//! 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 librustc_typeck/check/autoderef.rs). use std::iter::successors; use hir_def::lang_item::LangItemTarget; use hir_expand::name; use log::{info, warn}; use ra_db::CrateId; use crate::{db::HirDatabase, Trait}; use super::{ traits::{InEnvironment, Solution}, Canonical, Substs, Ty, TypeWalk, }; const AUTODEREF_RECURSION_LIMIT: usize = 10; pub(crate) fn autoderef<'a>( db: &'a impl HirDatabase, krate: Option, ty: InEnvironment>, ) -> impl Iterator> + 'a { let InEnvironment { value: ty, environment } = ty; successors(Some(ty), move |ty| { deref(db, krate?, InEnvironment { value: ty, environment: environment.clone() }) }) .take(AUTODEREF_RECURSION_LIMIT) } pub(crate) fn deref( db: &impl HirDatabase, krate: CrateId, ty: InEnvironment<&Canonical>, ) -> Option> { if let Some(derefed) = ty.value.value.builtin_deref() { Some(Canonical { value: derefed, num_vars: ty.value.num_vars }) } else { deref_by_trait(db, krate, ty) } } fn deref_by_trait( db: &impl HirDatabase, krate: CrateId, ty: InEnvironment<&Canonical>, ) -> Option> { let deref_trait = match db.lang_item(krate.into(), "deref".into())? { LangItemTarget::TraitId(t) => Trait::from(t), _ => return None, }; let target = deref_trait.associated_type_by_name(db, &name::TARGET_TYPE)?; let generic_params = db.generic_params(target.id.into()); if generic_params.count_params_including_parent() != 1 { // the Target type + Deref trait should only have one generic parameter, // namely Deref's Self type return None; } // FIXME make the Canonical handling nicer let parameters = Substs::build_for_generics(&generic_params) .push(ty.value.value.clone().shift_bound_vars(1)) .build(); let projection = super::traits::ProjectionPredicate { ty: Ty::Bound(0), projection_ty: super::ProjectionTy { associated_ty: target, parameters }, }; let obligation = super::Obligation::Projection(projection); let in_env = InEnvironment { value: obligation, environment: ty.environment }; let canonical = super::Canonical { num_vars: 1 + ty.value.num_vars, value: in_env }; let solution = db.trait_solve(krate.into(), canonical)?; match &solution { Solution::Unique(vars) => { // FIXME: vars may contain solutions for any inference variables // that happened to be inside ty. To correctly handle these, we // would have to pass the solution up to the inference context, but // that requires a larger refactoring (especially if the deref // happens during method resolution). So for the moment, we just // check that we're not in the situation we're we would actually // need to handle the values of the additional variables, i.e. // they're just being 'passed through'. In the 'standard' case where // we have `impl Deref for Foo { Target = T }`, that should be // the case. for i in 1..vars.0.num_vars { if vars.0.value[i] != Ty::Bound((i - 1) as u32) { warn!("complex solution for derefing {:?}: {:?}, ignoring", ty.value, solution); return None; } } Some(Canonical { value: vars.0.value[0].clone(), num_vars: vars.0.num_vars }) } Solution::Ambig(_) => { info!("Ambiguous solution for derefing {:?}: {:?}", ty.value, solution); None } } }