new(inner_ty), mutability) } ast::TypeRef::PlaceholderType(_inner) => TypeRef::Placeholder, ast::TypeRef::FnPointerType(inner) => { let ret_ty = TypeRef::from_ast_opt(inner.ret_type().and_then(|rt| rt.type_ref())); let mut params = if let Some(pl) = inner.param_list() { pl.params().map(|p| p.ascribed_type()).map(TypeRef::from_ast_opt).collect() } else { Vec::new() }; params.push(ret_ty); TypeRef::Fn(params) } // for types are close enough for our purposes to the inner type for now... ast::TypeRef::ForType(inner) => TypeRef::from_ast_opt(inner.type_ref()), ast::TypeRef::ImplTraitType(inner) => { TypeRef::ImplTrait(type_bounds_from_ast(inner.type_bound_list())) } ast::TypeRef::DynTraitType(inner) => { TypeRef::DynTrait(type_bounds_from_ast(inner.type_bound_list())) } } } pub fn from_ast_opt(node: Option) -> Self { if let Some(node) = node { TypeRef::from_ast(node) } else { TypeRef::Error } } pub fn unit() -> TypeRef { TypeRef::Tuple(Vec::new()) } } pub(crate) fn type_bounds_from_ast(type_bounds_opt: Option) -> Vec { if let Some(type_bounds) = type_bounds_opt { type_bounds.bounds().map(TypeBound::from_ast).collect() } else { vec![] } } impl TypeBound { pub fn from_ast(node: ast::TypeBound) -> Self { match node.kind() { ast::TypeBoundKind::PathType(path_type) => { let path = match path_type.path() { Some(p) => p, None => return TypeBound::Error, }; // FIXME: Use `Path::from_src` let path = match Path::from_ast(path) { Some(p) => p, None => return TypeBound::Error, }; TypeBound::Path(path) } ast::TypeBoundKind::ForType(_) | ast::TypeBoundKind::Lifetime(_) => TypeBound::Error, } } pub fn as_path(&self) -> Option<&Path> { match self { TypeBound::Path(p) => Some(p), _ => None, } } }