// Copyright 2012-2017 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use rustc; use rustc::hir; use rustc::hir::def_id::DefId; use rustc::middle::region; use rustc::mir::{self, Location, Place, Mir}; use rustc::mir::visit::{PlaceContext, Visitor}; use rustc::ty::{self, Region, TyCtxt}; use rustc::ty::RegionKind; use rustc::ty::RegionKind::ReScope; use rustc::util::nodemap::{FxHashMap, FxHashSet}; use rustc_data_structures::bitslice::{BitwiseOperator}; use rustc_data_structures::indexed_set::{IdxSet}; use rustc_data_structures::indexed_vec::{Idx, IndexVec}; use rustc_data_structures::sync::Lrc; use dataflow::{BitDenotation, BlockSets, InitialFlow}; pub use dataflow::indexes::{BorrowIndex, ReserveOrActivateIndex}; use borrow_check::nll::region_infer::RegionInferenceContext; use borrow_check::nll::ToRegionVid; use syntax_pos::Span; use std::fmt; use std::hash::Hash; use std::rc::Rc; /// `Borrows` stores the data used in the analyses that track the flow /// of borrows. /// /// It uniquely identifies every borrow (`Rvalue::Ref`) by a /// `BorrowIndex`, and maps each such index to a `BorrowData` /// describing the borrow. These indexes are used for representing the /// borrows in compact bitvectors. pub struct Borrows<'a, 'gcx: 'tcx, 'tcx: 'a> { tcx: TyCtxt<'a, 'gcx, 'tcx>, mir: &'a Mir<'tcx>, scope_tree: Lrc, root_scope: Option, /// The fundamental map relating bitvector indexes to the borrows /// in the MIR. borrows: IndexVec>, /// Each borrow is also uniquely identified in the MIR by the /// `Location` of the assignment statement in which it appears on /// the right hand side; we map each such location to the /// corresponding `BorrowIndex`. location_map: FxHashMap, /// Every borrow in MIR is immediately stored into a place via an /// assignment statement. This maps each such assigned place back /// to its borrow-indexes. assigned_map: FxHashMap, FxHashSet>, /// Locations which activate borrows. /// NOTE: A given location may activate more than one borrow in the future /// when more general two-phase borrow support is introduced, but for now we /// only need to store one borrow index activation_map: FxHashMap, /// Every borrow has a region; this maps each such regions back to /// its borrow-indexes. region_map: FxHashMap, FxHashSet>, /// Map from local to all the borrows on that local local_map: FxHashMap>, /// Maps regions to their corresponding source spans /// Only contains ReScope()s as keys region_span_map: FxHashMap, /// NLL region inference context with which NLL queries should be resolved nonlexical_regioncx: Option>>, } // temporarily allow some dead fields: `kind` and `region` will be // needed by borrowck; `borrowed_place` will probably be a MovePathIndex when // that is extended to include borrowed data paths. #[allow(dead_code)] #[derive(Debug)] pub struct BorrowData<'tcx> { /// Location where the borrow reservation starts. /// In many cases, this will be equal to the activation location but not always. pub(crate) reserve_location: Location, /// What kind of borrow this is pub(crate) kind: mir::BorrowKind, /// The region for which this borrow is live pub(crate) region: Region<'tcx>, /// Place from which we are borrowing pub(crate) borrowed_place: mir::Place<'tcx>, /// Place to which the borrow was stored pub(crate) assigned_place: mir::Place<'tcx>, } impl<'tcx> fmt::Display for BorrowData<'tcx> { fn fmt(&self, w: &mut fmt::Formatter) -> fmt::Result { let kind = match self.kind { mir::BorrowKind::Shared => "", mir::BorrowKind::Unique => "uniq ", mir::BorrowKind::Mut { .. } => "mut ", }; let region = format!("{}", self.region); let region = if region.len() > 0 { format!("{} ", region) } else { region }; write!(w, "&{}{}{:?}", region, kind, self.borrowed_place) } } impl ReserveOrActivateIndex { fn reserved(i: BorrowIndex) -> Self { ReserveOrActivateIndex::new(i.index() * 2) } fn active(i: BorrowIndex) -> Self { ReserveOrActivateIndex::new((i.index() * 2) + 1) } pub(crate) fn is_reservation(self) -> bool { self.index() % 2 == 0 } pub(crate) fn is_activation(self) -> bool { self.index() % 2 == 1} pub(crate) fn kind(self) -> &'static str { if self.is_reservation() { "reserved" } else { "active" } } pub(crate) fn borrow_index(self) -> BorrowIndex { BorrowIndex::new(self.index() / 2) } } impl<'a, 'gcx, 'tcx> Borrows<'a, 'gcx, 'tcx> { pub fn new(tcx: TyCtxt<'a, 'gcx, 'tcx>, mir: &'a Mir<'tcx>, nonlexical_regioncx: Option>>, def_id: DefId, body_id: Option) -> Self { let scope_tree = tcx.region_scope_tree(def_id); let root_scope = body_id.map(|body_id| { region::Scope::CallSite(tcx.hir.body(body_id).value.hir_id.local_id) }); let mut visitor = GatherBorrows { tcx, mir, idx_vec: IndexVec::new(), location_map: FxHashMap(), assigned_map: FxHashMap(), activation_map: FxHashMap(), region_map: FxHashMap(), local_map: FxHashMap(), region_span_map: FxHashMap(), nonlexical_regioncx: nonlexical_regioncx.clone() }; visitor.visit_mir(mir); return Borrows { tcx: tcx, mir: mir, borrows: visitor.idx_vec, scope_tree, root_scope, location_map: visitor.location_map, assigned_map: visitor.assigned_map, activation_map: visitor.activation_map, region_map: visitor.region_map, local_map: visitor.local_map, region_span_map: visitor.region_span_map, nonlexical_regioncx }; struct GatherBorrows<'a, 'gcx: 'tcx, 'tcx: 'a> { tcx: TyCtxt<'a, 'gcx, 'tcx>, mir: &'a Mir<'tcx>, idx_vec: IndexVec>, location_map: FxHashMap, assigned_map: FxHashMap, FxHashSet>, activation_map: FxHashMap, region_map: FxHashMap, FxHashSet>, local_map: FxHashMap>, region_span_map: FxHashMap, nonlexical_regioncx: Option>>, } impl<'a, 'gcx, 'tcx> Visitor<'tcx> for GatherBorrows<'a, 'gcx, 'tcx> { fn visit_assign(&mut self, block: mir::BasicBlock, assigned_place: &mir::Place<'tcx>, rvalue: &mir::Rvalue<'tcx>, location: mir::Location) { fn root_local(mut p: &mir::Place<'_>) -> Option { loop { match p { mir::Place::Projection(pi) => p = &pi.base, mir::Place::Static(_) => return None, mir::Place::Local(l) => return Some(*l) }} } if let mir::Rvalue::Ref(region, kind, ref borrowed_place) = *rvalue { if is_unsafe_place(self.tcx, self.mir, borrowed_place) { return; } let activate_location = self.compute_activation_location(location, &assigned_place, region, kind); let borrow = BorrowData { kind, region, reserve_location: location, borrowed_place: borrowed_place.clone(), assigned_place: assigned_place.clone(), }; let idx = self.idx_vec.push(borrow); self.location_map.insert(location, idx); // This assert is a good sanity check until more general 2-phase borrow // support is introduced. See NOTE on the activation_map field for more assert!(!self.activation_map.contains_key(&activate_location), "More than one activation introduced at the same location."); self.activation_map.insert(activate_location, idx); insert(&mut self.assigned_map, assigned_place, idx); insert(&mut self.region_map, ®ion, idx); if let Some(local) = root_local(borrowed_place) { insert(&mut self.local_map, &local, idx); } } return self.super_assign(block, assigned_place, rvalue, location); fn insert<'a, K, V>(map: &'a mut FxHashMap>, k: &K, v: V) where K: Clone+Eq+Hash, V: Eq+Hash { map.entry(k.clone()) .or_insert(FxHashSet()) .insert(v); } } fn visit_rvalue(&mut self, rvalue: &mir::Rvalue<'tcx>, location: mir::Location) { if let mir::Rvalue::Ref(region, kind, ref place) = *rvalue { // double-check that we already registered a BorrowData for this let mut found_it = false; for idx in &self.region_map[region] { let bd = &self.idx_vec[*idx]; if bd.reserve_location == location && bd.kind == kind && bd.region == region && bd.borrowed_place == *place { found_it = true; break; } } assert!(found_it, "Ref {:?} at {:?} missing BorrowData", rvalue, location); } return self.super_rvalue(rvalue, location); } fn visit_statement(&mut self, block: mir::BasicBlock, statement: &mir::Statement<'tcx>, location: Location) { if let mir::StatementKind::EndRegion(region_scope) = statement.kind { self.region_span_map.insert(ReScope(region_scope), statement.source_info.span); } return self.super_statement(block, statement, location); } } /// A MIR visitor that determines if a specific place is used in a two-phase activating /// manner in a given chunk of MIR. struct ContainsUseOfPlace<'b, 'tcx: 'b> { target: &'b Place<'tcx>, use_found: bool, } impl<'b, 'tcx: 'b> ContainsUseOfPlace<'b, 'tcx> { fn new(place: &'b Place<'tcx>) -> Self { Self { target: place, use_found: false } } /// return whether `context` should be considered a "use" of a /// place found in that context. "Uses" activate associated /// borrows (at least when such uses occur while the borrow also /// has a reservation at the time). fn is_potential_use(context: PlaceContext) -> bool { match context { // storage effects on a place do not activate it PlaceContext::StorageLive | PlaceContext::StorageDead => false, // validation effects do not activate a place // // FIXME: Should they? Is it just another read? Or can we // guarantee it won't dereference the stored address? How // "deep" does validation go? PlaceContext::Validate => false, // FIXME: This is here to not change behaviour from before // AsmOutput existed, but it's not necessarily a pure overwrite. // so it's possible this should activate the place. PlaceContext::AsmOutput | // pure overwrites of a place do not activate it. (note // PlaceContext::Call is solely about dest place) PlaceContext::Store | PlaceContext::Call => false, // reads of a place *do* activate it PlaceContext::Move | PlaceContext::Copy | PlaceContext::Drop | PlaceContext::Inspect | PlaceContext::Borrow { .. } | PlaceContext::Projection(..) => true, } } } impl<'b, 'tcx: 'b> Visitor<'tcx> for ContainsUseOfPlace<'b, 'tcx> { fn visit_place(&mut self, place: &mir::Place<'tcx>, context: PlaceContext<'tcx>, location: Location) { if Self::is_potential_use(context) && place == self.target { self.use_found = true; return; // There is no need to keep checking the statement, we already found a use } self.super_place(place, context, location); } } impl<'a, 'gcx, 'tcx> GatherBorrows<'a, 'gcx, 'tcx> { /// Returns true if the borrow represented by `kind` is /// allowed to be split into separate Reservation and /// Activation phases. fn allow_two_phase_borrow(&self, kind: mir::BorrowKind) -> bool { self.tcx.two_phase_borrows() && (kind.allows_two_phase_borrow() || self.tcx.sess.opts.debugging_opts.two_phase_beyond_autoref) } /// Returns true if the given location contains an NLL-activating use of the given place fn location_contains_use(&self, location: Location, place: &Place) -> bool { let mut use_checker = ContainsUseOfPlace::new(place); let block = &self.mir.basic_blocks().get(location.block).unwrap_or_else(|| { panic!("could not find block at location {:?}", location); }); if location.statement_index != block.statements.len() { // This is a statement let stmt = block.statements.get(location.statement_index).unwrap_or_else(|| { panic!("could not find statement at location {:?}"); }); use_checker.visit_statement(location.block, stmt, location); } else { // This is a terminator match block.terminator { Some(ref term) => { use_checker.visit_terminator(location.block, term, location); } None => { // There is no way for Place to be used by the terminator if there is no // terminator } } } use_checker.use_found } /// Determines if the provided region is terminated after the provided location. /// EndRegion statements terminate their enclosed region::Scope. /// We also consult with the NLL region inference engine, should one be available fn region_terminated_after(&self, region: Region<'tcx>, location: Location) -> bool { let block_data = &self.mir[location.block]; if location.statement_index != block_data.statements.len() { let stmt = &block_data.statements[location.statement_index]; if let mir::StatementKind::EndRegion(region_scope) = stmt.kind { if &ReScope(region_scope) == region { // We encountered an EndRegion statement that terminates the provided // region return true; } } } if let Some(ref regioncx) = self.nonlexical_regioncx { if !regioncx.region_contains_point(region, location) { // NLL says the region has ended already return true; } } false } /// Computes the activation location of a borrow. /// The general idea is to start at the beginning of the region and perform a DFS /// until we exit the region, either via an explicit EndRegion or because NLL tells /// us so. If we find more than one valid activation point, we currently panic the /// compiler since two-phase borrows are only currently supported for compiler- /// generated code. More precisely, we only allow two-phase borrows for: /// - Function calls (fn some_func(&mut self, ....)) /// - *Assign operators (a += b -> fn add_assign(&mut self, other: Self)) /// See /// - https://github.com/rust-lang/rust/issues/48431 /// for detailed design notes. /// See the FIXME in the body of the function for notes on extending support to more /// general two-phased borrows. fn compute_activation_location(&self, start_location: Location, assigned_place: &mir::Place<'tcx>, region: Region<'tcx>, kind: mir::BorrowKind) -> Location { debug!("Borrows::compute_activation_location({:?}, {:?}, {:?})", start_location, assigned_place, region); if !self.allow_two_phase_borrow(kind) { debug!(" -> {:?}", start_location); return start_location; } // Perform the DFS. // `stack` is the stack of locations still under consideration // `visited` is the set of points we have already visited // `found_use` is an Option that becomes Some when we find a use let mut stack = vec![start_location]; let mut visited = FxHashSet(); let mut found_use = None; while let Some(curr_loc) = stack.pop() { let block_data = &self.mir.basic_blocks() .get(curr_loc.block) .unwrap_or_else(|| { panic!("could not find block at location {:?}", curr_loc); }); if self.region_terminated_after(region, curr_loc) { // No need to process this statement. // It's either an EndRegion (and thus couldn't use assigned_place) or not // contained in the NLL region and thus a use would be invalid continue; } if !visited.insert(curr_loc) { debug!(" Already visited {:?}", curr_loc); continue; } if self.location_contains_use(curr_loc, assigned_place) { // FIXME: Handle this case a little more gracefully. Perhaps collect // all uses in a vector, and find the point in the CFG that dominates // all of them? // Right now this is sufficient though since there should only be exactly // one borrow-activating use of the borrow. assert!(found_use.is_none(), "Found secondary use of place"); found_use = Some(curr_loc); } // Push the points we should consider next. if curr_loc.statement_index < block_data.statements.len() { stack.push(curr_loc.successor_within_block()); } else { stack.extend(block_data.terminator().successors().iter().map( |&basic_block| { Location { statement_index: 0, block: basic_block } } )) } } let found_use = found_use.expect("Did not find use of two-phase place"); debug!(" -> {:?}", found_use); found_use } } } /// Returns the span for the "end point" given region. This will /// return `None` if NLL is enabled, since that concept has no /// meaning there. Otherwise, return region span if it exists and /// span for end of the function if it doesn't exist. pub(crate) fn opt_region_end_span(&self, region: &Region) -> Option { match self.nonlexical_regioncx { Some(_) => None, None => { match self.region_span_map.get(region) { Some(span) => Some(self.tcx.sess.codemap().end_point(*span)), None => Some(self.tcx.sess.codemap().end_point(self.mir.span)) } } } } pub fn borrows(&self) -> &IndexVec> { &self.borrows } pub fn scope_tree(&self) -> &Lrc { &self.scope_tree } pub fn location(&self, idx: BorrowIndex) -> &Location { &self.borrows[idx].reserve_location } /// Add all borrows to the kill set, if those borrows are out of scope at `location`. /// That means either they went out of either a nonlexical scope, if we care about those /// at the moment, or the location represents a lexical EndRegion fn kill_loans_out_of_scope_at_location(&self, sets: &mut BlockSets, location: Location) { if let Some(ref regioncx) = self.nonlexical_regioncx { // NOTE: The state associated with a given `location` // reflects the dataflow on entry to the statement. If it // does not contain `borrow_region`, then then that means // that the statement at `location` kills the borrow. // // We are careful always to call this function *before* we // set up the gen-bits for the statement or // termanator. That way, if the effect of the statement or // terminator *does* introduce a new loan of the same // region, then setting that gen-bit will override any // potential kill introduced here. for (borrow_index, borrow_data) in self.borrows.iter_enumerated() { let borrow_region = borrow_data.region.to_region_vid(); if !regioncx.region_contains_point(borrow_region, location) { sets.kill(&ReserveOrActivateIndex::reserved(borrow_index)); sets.kill(&ReserveOrActivateIndex::active(borrow_index)); } } } } fn kill_borrows_on_local(&self, sets: &mut BlockSets, local: &rustc::mir::Local) { if let Some(borrow_indexes) = self.local_map.get(local) { sets.kill_all(borrow_indexes.iter() .map(|b| ReserveOrActivateIndex::reserved(*b))); sets.kill_all(borrow_indexes.iter() .map(|b| ReserveOrActivateIndex::active(*b))); } } /// Performs the activations for a given location fn perform_activations_at_location(&self, sets: &mut BlockSets, location: Location) { // Handle activations match self.activation_map.get(&location) { Some(&activated) => { debug!("activating borrow {:?}", activated); sets.gen(&ReserveOrActivateIndex::active(activated)) } None => {} } } } impl<'a, 'gcx, 'tcx> BitDenotation for Borrows<'a, 'gcx, 'tcx> { type Idx = ReserveOrActivateIndex; fn name() -> &'static str { "borrows" } fn bits_per_block(&self) -> usize { self.borrows.len() * 2 } fn start_block_effect(&self, _entry_set: &mut IdxSet) { // no borrows of code region_scopes have been taken prior to // function execution, so this method has no effect on // `_sets`. } fn before_statement_effect(&self, sets: &mut BlockSets, location: Location) { debug!("Borrows::before_statement_effect sets: {:?} location: {:?}", sets, location); self.kill_loans_out_of_scope_at_location(sets, location); } fn statement_effect(&self, sets: &mut BlockSets, location: Location) { debug!("Borrows::statement_effect sets: {:?} location: {:?}", sets, location); let block = &self.mir.basic_blocks().get(location.block).unwrap_or_else(|| { panic!("could not find block at location {:?}", location); }); let stmt = block.statements.get(location.statement_index).unwrap_or_else(|| { panic!("could not find statement at location {:?}"); }); self.perform_activations_at_location(sets, location); self.kill_loans_out_of_scope_at_location(sets, location); match stmt.kind { // EndRegion kills any borrows (reservations and active borrows both) mir::StatementKind::EndRegion(region_scope) => { if let Some(borrow_indexes) = self.region_map.get(&ReScope(region_scope)) { assert!(self.nonlexical_regioncx.is_none()); for idx in borrow_indexes { sets.kill(&ReserveOrActivateIndex::reserved(*idx)); sets.kill(&ReserveOrActivateIndex::active(*idx)); } } else { // (if there is no entry, then there are no borrows to be tracked) } } mir::StatementKind::Assign(ref lhs, ref rhs) => { // Make sure there are no remaining borrows for variables // that are assigned over. if let Place::Local(ref local) = *lhs { // FIXME: Handle the case in which we're assigning over // a projection (`foo.bar`). self.kill_borrows_on_local(sets, local); } // NOTE: if/when the Assign case is revised to inspect // the assigned_place here, make sure to also // re-consider the current implementations of the // propagate_call_return method. if let mir::Rvalue::Ref(region, _, ref place) = *rhs { if is_unsafe_place(self.tcx, self.mir, place) { return; } let index = self.location_map.get(&location).unwrap_or_else(|| { panic!("could not find BorrowIndex for location {:?}", location); }); if let RegionKind::ReEmpty = region { // If the borrowed value dies before the borrow is used, the region for // the borrow can be empty. Don't track the borrow in that case. sets.kill(&ReserveOrActivateIndex::active(*index)); return } assert!(self.region_map.get(region).unwrap_or_else(|| { panic!("could not find BorrowIndexs for region {:?}", region); }).contains(&index)); sets.gen(&ReserveOrActivateIndex::reserved(*index)); // Issue #46746: Two-phase borrows handles // stmts of form `Tmp = &mut Borrow` ... match lhs { Place::Local(..) | Place::Static(..) => {} // okay Place::Projection(..) => { // ... can assign into projections, // e.g. `box (&mut _)`. Current // conservative solution: force // immediate activation here. sets.gen(&ReserveOrActivateIndex::active(*index)); } } } } mir::StatementKind::StorageDead(local) => { // Make sure there are no remaining borrows for locals that // are gone out of scope. self.kill_borrows_on_local(sets, &local) } mir::StatementKind::InlineAsm { ref outputs, ref asm, .. } => { for (output, kind) in outputs.iter().zip(&asm.outputs) { if !kind.is_indirect && !kind.is_rw { // Make sure there are no remaining borrows for direct // output variables. if let Place::Local(ref local) = *output { // FIXME: Handle the case in which we're assigning over // a projection (`foo.bar`). self.kill_borrows_on_local(sets, local); } } } } mir::StatementKind::SetDiscriminant { .. } | mir::StatementKind::StorageLive(..) | mir::StatementKind::Validate(..) | mir::StatementKind::UserAssertTy(..) | mir::StatementKind::Nop => {} } } fn before_terminator_effect(&self, sets: &mut BlockSets, location: Location) { debug!("Borrows::before_terminator_effect sets: {:?} location: {:?}", sets, location); self.kill_loans_out_of_scope_at_location(sets, location); } fn terminator_effect(&self, sets: &mut BlockSets, location: Location) { debug!("Borrows::terminator_effect sets: {:?} location: {:?}", sets, location); let block = &self.mir.basic_blocks().get(location.block).unwrap_or_else(|| { panic!("could not find block at location {:?}", location); }); let term = block.terminator(); self.perform_activations_at_location(sets, location); self.kill_loans_out_of_scope_at_location(sets, location); match term.kind { mir::TerminatorKind::Resume | mir::TerminatorKind::Return | mir::TerminatorKind::GeneratorDrop => { // When we return from the function, then all `ReScope`-style regions // are guaranteed to have ended. // Normally, there would be `EndRegion` statements that come before, // and hence most of these loans will already be dead -- but, in some cases // like unwind paths, we do not always emit `EndRegion` statements, so we // add some kills here as a "backup" and to avoid spurious error messages. for (borrow_index, borrow_data) in self.borrows.iter_enumerated() { if let ReScope(scope) = borrow_data.region { // Check that the scope is not actually a scope from a function that is // a parent of our closure. Note that the CallSite scope itself is // *outside* of the closure, for some weird reason. if let Some(root_scope) = self.root_scope { if *scope != root_scope && self.scope_tree.is_subscope_of(*scope, root_scope) { sets.kill(&ReserveOrActivateIndex::reserved(borrow_index)); sets.kill(&ReserveOrActivateIndex::active(borrow_index)); } } } } } mir::TerminatorKind::Abort | mir::TerminatorKind::SwitchInt {..} | mir::TerminatorKind::Drop {..} | mir::TerminatorKind::DropAndReplace {..} | mir::TerminatorKind::Call {..} | mir::TerminatorKind::Assert {..} | mir::TerminatorKind::Yield {..} | mir::TerminatorKind::Goto {..} | mir::TerminatorKind::FalseEdges {..} | mir::TerminatorKind::FalseUnwind {..} | mir::TerminatorKind::Unreachable => {} } } fn propagate_call_return(&self, _in_out: &mut IdxSet, _call_bb: mir::BasicBlock, _dest_bb: mir::BasicBlock, _dest_place: &mir::Place) { // there are no effects on borrows from method call return... // // ... but if overwriting a place can affect flow state, then // latter is not true; see NOTE on Assign case in // statement_effect_on_borrows. } } impl<'a, 'gcx, 'tcx> BitwiseOperator for Borrows<'a, 'gcx, 'tcx> { #[inline] fn join(&self, pred1: usize, pred2: usize) -> usize { pred1 | pred2 // union effects of preds when computing reservations } } impl<'a, 'gcx, 'tcx> InitialFlow for Borrows<'a, 'gcx, 'tcx> { #[inline] fn bottom_value() -> bool { false // bottom = nothing is reserved or activated yet } } fn is_unsafe_place<'a, 'gcx: 'tcx, 'tcx: 'a>( tcx: TyCtxt<'a, 'gcx, 'tcx>, mir: &'a Mir<'tcx>, place: &mir::Place<'tcx> ) -> bool { use self::mir::Place::*; use self::mir::ProjectionElem; match *place { Local(_) => false, Static(ref static_) => tcx.is_static(static_.def_id) == Some(hir::Mutability::MutMutable), Projection(ref proj) => { match proj.elem { ProjectionElem::Field(..) | ProjectionElem::Downcast(..) | ProjectionElem::Subslice { .. } | ProjectionElem::ConstantIndex { .. } | ProjectionElem::Index(_) => { is_unsafe_place(tcx, mir, &proj.base) } ProjectionElem::Deref => { let ty = proj.base.ty(mir, tcx).to_ty(tcx); match ty.sty { ty::TyRawPtr(..) => true, _ => is_unsafe_place(tcx, mir, &proj.base), } } } } } }