use rustc_middle::infer::unify_key::ConstVidKey; use rustc_middle::ty::fold::{TypeFoldable, TypeFolder, TypeSuperFoldable}; use rustc_middle::ty::{self, ConstVid, FloatVid, IntVid, RegionVid, Ty, TyCtxt, TyVid}; use super::type_variable::TypeVariableOrigin; use super::InferCtxt; use super::{ConstVariableOrigin, RegionVariableOrigin, UnificationTable}; use rustc_data_structures::snapshot_vec as sv; use rustc_data_structures::unify as ut; use ut::UnifyKey; use std::ops::Range; fn vars_since_snapshot<'tcx, T>( table: &mut UnificationTable<'_, 'tcx, T>, snapshot_var_len: usize, ) -> Range where T: UnifyKey, super::UndoLog<'tcx>: From>>, { T::from_index(snapshot_var_len as u32)..T::from_index(table.len() as u32) } fn const_vars_since_snapshot<'tcx>( table: &mut UnificationTable<'_, 'tcx, ConstVidKey<'tcx>>, snapshot_var_len: usize, ) -> (Range, Vec) { let range = vars_since_snapshot(table, snapshot_var_len); ( range.start.vid..range.end.vid, (range.start.index()..range.end.index()) .map(|index| table.probe_value(ConstVid::from_u32(index)).origin) .collect(), ) } struct VariableLengths { type_var_len: usize, const_var_len: usize, int_var_len: usize, float_var_len: usize, region_constraints_len: usize, } impl<'tcx> InferCtxt<'tcx> { fn variable_lengths(&self) -> VariableLengths { let mut inner = self.inner.borrow_mut(); VariableLengths { type_var_len: inner.type_variables().num_vars(), const_var_len: inner.const_unification_table().len(), int_var_len: inner.int_unification_table().len(), float_var_len: inner.float_unification_table().len(), region_constraints_len: inner.unwrap_region_constraints().num_region_vars(), } } /// This rather funky routine is used while processing expected /// types. What happens here is that we want to propagate a /// coercion through the return type of a fn to its /// argument. Consider the type of `Option::Some`, which is /// basically `for fn(T) -> Option`. So if we have an /// expression `Some(&[1, 2, 3])`, and that has the expected type /// `Option<&[u32]>`, we would like to type check `&[1, 2, 3]` /// with the expectation of `&[u32]`. This will cause us to coerce /// from `&[u32; 3]` to `&[u32]` and make the users life more /// pleasant. /// /// The way we do this is using `fudge_inference_if_ok`. What the /// routine actually does is to start a snapshot and execute the /// closure `f`. In our example above, what this closure will do /// is to unify the expectation (`Option<&[u32]>`) with the actual /// return type (`Option`, where `?T` represents the variable /// instantiated for `T`). This will cause `?T` to be unified /// with `&?a [u32]`, where `?a` is a fresh lifetime variable. The /// input type (`?T`) is then returned by `f()`. /// /// At this point, `fudge_inference_if_ok` will normalize all type /// variables, converting `?T` to `&?a [u32]` and end the /// snapshot. The problem is that we can't just return this type /// out, because it references the region variable `?a`, and that /// region variable was popped when we popped the snapshot. /// /// So what we do is to keep a list (`region_vars`, in the code below) /// of region variables created during the snapshot (here, `?a`). We /// fold the return value and replace any such regions with a *new* /// region variable (e.g., `?b`) and return the result (`&?b [u32]`). /// This can then be used as the expectation for the fn argument. /// /// The important point here is that, for soundness purposes, the /// regions in question are not particularly important. We will /// use the expected types to guide coercions, but we will still /// type-check the resulting types from those coercions against /// the actual types (`?T`, `Option`) -- and remember that /// after the snapshot is popped, the variable `?T` is no longer /// unified. #[instrument(skip(self, f), level = "debug")] pub fn fudge_inference_if_ok(&self, f: F) -> Result where F: FnOnce() -> Result, T: TypeFoldable>, { let variable_lengths = self.variable_lengths(); let (mut fudger, value) = self.probe(|_| { match f() { Ok(value) => { let value = self.resolve_vars_if_possible(value); // At this point, `value` could in principle refer // to inference variables that have been created during // the snapshot. Once we exit `probe()`, those are // going to be popped, so we will have to // eliminate any references to them. let mut inner = self.inner.borrow_mut(); let type_vars = inner.type_variables().vars_since_snapshot(variable_lengths.type_var_len); let int_vars = vars_since_snapshot( &mut inner.int_unification_table(), variable_lengths.int_var_len, ); let float_vars = vars_since_snapshot( &mut inner.float_unification_table(), variable_lengths.float_var_len, ); let region_vars = inner .unwrap_region_constraints() .vars_since_snapshot(variable_lengths.region_constraints_len); let const_vars = const_vars_since_snapshot( &mut inner.const_unification_table(), variable_lengths.const_var_len, ); let fudger = InferenceFudger { infcx: self, type_vars, int_vars, float_vars, region_vars, const_vars, }; Ok((fudger, value)) } Err(e) => Err(e), } })?; // At this point, we need to replace any of the now-popped // type/region variables that appear in `value` with a fresh // variable of the appropriate kind. We can't do this during // the probe because they would just get popped then too. =) // Micro-optimization: if no variables have been created, then // `value` can't refer to any of them. =) So we can just return it. if fudger.type_vars.0.is_empty() && fudger.int_vars.is_empty() && fudger.float_vars.is_empty() && fudger.region_vars.0.is_empty() && fudger.const_vars.0.is_empty() { Ok(value) } else { Ok(value.fold_with(&mut fudger)) } } } pub struct InferenceFudger<'a, 'tcx> { infcx: &'a InferCtxt<'tcx>, type_vars: (Range, Vec), int_vars: Range, float_vars: Range, region_vars: (Range, Vec), const_vars: (Range, Vec), } impl<'a, 'tcx> TypeFolder> for InferenceFudger<'a, 'tcx> { fn interner(&self) -> TyCtxt<'tcx> { self.infcx.tcx } fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> { match *ty.kind() { ty::Infer(ty::InferTy::TyVar(vid)) => { if self.type_vars.0.contains(&vid) { // This variable was created during the fudging. // Recreate it with a fresh variable here. let idx = (vid.as_usize() - self.type_vars.0.start.as_usize()) as usize; let origin = self.type_vars.1[idx]; self.infcx.next_ty_var(origin) } else { // This variable was created before the // "fudging". Since we refresh all type // variables to their binding anyhow, we know // that it is unbound, so we can just return // it. debug_assert!( self.infcx.inner.borrow_mut().type_variables().probe(vid).is_unknown() ); ty } } ty::Infer(ty::InferTy::IntVar(vid)) => { if self.int_vars.contains(&vid) { self.infcx.next_int_var() } else { ty } } ty::Infer(ty::InferTy::FloatVar(vid)) => { if self.float_vars.contains(&vid) { self.infcx.next_float_var() } else { ty } } _ => ty.super_fold_with(self), } } fn fold_region(&mut self, r: ty::Region<'tcx>) -> ty::Region<'tcx> { if let ty::ReVar(vid) = *r && self.region_vars.0.contains(&vid) { let idx = vid.index() - self.region_vars.0.start.index(); let origin = self.region_vars.1[idx]; return self.infcx.next_region_var(origin); } r } fn fold_const(&mut self, ct: ty::Const<'tcx>) -> ty::Const<'tcx> { if let ty::ConstKind::Infer(ty::InferConst::Var(vid)) = ct.kind() { if self.const_vars.0.contains(&vid) { // This variable was created during the fudging. // Recreate it with a fresh variable here. let idx = (vid.index() - self.const_vars.0.start.index()) as usize; let origin = self.const_vars.1[idx]; self.infcx.next_const_var(ct.ty(), origin) } else { ct } } else { ct.super_fold_with(self) } } }