#![deny(rustc::untranslatable_diagnostic)] #![deny(rustc::diagnostic_outside_of_impl)] use crate::borrow_set::{BorrowData, BorrowSet, TwoPhaseActivation}; use crate::places_conflict; use crate::AccessDepth; use crate::BorrowIndex; use crate::Upvar; use rustc_data_structures::graph::dominators::Dominators; use rustc_middle::mir::BorrowKind; use rustc_middle::mir::{BasicBlock, Body, Location, Place, PlaceRef, ProjectionElem}; use rustc_middle::ty::TyCtxt; use rustc_target::abi::FieldIdx; /// Returns `true` if the borrow represented by `kind` is /// allowed to be split into separate Reservation and /// Activation phases. pub(super) fn allow_two_phase_borrow(kind: BorrowKind) -> bool { kind.allows_two_phase_borrow() } /// Control for the path borrow checking code #[derive(Copy, Clone, PartialEq, Eq, Debug)] pub(super) enum Control { Continue, Break, } /// Encapsulates the idea of iterating over every borrow that involves a particular path pub(super) fn each_borrow_involving_path<'tcx, F, I, S>( s: &mut S, tcx: TyCtxt<'tcx>, body: &Body<'tcx>, _location: Location, access_place: (AccessDepth, Place<'tcx>), borrow_set: &BorrowSet<'tcx>, is_candidate: I, mut op: F, ) where F: FnMut(&mut S, BorrowIndex, &BorrowData<'tcx>) -> Control, I: Fn(BorrowIndex) -> bool, { let (access, place) = access_place; // The number of candidates can be large, but borrows for different locals cannot conflict with // each other, so we restrict the working set a priori. let Some(borrows_for_place_base) = borrow_set.local_map.get(&place.local) else { return }; // check for loan restricting path P being used. Accounts for // borrows of P, P.a.b, etc. for &i in borrows_for_place_base { if !is_candidate(i) { continue; } let borrowed = &borrow_set[i]; if places_conflict::borrow_conflicts_with_place( tcx, body, borrowed.borrowed_place, borrowed.kind, place.as_ref(), access, places_conflict::PlaceConflictBias::Overlap, ) { debug!( "each_borrow_involving_path: {:?} @ {:?} vs. {:?}/{:?}", i, borrowed, place, access ); let ctrl = op(s, i, borrowed); if ctrl == Control::Break { return; } } } } pub(super) fn is_active<'tcx>( dominators: &Dominators, borrow_data: &BorrowData<'tcx>, location: Location, ) -> bool { debug!("is_active(borrow_data={:?}, location={:?})", borrow_data, location); let activation_location = match borrow_data.activation_location { // If this is not a 2-phase borrow, it is always active. TwoPhaseActivation::NotTwoPhase => return true, // And if the unique 2-phase use is not an activation, then it is *never* active. TwoPhaseActivation::NotActivated => return false, // Otherwise, we derive info from the activation point `loc`: TwoPhaseActivation::ActivatedAt(loc) => loc, }; // Otherwise, it is active for every location *except* in between // the reservation and the activation: // // X // / // R <--+ Except for this // / \ | diamond // \ / | // A <------+ // | // Z // // Note that we assume that: // - the reservation R dominates the activation A // - the activation A post-dominates the reservation R (ignoring unwinding edges). // // This means that there can't be an edge that leaves A and // comes back into that diamond unless it passes through R. // // Suboptimal: In some cases, this code walks the dominator // tree twice when it only has to be walked once. I am // lazy. -nmatsakis // If dominated by the activation A, then it is active. The // activation occurs upon entering the point A, so this is // also true if location == activation_location. if activation_location.dominates(location, dominators) { return true; } // The reservation starts *on exiting* the reservation block, // so check if the location is dominated by R.successor. If so, // this point falls in between the reservation and location. let reserve_location = borrow_data.reserve_location.successor_within_block(); if reserve_location.dominates(location, dominators) { false } else { // Otherwise, this point is outside the diamond, so // consider the borrow active. This could happen for // example if the borrow remains active around a loop (in // which case it would be active also for the point R, // which would generate an error). true } } /// Determines if a given borrow is borrowing local data /// This is called for all Yield expressions on movable coroutines pub(super) fn borrow_of_local_data(place: Place<'_>) -> bool { // Reborrow of already borrowed data is ignored // Any errors will be caught on the initial borrow !place.is_indirect() } /// If `place` is a field projection, and the field is being projected from a closure type, /// then returns the index of the field being projected. Note that this closure will always /// be `self` in the current MIR, because that is the only time we directly access the fields /// of a closure type. pub(crate) fn is_upvar_field_projection<'tcx>( tcx: TyCtxt<'tcx>, upvars: &[Upvar<'tcx>], place_ref: PlaceRef<'tcx>, body: &Body<'tcx>, ) -> Option { let mut place_ref = place_ref; let mut by_ref = false; if let Some((place_base, ProjectionElem::Deref)) = place_ref.last_projection() { place_ref = place_base; by_ref = true; } match place_ref.last_projection() { Some((place_base, ProjectionElem::Field(field, _ty))) => { let base_ty = place_base.ty(body, tcx).ty; if (base_ty.is_closure() || base_ty.is_coroutine()) && (!by_ref || upvars[field.index()].by_ref) { Some(field) } else { None } } _ => None, } }