//! In certain situations, rust automatically inserts derefs as necessary: for //! example, field accesses `foo.bar` still work when `foo` is actually a //! reference to a type with the field `bar`. This is an approximation of the //! logic in rustc (which lives in rustc_hir_analysis/check/autoderef.rs). use std::sync::Arc; use chalk_ir::cast::Cast; use hir_def::lang_item::LangItem; use hir_expand::name::name; use limit::Limit; use crate::{ db::HirDatabase, infer::unify::InferenceTable, Canonical, Goal, Interner, ProjectionTyExt, TraitEnvironment, Ty, TyBuilder, TyKind, }; static AUTODEREF_RECURSION_LIMIT: Limit = Limit::new(10); pub(crate) enum AutoderefKind { Builtin, Overloaded, } pub(crate) struct Autoderef<'a, 'db> { pub(crate) table: &'a mut InferenceTable<'db>, ty: Ty, at_start: bool, steps: Vec<(AutoderefKind, Ty)>, } impl<'a, 'db> Autoderef<'a, 'db> { pub(crate) fn new(table: &'a mut InferenceTable<'db>, ty: Ty) -> Self { let ty = table.resolve_ty_shallow(&ty); Autoderef { table, ty, at_start: true, steps: Vec::new() } } pub(crate) fn step_count(&self) -> usize { self.steps.len() } pub(crate) fn steps(&self) -> &[(AutoderefKind, Ty)] { &self.steps } pub(crate) fn final_ty(&self) -> Ty { self.ty.clone() } } impl Iterator for Autoderef<'_, '_> { type Item = (Ty, usize); fn next(&mut self) -> Option { if self.at_start { self.at_start = false; return Some((self.ty.clone(), 0)); } if AUTODEREF_RECURSION_LIMIT.check(self.steps.len() + 1).is_err() { return None; } let (kind, new_ty) = autoderef_step(self.table, self.ty.clone())?; self.steps.push((kind, self.ty.clone())); self.ty = new_ty; Some((self.ty.clone(), self.step_count())) } } pub(crate) fn autoderef_step( table: &mut InferenceTable<'_>, ty: Ty, ) -> Option<(AutoderefKind, Ty)> { if let Some(derefed) = builtin_deref(&ty) { Some((AutoderefKind::Builtin, table.resolve_ty_shallow(derefed))) } else { Some((AutoderefKind::Overloaded, deref_by_trait(table, ty)?)) } } // FIXME: replace uses of this with Autoderef above pub fn autoderef( db: &dyn HirDatabase, env: Arc, ty: Canonical, ) -> impl Iterator> + '_ { let mut table = InferenceTable::new(db, env); let ty = table.instantiate_canonical(ty); let mut autoderef = Autoderef::new(&mut table, ty); let mut v = Vec::new(); while let Some((ty, _steps)) = autoderef.next() { v.push(autoderef.table.canonicalize(ty).value); } v.into_iter() } pub(crate) fn deref(table: &mut InferenceTable<'_>, ty: Ty) -> Option { let _p = profile::span("deref"); autoderef_step(table, ty).map(|(_, ty)| ty) } fn builtin_deref(ty: &Ty) -> Option<&Ty> { match ty.kind(Interner) { TyKind::Ref(.., ty) | TyKind::Raw(.., ty) => Some(ty), _ => None, } } fn deref_by_trait(table: &mut InferenceTable<'_>, ty: Ty) -> Option { let _p = profile::span("deref_by_trait"); if table.resolve_ty_shallow(&ty).inference_var(Interner).is_some() { // don't try to deref unknown variables return None; } let db = table.db; let deref_trait = db.lang_item(table.trait_env.krate, LangItem::Deref).and_then(|l| l.as_trait())?; let target = db.trait_data(deref_trait).associated_type_by_name(&name![Target])?; let projection = { let b = TyBuilder::subst_for_def(db, deref_trait, None); if b.remaining() != 1 { // the Target type + Deref trait should only have one generic parameter, // namely Deref's Self type return None; } let deref_subst = b.push(ty).build(); TyBuilder::assoc_type_projection(db, target, Some(deref_subst)).build() }; // Check that the type implements Deref at all let trait_ref = projection.trait_ref(db); let implements_goal: Goal = trait_ref.cast(Interner); table.try_obligation(implements_goal.clone())?; table.register_obligation(implements_goal); let result = table.normalize_projection_ty(projection); Some(table.resolve_ty_shallow(&result)) }