1 // Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT
2 // file at the top-level directory of this distribution and at
3 // http://rust-lang.org/COPYRIGHT.
5 // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
6 // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
7 // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
8 // option. This file may not be copied, modified, or distributed
9 // except according to those terms.
11 //! See The Book chapter on the borrow checker for more details.
13 #![allow(non_camel_case_types)]
15 pub use self::LoanPathKind::*;
16 pub use self::LoanPathElem::*;
17 pub use self::bckerr_code::*;
18 pub use self::AliasableViolationKind::*;
19 pub use self::MovedValueUseKind::*;
21 use self::InteriorKind::*;
23 use rustc::hir::map as hir_map;
24 use rustc::hir::map::blocks::FnLikeNode;
26 use rustc::middle::dataflow::DataFlowContext;
27 use rustc::middle::dataflow::BitwiseOperator;
28 use rustc::middle::dataflow::DataFlowOperator;
29 use rustc::middle::dataflow::KillFrom;
30 use rustc::hir::def_id::{DefId, DefIndex};
31 use rustc::middle::expr_use_visitor as euv;
32 use rustc::middle::mem_categorization as mc;
33 use rustc::middle::mem_categorization::Categorization;
34 use rustc::middle::mem_categorization::ImmutabilityBlame;
35 use rustc::middle::region;
36 use rustc::middle::free_region::RegionRelations;
37 use rustc::ty::{self, Ty, TyCtxt};
38 use rustc::ty::maps::Providers;
39 use rustc_mir::util::borrowck_errors::{BorrowckErrors, Origin};
43 use std::hash::{Hash, Hasher};
45 use syntax_pos::{MultiSpan, Span};
46 use errors::DiagnosticBuilder;
49 use rustc::hir::intravisit::{self, Visitor};
57 #[derive(Clone, Copy)]
58 pub struct LoanDataFlowOperator;
60 pub type LoanDataFlow<'a, 'tcx> = DataFlowContext<'a, 'tcx, LoanDataFlowOperator>;
62 pub fn check_crate<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>) {
63 for body_owner_def_id in tcx.body_owners() {
64 tcx.borrowck(body_owner_def_id);
68 pub fn provide(providers: &mut Providers) {
69 *providers = Providers {
75 /// Collection of conclusions determined via borrow checker analyses.
76 pub struct AnalysisData<'a, 'tcx: 'a> {
77 pub all_loans: Vec<Loan<'tcx>>,
78 pub loans: DataFlowContext<'a, 'tcx, LoanDataFlowOperator>,
79 pub move_data: move_data::FlowedMoveData<'a, 'tcx>,
82 fn borrowck<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, owner_def_id: DefId) {
83 debug!("borrowck(body_owner_def_id={:?})", owner_def_id);
85 let owner_id = tcx.hir.as_local_node_id(owner_def_id).unwrap();
87 match tcx.hir.get(owner_id) {
88 hir_map::NodeStructCtor(_) |
89 hir_map::NodeVariant(_) => {
90 // We get invoked with anything that has MIR, but some of
91 // those things (notably the synthesized constructors from
92 // tuple structs/variants) do not have an associated body
93 // and do not need borrowchecking.
99 let body_id = tcx.hir.body_owned_by(owner_id);
100 let tables = tcx.typeck_tables_of(owner_def_id);
101 let region_scope_tree = tcx.region_scope_tree(owner_def_id);
102 let body = tcx.hir.body(body_id);
103 let bccx = &mut BorrowckCtxt { tcx, tables, region_scope_tree, owner_def_id, body };
105 // Eventually, borrowck will always read the MIR, but at the
106 // moment we do not. So, for now, we always force MIR to be
107 // constructed for a given fn, since this may result in errors
108 // being reported and we want that to happen.
110 // Note that `mir_validated` is a "stealable" result; the
111 // thief, `optimized_mir()`, forces borrowck, so we know that
112 // is not yet stolen.
113 tcx.mir_validated(owner_def_id).borrow();
115 // option dance because you can't capture an uninitialized variable
118 if let Some(AnalysisData { all_loans,
120 move_data: flowed_moves }) =
121 build_borrowck_dataflow_data(bccx, false, body_id,
123 cfg = Some(cfg::CFG::new(bccx.tcx, &body));
124 cfg.as_mut().unwrap()
127 check_loans::check_loans(bccx, &loan_dfcx, &flowed_moves, &all_loans, body);
131 fn build_borrowck_dataflow_data<'a, 'c, 'tcx, F>(this: &mut BorrowckCtxt<'a, 'tcx>,
132 force_analysis: bool,
133 body_id: hir::BodyId,
135 -> Option<AnalysisData<'a, 'tcx>>
136 where F: FnOnce(&mut BorrowckCtxt<'a, 'tcx>) -> &'c cfg::CFG
138 // Check the body of fn items.
141 let mut visitor = intravisit::IdRangeComputingVisitor::new(&tcx.hir);
142 visitor.visit_body(this.body);
145 let (all_loans, move_data) =
146 gather_loans::gather_loans_in_fn(this, body_id);
148 if !force_analysis && move_data.is_empty() && all_loans.is_empty() {
149 // large arrays of data inserted as constants can take a lot of
150 // time and memory to borrow-check - see issue #36799. However,
151 // they don't have lvalues, so no borrow-check is actually needed.
152 // Recognize that case and skip borrow-checking.
153 debug!("skipping loan propagation for {:?} because of no loans", body_id);
156 debug!("propagating loans in {:?}", body_id);
159 let cfg = get_cfg(this);
161 DataFlowContext::new(this.tcx,
165 LoanDataFlowOperator,
168 for (loan_idx, loan) in all_loans.iter().enumerate() {
169 loan_dfcx.add_gen(loan.gen_scope.item_local_id(), loan_idx);
170 loan_dfcx.add_kill(KillFrom::ScopeEnd,
171 loan.kill_scope.item_local_id(),
174 loan_dfcx.add_kills_from_flow_exits(cfg);
175 loan_dfcx.propagate(cfg, this.body);
177 let flowed_moves = move_data::FlowedMoveData::new(move_data,
183 Some(AnalysisData { all_loans,
185 move_data:flowed_moves })
188 /// Accessor for introspective clients inspecting `AnalysisData` and
189 /// the `BorrowckCtxt` itself , e.g. the flowgraph visualizer.
190 pub fn build_borrowck_dataflow_data_for_fn<'a, 'tcx>(
191 tcx: TyCtxt<'a, 'tcx, 'tcx>,
192 body_id: hir::BodyId,
194 -> (BorrowckCtxt<'a, 'tcx>, AnalysisData<'a, 'tcx>)
196 let owner_id = tcx.hir.body_owner(body_id);
197 let owner_def_id = tcx.hir.local_def_id(owner_id);
198 let tables = tcx.typeck_tables_of(owner_def_id);
199 let region_scope_tree = tcx.region_scope_tree(owner_def_id);
200 let body = tcx.hir.body(body_id);
201 let mut bccx = BorrowckCtxt { tcx, tables, region_scope_tree, owner_def_id, body };
203 let dataflow_data = build_borrowck_dataflow_data(&mut bccx, true, body_id, |_| cfg);
204 (bccx, dataflow_data.unwrap())
207 // ----------------------------------------------------------------------
210 pub struct BorrowckCtxt<'a, 'tcx: 'a> {
211 tcx: TyCtxt<'a, 'tcx, 'tcx>,
213 // tables for the current thing we are checking; set to
214 // Some in `borrowck_fn` and cleared later
215 tables: &'a ty::TypeckTables<'tcx>,
217 region_scope_tree: Rc<region::ScopeTree>,
221 body: &'tcx hir::Body,
224 impl<'b, 'tcx: 'b> BorrowckErrors for BorrowckCtxt<'b, 'tcx> {
225 fn struct_span_err_with_code<'a, S: Into<MultiSpan>>(&'a self,
229 -> DiagnosticBuilder<'a>
231 self.tcx.sess.struct_span_err_with_code(sp, msg, code)
234 fn struct_span_err<'a, S: Into<MultiSpan>>(&'a self,
237 -> DiagnosticBuilder<'a>
239 self.tcx.sess.struct_span_err(sp, msg)
243 ///////////////////////////////////////////////////////////////////////////
244 // Loans and loan paths
246 /// Record of a loan that was issued.
247 pub struct Loan<'tcx> {
249 loan_path: Rc<LoanPath<'tcx>>,
250 kind: ty::BorrowKind,
251 restricted_paths: Vec<Rc<LoanPath<'tcx>>>,
253 /// gen_scope indicates where loan is introduced. Typically the
254 /// loan is introduced at the point of the borrow, but in some
255 /// cases, notably method arguments, the loan may be introduced
256 /// only later, once it comes into scope. See also
257 /// `GatherLoanCtxt::compute_gen_scope`.
258 gen_scope: region::Scope,
260 /// kill_scope indicates when the loan goes out of scope. This is
261 /// either when the lifetime expires or when the local variable
262 /// which roots the loan-path goes out of scope, whichever happens
263 /// faster. See also `GatherLoanCtxt::compute_kill_scope`.
264 kill_scope: region::Scope,
266 cause: euv::LoanCause,
269 impl<'tcx> Loan<'tcx> {
270 pub fn loan_path(&self) -> Rc<LoanPath<'tcx>> {
271 self.loan_path.clone()
276 pub struct LoanPath<'tcx> {
277 kind: LoanPathKind<'tcx>,
281 impl<'tcx> PartialEq for LoanPath<'tcx> {
282 fn eq(&self, that: &LoanPath<'tcx>) -> bool {
283 self.kind == that.kind
287 impl<'tcx> Hash for LoanPath<'tcx> {
288 fn hash<H: Hasher>(&self, state: &mut H) {
289 self.kind.hash(state);
293 #[derive(PartialEq, Eq, Hash, Debug)]
294 pub enum LoanPathKind<'tcx> {
295 LpVar(ast::NodeId), // `x` in README.md
296 LpUpvar(ty::UpvarId), // `x` captured by-value into closure
297 LpDowncast(Rc<LoanPath<'tcx>>, DefId), // `x` downcast to particular enum variant
298 LpExtend(Rc<LoanPath<'tcx>>, mc::MutabilityCategory, LoanPathElem<'tcx>)
301 impl<'tcx> LoanPath<'tcx> {
302 fn new(kind: LoanPathKind<'tcx>, ty: Ty<'tcx>) -> LoanPath<'tcx> {
303 LoanPath { kind: kind, ty: ty }
306 fn to_type(&self) -> Ty<'tcx> { self.ty }
309 // FIXME (pnkfelix): See discussion here
310 // https://github.com/pnkfelix/rust/commit/
311 // b2b39e8700e37ad32b486b9a8409b50a8a53aa51#commitcomment-7892003
312 const DOWNCAST_PRINTED_OPERATOR: &'static str = " as ";
314 // A local, "cleaned" version of `mc::InteriorKind` that drops
315 // information that is not relevant to loan-path analysis. (In
316 // particular, the distinction between how precisely an array-element
317 // is tracked is irrelevant here.)
318 #[derive(Clone, Copy, PartialEq, Eq, Hash)]
319 pub enum InteriorKind {
320 InteriorField(mc::FieldName),
324 trait ToInteriorKind { fn cleaned(self) -> InteriorKind; }
325 impl ToInteriorKind for mc::InteriorKind {
326 fn cleaned(self) -> InteriorKind {
328 mc::InteriorField(name) => InteriorField(name),
329 mc::InteriorElement(_) => InteriorElement,
335 // - a pointer dereference (`*LV` in README.md)
336 // - a field reference, with an optional definition of the containing
337 // enum variant (`LV.f` in README.md)
338 // `DefId` is present when the field is part of struct that is in
339 // a variant of an enum. For instance in:
340 // `enum E { X { foo: u32 }, Y { foo: u32 }}`
341 // each `foo` is qualified by the definitition id of the variant (`X` or `Y`).
342 #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug)]
343 pub enum LoanPathElem<'tcx> {
344 LpDeref(mc::PointerKind<'tcx>),
345 LpInterior(Option<DefId>, InteriorKind),
348 fn closure_to_block(closure_id: DefIndex,
349 tcx: TyCtxt) -> ast::NodeId {
350 let closure_id = tcx.hir.def_index_to_node_id(closure_id);
351 match tcx.hir.get(closure_id) {
352 hir_map::NodeExpr(expr) => match expr.node {
353 hir::ExprClosure(.., body_id, _, _) => {
357 bug!("encountered non-closure id: {}", closure_id)
360 _ => bug!("encountered non-expr id: {}", closure_id)
364 impl<'a, 'tcx> LoanPath<'tcx> {
365 pub fn kill_scope(&self, bccx: &BorrowckCtxt<'a, 'tcx>) -> region::Scope {
368 let hir_id = bccx.tcx.hir.node_to_hir_id(local_id);
369 bccx.region_scope_tree.var_scope(hir_id.local_id)
371 LpUpvar(upvar_id) => {
372 let block_id = closure_to_block(upvar_id.closure_expr_id, bccx.tcx);
373 let hir_id = bccx.tcx.hir.node_to_hir_id(block_id);
374 region::Scope::Node(hir_id.local_id)
376 LpDowncast(ref base, _) |
377 LpExtend(ref base, ..) => base.kill_scope(bccx),
381 fn has_fork(&self, other: &LoanPath<'tcx>) -> bool {
382 match (&self.kind, &other.kind) {
383 (&LpExtend(ref base, _, LpInterior(opt_variant_id, id)),
384 &LpExtend(ref base2, _, LpInterior(opt_variant_id2, id2))) =>
385 if id == id2 && opt_variant_id == opt_variant_id2 {
386 base.has_fork(&base2)
390 (&LpExtend(ref base, _, LpDeref(_)), _) => base.has_fork(other),
391 (_, &LpExtend(ref base, _, LpDeref(_))) => self.has_fork(&base),
396 fn depth(&self) -> usize {
398 LpExtend(ref base, _, LpDeref(_)) => base.depth(),
399 LpExtend(ref base, _, LpInterior(..)) => base.depth() + 1,
404 fn common(&self, other: &LoanPath<'tcx>) -> Option<LoanPath<'tcx>> {
405 match (&self.kind, &other.kind) {
406 (&LpExtend(ref base, a, LpInterior(opt_variant_id, id)),
407 &LpExtend(ref base2, _, LpInterior(opt_variant_id2, id2))) => {
408 if id == id2 && opt_variant_id == opt_variant_id2 {
409 base.common(&base2).map(|x| {
411 if base.depth() == xd && base2.depth() == xd {
413 kind: LpExtend(Rc::new(x), a, LpInterior(opt_variant_id, id)),
424 (&LpExtend(ref base, _, LpDeref(_)), _) => base.common(other),
425 (_, &LpExtend(ref other, _, LpDeref(_))) => self.common(&other),
426 (&LpVar(id), &LpVar(id2)) => {
428 Some(LoanPath { kind: LpVar(id), ty: self.ty })
433 (&LpUpvar(id), &LpUpvar(id2)) => {
435 Some(LoanPath { kind: LpUpvar(id), ty: self.ty })
445 pub fn opt_loan_path<'tcx>(cmt: &mc::cmt<'tcx>) -> Option<Rc<LoanPath<'tcx>>> {
446 //! Computes the `LoanPath` (if any) for a `cmt`.
447 //! Note that this logic is somewhat duplicated in
448 //! the method `compute()` found in `gather_loans::restrictions`,
449 //! which allows it to share common loan path pieces as it
450 //! traverses the CMT.
452 let new_lp = |v: LoanPathKind<'tcx>| Rc::new(LoanPath::new(v, cmt.ty));
455 Categorization::Rvalue(..) |
456 Categorization::StaticItem => {
460 Categorization::Local(id) => {
461 Some(new_lp(LpVar(id)))
464 Categorization::Upvar(mc::Upvar { id, .. }) => {
465 Some(new_lp(LpUpvar(id)))
468 Categorization::Deref(ref cmt_base, pk) => {
469 opt_loan_path(cmt_base).map(|lp| {
470 new_lp(LpExtend(lp, cmt.mutbl, LpDeref(pk)))
474 Categorization::Interior(ref cmt_base, ik) => {
475 opt_loan_path(cmt_base).map(|lp| {
476 let opt_variant_id = match cmt_base.cat {
477 Categorization::Downcast(_, did) => Some(did),
480 new_lp(LpExtend(lp, cmt.mutbl, LpInterior(opt_variant_id, ik.cleaned())))
484 Categorization::Downcast(ref cmt_base, variant_def_id) =>
485 opt_loan_path(cmt_base)
487 new_lp(LpDowncast(lp, variant_def_id))
493 ///////////////////////////////////////////////////////////////////////////
496 // Errors that can occur
497 #[derive(Debug, PartialEq)]
498 pub enum bckerr_code<'tcx> {
500 /// superscope, subscope, loan cause
501 err_out_of_scope(ty::Region<'tcx>, ty::Region<'tcx>, euv::LoanCause),
502 err_borrowed_pointer_too_short(ty::Region<'tcx>, ty::Region<'tcx>), // loan, ptr
505 // Combination of an error code and the categorization of the expression
507 #[derive(Debug, PartialEq)]
508 pub struct BckError<'tcx> {
510 cause: AliasableViolationKind,
512 code: bckerr_code<'tcx>
515 #[derive(Copy, Clone, Debug, PartialEq)]
516 pub enum AliasableViolationKind {
518 BorrowViolation(euv::LoanCause)
521 #[derive(Copy, Clone, Debug)]
522 pub enum MovedValueUseKind {
527 ///////////////////////////////////////////////////////////////////////////
530 impl<'a, 'tcx> BorrowckCtxt<'a, 'tcx> {
531 pub fn is_subregion_of(&self,
532 r_sub: ty::Region<'tcx>,
533 r_sup: ty::Region<'tcx>)
536 let region_rels = RegionRelations::new(self.tcx,
538 &self.region_scope_tree,
539 &self.tables.free_region_map);
540 region_rels.is_subregion_of(r_sub, r_sup)
543 pub fn report(&self, err: BckError<'tcx>) {
544 // Catch and handle some particular cases.
545 match (&err.code, &err.cause) {
546 (&err_out_of_scope(&ty::ReScope(_), &ty::ReStatic, _),
547 &BorrowViolation(euv::ClosureCapture(span))) |
548 (&err_out_of_scope(&ty::ReScope(_), &ty::ReEarlyBound(..), _),
549 &BorrowViolation(euv::ClosureCapture(span))) |
550 (&err_out_of_scope(&ty::ReScope(_), &ty::ReFree(..), _),
551 &BorrowViolation(euv::ClosureCapture(span))) => {
552 return self.report_out_of_scope_escaping_closure_capture(&err, span);
557 self.report_bckerr(&err);
560 pub fn report_use_of_moved_value(&self,
562 use_kind: MovedValueUseKind,
564 the_move: &move_data::Move,
565 moved_lp: &LoanPath<'tcx>,
566 _param_env: ty::ParamEnv<'tcx>) {
567 let (verb, verb_participle) = match use_kind {
568 MovedInUse => ("use", "used"),
569 MovedInCapture => ("capture", "captured"),
572 let (_ol, _moved_lp_msg, mut err, need_note) = match the_move.kind {
573 move_data::Declared => {
574 // If this is an uninitialized variable, just emit a simple warning
576 self.cannot_act_on_uninitialized_variable(use_span,
578 &self.loan_path_to_string(lp),
580 .span_label(use_span, format!("use of possibly uninitialized `{}`",
581 self.loan_path_to_string(lp)))
586 // If moved_lp is something like `x.a`, and lp is something like `x.b`, we would
587 // normally generate a rather confusing message:
589 // error: use of moved value: `x.b`
590 // note: `x.a` moved here...
592 // What we want to do instead is get the 'common ancestor' of the two moves and
593 // use that for most of the message instead, giving is something like this:
595 // error: use of moved value: `x`
596 // note: `x` moved here (through moving `x.a`)...
598 let common = moved_lp.common(lp);
599 let has_common = common.is_some();
600 let has_fork = moved_lp.has_fork(lp);
601 let (nl, ol, moved_lp_msg) =
602 if has_fork && has_common {
603 let nl = self.loan_path_to_string(&common.unwrap());
605 let moved_lp_msg = format!(" (through moving `{}`)",
606 self.loan_path_to_string(moved_lp));
607 (nl, ol, moved_lp_msg)
609 (self.loan_path_to_string(lp),
610 self.loan_path_to_string(moved_lp),
614 let partial = moved_lp.depth() > lp.depth();
615 let msg = if !has_fork && partial { "partially " }
616 else if has_fork && !has_common { "collaterally "}
618 let mut err = struct_span_err!(
619 self.tcx.sess, use_span, E0382,
620 "{} of {}moved value: `{}`",
622 let need_note = match lp.ty.sty {
623 ty::TypeVariants::TyClosure(id, _) => {
624 let node_id = self.tcx.hir.as_local_node_id(id).unwrap();
625 let hir_id = self.tcx.hir.node_to_hir_id(node_id);
626 if let Some(&(ty::ClosureKind::FnOnce, Some((span, name)))) =
627 self.tables.closure_kinds().get(hir_id)
629 err.span_note(span, &format!(
630 "closure cannot be invoked more than once because \
631 it moves the variable `{}` out of its environment",
641 (ol, moved_lp_msg, err, need_note)
645 // Get type of value and span where it was previously
647 let node_id = self.tcx.hir.hir_to_node_id(hir::HirId {
648 owner: self.body.value.hir_id.owner,
649 local_id: the_move.id
651 let (move_span, move_note) = match the_move.kind {
652 move_data::Declared => {
656 move_data::MoveExpr |
657 move_data::MovePat => (self.tcx.hir.span(node_id), ""),
659 move_data::Captured =>
660 (match self.tcx.hir.expect_expr(node_id).node {
661 hir::ExprClosure(.., fn_decl_span, _) => fn_decl_span,
662 ref r => bug!("Captured({:?}) maps to non-closure: {:?}",
664 }, " (into closure)"),
667 // Annotate the use and the move in the span. Watch out for
668 // the case where the use and the move are the same. This
669 // means the use is in a loop.
670 err = if use_span == move_span {
673 format!("value moved{} here in previous iteration of loop",
677 err.span_label(use_span, format!("value {} here after move", verb_participle))
678 .span_label(move_span, format!("value moved{} here", move_note));
683 err.note(&format!("move occurs because `{}` has type `{}`, \
684 which does not implement the `Copy` trait",
685 self.loan_path_to_string(moved_lp),
689 // Note: we used to suggest adding a `ref binding` or calling
690 // `clone` but those suggestions have been removed because
691 // they are often not what you actually want to do, and were
692 // not considered particularly helpful.
697 pub fn report_partial_reinitialization_of_uninitialized_structure(
700 lp: &LoanPath<'tcx>) {
702 self.tcx.sess, span, E0383,
703 "partial reinitialization of uninitialized structure `{}`",
704 self.loan_path_to_string(lp));
707 pub fn report_reassigned_immutable_variable(&self,
711 &move_data::Assignment) {
712 let mut err = self.cannot_reassign_immutable(span,
713 &self.loan_path_to_string(lp),
715 err.span_label(span, "re-assignment of immutable variable");
716 if span != assign.span {
717 err.span_label(assign.span, format!("first assignment to `{}`",
718 self.loan_path_to_string(lp)));
723 pub fn struct_span_err_with_code<S: Into<MultiSpan>>(&self,
727 -> DiagnosticBuilder<'a> {
728 self.tcx.sess.struct_span_err_with_code(s, msg, code)
731 pub fn span_err_with_code<S: Into<MultiSpan>>(&self, s: S, msg: &str, code: &str) {
732 self.tcx.sess.span_err_with_code(s, msg, code);
735 fn report_bckerr(&self, err: &BckError<'tcx>) {
736 let error_span = err.span.clone();
740 let descr = match err.cmt.note {
741 mc::NoteClosureEnv(_) | mc::NoteUpvarRef(_) => {
742 self.cmt_to_string(&err.cmt)
744 _ => match opt_loan_path(&err.cmt) {
747 err.cmt.mutbl.to_user_str(),
748 self.cmt_to_string(&err.cmt))
752 format!("{} {} `{}`",
753 err.cmt.mutbl.to_user_str(),
754 self.cmt_to_string(&err.cmt),
755 self.loan_path_to_string(&lp))
760 let mut db = match err.cause {
761 MutabilityViolation => {
762 self.cannot_assign(error_span, &descr, Origin::Ast)
764 BorrowViolation(euv::ClosureCapture(_)) => {
765 struct_span_err!(self.tcx.sess, error_span, E0595,
766 "closure cannot assign to {}", descr)
768 BorrowViolation(euv::OverloadedOperator) |
769 BorrowViolation(euv::AddrOf) |
770 BorrowViolation(euv::RefBinding) |
771 BorrowViolation(euv::AutoRef) |
772 BorrowViolation(euv::AutoUnsafe) |
773 BorrowViolation(euv::ForLoop) |
774 BorrowViolation(euv::MatchDiscriminant) => {
775 struct_span_err!(self.tcx.sess, error_span, E0596,
776 "cannot borrow {} as mutable", descr)
778 BorrowViolation(euv::ClosureInvocation) => {
780 "err_mutbl with a closure invocation");
784 self.note_and_explain_mutbl_error(&mut db, &err, &error_span);
785 self.note_immutability_blame(&mut db, err.cmt.immutability_blame());
788 err_out_of_scope(super_scope, sub_scope, cause) => {
789 let msg = match opt_loan_path(&err.cmt) {
790 None => "borrowed value".to_string(),
792 format!("`{}`", self.loan_path_to_string(&lp))
796 // When you have a borrow that lives across a yield,
797 // that reference winds up captured in the generator
798 // type. Regionck then constraints it to live as long
799 // as the generator itself. If that borrow is borrowing
800 // data owned by the generator, this winds up resulting in
801 // an `err_out_of_scope` error:
806 // let a = &3; // this borrow is forced to ... -+
808 // println!("{}", a); // |
810 // } <----------------------... live until here --------+
813 // To detect this case, we look for cases where the
814 // `super_scope` (lifetime of the value) is within the
815 // body, but the `sub_scope` is not.
816 debug!("err_out_of_scope: self.body.is_generator = {:?}",
817 self.body.is_generator);
818 let maybe_borrow_across_yield = if self.body.is_generator {
819 let body_scope = region::Scope::Node(self.body.value.hir_id.local_id);
820 debug!("err_out_of_scope: body_scope = {:?}", body_scope);
821 debug!("err_out_of_scope: super_scope = {:?}", super_scope);
822 debug!("err_out_of_scope: sub_scope = {:?}", sub_scope);
823 match (super_scope, sub_scope) {
824 (&ty::RegionKind::ReScope(value_scope),
825 &ty::RegionKind::ReScope(loan_scope)) => {
827 // value_scope <= body_scope &&
828 self.region_scope_tree.is_subscope_of(value_scope, body_scope) &&
829 // body_scope <= loan_scope
830 self.region_scope_tree.is_subscope_of(body_scope, loan_scope)
832 // We now know that this is a case
833 // that fits the bill described above:
834 // a borrow of something whose scope
835 // is within the generator, but the
836 // borrow is for a scope outside the
839 // Now look within the scope of the of
840 // the value being borrowed (in the
841 // example above, that would be the
842 // block remainder that starts with
843 // `let a`) for a yield. We can cite
844 // that for the user.
845 self.region_scope_tree.yield_in_scope(value_scope)
856 if let Some((yield_span, _)) = maybe_borrow_across_yield {
857 debug!("err_out_of_scope: opt_yield_span = {:?}", yield_span);
858 struct_span_err!(self.tcx.sess,
861 "borrow may still be in use when generator yields")
862 .span_label(yield_span, "possible yield occurs here")
867 let mut db = struct_span_err!(self.tcx.sess,
870 "{} does not live long enough",
873 let (value_kind, value_msg) = match err.cmt.cat {
874 mc::Categorization::Rvalue(..) =>
875 ("temporary value", "temporary value created here"),
877 ("borrowed value", "borrow occurs here")
880 let is_closure = match cause {
881 euv::ClosureCapture(s) => {
882 // The primary span starts out as the closure creation point.
883 // Change the primary span here to highlight the use of the variable
884 // in the closure, because it seems more natural. Highlight
885 // closure creation point as a secondary span.
886 match db.span.primary_span() {
888 db.span = MultiSpan::from_span(s);
889 db.span_label(primary, "capture occurs here");
890 db.span_label(s, "does not live long enough");
897 db.span_label(error_span, "does not live long enough");
902 let sub_span = self.region_end_span(sub_scope);
903 let super_span = self.region_end_span(super_scope);
905 match (sub_span, super_span) {
906 (Some(s1), Some(s2)) if s1 == s2 => {
908 db.span = MultiSpan::from_span(s1);
909 db.span_label(error_span, value_msg);
910 let msg = match opt_loan_path(&err.cmt) {
911 None => value_kind.to_string(),
913 format!("`{}`", self.loan_path_to_string(&lp))
917 format!("{} dropped here while still borrowed", msg));
919 db.span_label(s1, format!("{} dropped before borrower", value_kind));
921 db.note("values in a scope are dropped in the opposite order \
924 (Some(s1), Some(s2)) if !is_closure => {
925 db.span = MultiSpan::from_span(s2);
926 db.span_label(error_span, value_msg);
927 let msg = match opt_loan_path(&err.cmt) {
928 None => value_kind.to_string(),
930 format!("`{}`", self.loan_path_to_string(&lp))
933 db.span_label(s2, format!("{} dropped here while still borrowed", msg));
934 db.span_label(s1, format!("{} needs to live until here", value_kind));
939 db.span_label(s, format!("{} needs to live until here",
943 self.tcx.note_and_explain_region(
944 &self.region_scope_tree,
946 "borrowed value must be valid for ",
953 db.span_label(s, format!("{} only lives until here", value_kind));
956 self.tcx.note_and_explain_region(
957 &self.region_scope_tree,
959 "...but borrowed value is only valid for ",
967 if let ty::ReScope(scope) = *super_scope {
968 let node_id = scope.node_id(self.tcx, &self.region_scope_tree);
969 match self.tcx.hir.find(node_id) {
970 Some(hir_map::NodeStmt(_)) => {
971 db.note("consider using a `let` binding to increase its lifetime");
979 err_borrowed_pointer_too_short(loan_scope, ptr_scope) => {
980 let descr = self.cmt_to_path_or_string(&err.cmt);
981 let mut db = struct_span_err!(self.tcx.sess, error_span, E0598,
982 "lifetime of {} is too short to guarantee \
983 its contents can be safely reborrowed",
986 let descr = match opt_loan_path(&err.cmt) {
988 format!("`{}`", self.loan_path_to_string(&lp))
990 None => self.cmt_to_string(&err.cmt),
992 self.tcx.note_and_explain_region(
993 &self.region_scope_tree,
995 &format!("{} would have to be valid for ",
999 self.tcx.note_and_explain_region(
1000 &self.region_scope_tree,
1002 &format!("...but {} is only valid for ", descr),
1011 pub fn report_aliasability_violation(&self,
1013 kind: AliasableViolationKind,
1014 cause: mc::AliasableReason,
1015 cmt: mc::cmt<'tcx>) {
1016 let mut is_closure = false;
1017 let prefix = match kind {
1018 MutabilityViolation => {
1019 "cannot assign to data"
1021 BorrowViolation(euv::ClosureCapture(_)) |
1022 BorrowViolation(euv::OverloadedOperator) |
1023 BorrowViolation(euv::AddrOf) |
1024 BorrowViolation(euv::AutoRef) |
1025 BorrowViolation(euv::AutoUnsafe) |
1026 BorrowViolation(euv::RefBinding) |
1027 BorrowViolation(euv::MatchDiscriminant) => {
1028 "cannot borrow data mutably"
1031 BorrowViolation(euv::ClosureInvocation) => {
1033 "closure invocation"
1036 BorrowViolation(euv::ForLoop) => {
1042 mc::AliasableStatic |
1043 mc::AliasableStaticMut => {
1044 // This path cannot occur. It happens when we have an
1045 // `&mut` or assignment to a static. But in the case
1046 // of `static X`, we get a mutability violation first,
1047 // and never get here. In the case of `static mut X`,
1048 // that is unsafe and hence the aliasability error is
1050 span_bug!(span, "aliasability violation for static `{}`", prefix)
1052 mc::AliasableBorrowed => {}
1054 let blame = cmt.immutability_blame();
1055 let mut err = match blame {
1056 Some(ImmutabilityBlame::ClosureEnv(id)) => {
1057 let mut err = struct_span_err!(
1058 self.tcx.sess, span, E0387,
1059 "{} in a captured outer variable in an `Fn` closure", prefix);
1061 // FIXME: the distinction between these 2 messages looks wrong.
1062 let help = if let BorrowViolation(euv::ClosureCapture(_)) = kind {
1063 // The aliasability violation with closure captures can
1064 // happen for nested closures, so we know the enclosing
1065 // closure incorrectly accepts an `Fn` while it needs to
1067 "consider changing this to accept closures that implement `FnMut`"
1070 "consider changing this closure to take self by mutable reference"
1072 let node_id = self.tcx.hir.def_index_to_node_id(id);
1073 err.span_help(self.tcx.hir.span(node_id), help);
1077 let mut err = struct_span_err!(
1078 self.tcx.sess, span, E0389,
1079 "{} in a `&` reference", prefix);
1080 err.span_label(span, "assignment into an immutable reference");
1084 self.note_immutability_blame(&mut err, blame);
1087 err.help("closures behind references must be called via `&mut`");
1092 /// Given a type, if it is an immutable reference, return a suggestion to make it mutable
1093 fn suggest_mut_for_immutable(&self, pty: &hir::Ty, is_implicit_self: bool) -> Option<String> {
1094 // Check wether the argument is an immutable reference
1095 debug!("suggest_mut_for_immutable({:?}, {:?})", pty, is_implicit_self);
1096 if let hir::TyRptr(lifetime, hir::MutTy {
1097 mutbl: hir::Mutability::MutImmutable,
1100 // Account for existing lifetimes when generating the message
1101 let pointee_snippet = match self.tcx.sess.codemap().span_to_snippet(ty.span) {
1102 Ok(snippet) => snippet,
1106 let lifetime_snippet = if !lifetime.is_elided() {
1107 format!("{} ", match self.tcx.sess.codemap().span_to_snippet(lifetime.span) {
1108 Ok(lifetime_snippet) => lifetime_snippet,
1114 Some(format!("use `&{}mut {}` here to make mutable",
1116 if is_implicit_self { "self" } else { &*pointee_snippet }))
1122 fn local_binding_mode(&self, node_id: ast::NodeId) -> ty::BindingMode {
1123 let pat = match self.tcx.hir.get(node_id) {
1124 hir_map::Node::NodeBinding(pat) => pat,
1125 node => bug!("bad node for local: {:?}", node)
1129 hir::PatKind::Binding(..) => {
1131 .pat_binding_modes()
1133 .expect("missing binding mode")
1135 _ => bug!("local is not a binding: {:?}", pat)
1139 fn local_ty(&self, node_id: ast::NodeId) -> (Option<&hir::Ty>, bool) {
1140 let parent = self.tcx.hir.get_parent_node(node_id);
1141 let parent_node = self.tcx.hir.get(parent);
1143 // The parent node is like a fn
1144 if let Some(fn_like) = FnLikeNode::from_node(parent_node) {
1145 // `nid`'s parent's `Body`
1146 let fn_body = self.tcx.hir.body(fn_like.body());
1147 // Get the position of `node_id` in the arguments list
1148 let arg_pos = fn_body.arguments.iter().position(|arg| arg.pat.id == node_id);
1149 if let Some(i) = arg_pos {
1150 // The argument's `Ty`
1151 (Some(&fn_like.decl().inputs[i]),
1152 i == 0 && fn_like.decl().has_implicit_self)
1161 fn note_immutability_blame(&self,
1162 db: &mut DiagnosticBuilder,
1163 blame: Option<ImmutabilityBlame>) {
1166 Some(ImmutabilityBlame::ClosureEnv(_)) => {}
1167 Some(ImmutabilityBlame::ImmLocal(node_id)) => {
1168 let let_span = self.tcx.hir.span(node_id);
1169 if let ty::BindByValue(..) = self.local_binding_mode(node_id) {
1170 if let Ok(snippet) = self.tcx.sess.codemap().span_to_snippet(let_span) {
1171 let (_, is_implicit_self) = self.local_ty(node_id);
1172 if is_implicit_self && snippet != "self" {
1173 // avoid suggesting `mut &self`.
1178 format!("consider changing this to `mut {}`", snippet)
1183 Some(ImmutabilityBlame::LocalDeref(node_id)) => {
1184 let let_span = self.tcx.hir.span(node_id);
1185 match self.local_binding_mode(node_id) {
1186 ty::BindByReference(..) => {
1187 let snippet = self.tcx.sess.codemap().span_to_snippet(let_span);
1188 if let Ok(snippet) = snippet {
1191 format!("consider changing this to `{}`",
1192 snippet.replace("ref ", "ref mut "))
1196 ty::BindByValue(..) => {
1197 if let (Some(local_ty), is_implicit_self) = self.local_ty(node_id) {
1199 self.suggest_mut_for_immutable(local_ty, is_implicit_self) {
1200 db.span_label(local_ty.span, msg);
1206 Some(ImmutabilityBlame::AdtFieldDeref(_, field)) => {
1207 let node_id = match self.tcx.hir.as_local_node_id(field.did) {
1208 Some(node_id) => node_id,
1212 if let hir_map::Node::NodeField(ref field) = self.tcx.hir.get(node_id) {
1213 if let Some(msg) = self.suggest_mut_for_immutable(&field.ty, false) {
1214 db.span_label(field.ty.span, msg);
1221 fn report_out_of_scope_escaping_closure_capture(&self,
1222 err: &BckError<'tcx>,
1225 let cmt_path_or_string = self.cmt_to_path_or_string(&err.cmt);
1228 match self.tcx.sess.codemap().span_to_snippet(err.span) {
1229 Ok(string) => format!("move {}", string),
1230 Err(_) => format!("move |<args>| <body>")
1233 struct_span_err!(self.tcx.sess, err.span, E0373,
1234 "closure may outlive the current function, \
1235 but it borrows {}, \
1236 which is owned by the current function",
1238 .span_label(capture_span,
1239 format!("{} is borrowed here",
1240 cmt_path_or_string))
1241 .span_label(err.span,
1242 format!("may outlive borrowed value {}",
1243 cmt_path_or_string))
1244 .span_suggestion(err.span,
1245 &format!("to force the closure to take ownership of {} \
1246 (and any other referenced variables), \
1247 use the `move` keyword",
1248 cmt_path_or_string),
1253 fn region_end_span(&self, region: ty::Region<'tcx>) -> Option<Span> {
1255 ty::ReScope(scope) => {
1256 Some(scope.span(self.tcx, &self.region_scope_tree).end_point())
1262 fn note_and_explain_mutbl_error(&self, db: &mut DiagnosticBuilder, err: &BckError<'tcx>,
1263 error_span: &Span) {
1264 match err.cmt.note {
1265 mc::NoteClosureEnv(upvar_id) | mc::NoteUpvarRef(upvar_id) => {
1266 // If this is an `Fn` closure, it simply can't mutate upvars.
1267 // If it's an `FnMut` closure, the original variable was declared immutable.
1268 // We need to determine which is the case here.
1269 let kind = match err.cmt.upvar().unwrap().cat {
1270 Categorization::Upvar(mc::Upvar { kind, .. }) => kind,
1273 if kind == ty::ClosureKind::Fn {
1274 let closure_node_id =
1275 self.tcx.hir.def_index_to_node_id(upvar_id.closure_expr_id);
1276 db.span_help(self.tcx.hir.span(closure_node_id),
1277 "consider changing this closure to take \
1278 self by mutable reference");
1282 if let Categorization::Deref(..) = err.cmt.cat {
1283 db.span_label(*error_span, "cannot borrow as mutable");
1284 } else if let Categorization::Local(local_id) = err.cmt.cat {
1285 let span = self.tcx.hir.span(local_id);
1286 if let Ok(snippet) = self.tcx.sess.codemap().span_to_snippet(span) {
1287 if snippet.starts_with("ref mut ") || snippet.starts_with("&mut ") {
1288 db.span_label(*error_span, "cannot reborrow mutably");
1289 db.span_label(*error_span, "try removing `&mut` here");
1291 db.span_label(*error_span, "cannot borrow mutably");
1294 db.span_label(*error_span, "cannot borrow mutably");
1296 } else if let Categorization::Interior(ref cmt, _) = err.cmt.cat {
1297 if let mc::MutabilityCategory::McImmutable = cmt.mutbl {
1298 db.span_label(*error_span,
1299 "cannot mutably borrow immutable field");
1305 pub fn append_loan_path_to_string(&self,
1306 loan_path: &LoanPath<'tcx>,
1308 match loan_path.kind {
1309 LpUpvar(ty::UpvarId { var_id: id, closure_expr_id: _ }) => {
1310 out.push_str(&self.tcx.hir.name(self.tcx.hir.hir_to_node_id(id)).as_str());
1313 out.push_str(&self.tcx.hir.name(id).as_str());
1316 LpDowncast(ref lp_base, variant_def_id) => {
1318 self.append_loan_path_to_string(&lp_base, out);
1319 out.push_str(DOWNCAST_PRINTED_OPERATOR);
1320 out.push_str(&self.tcx.item_path_str(variant_def_id));
1324 LpExtend(ref lp_base, _, LpInterior(_, InteriorField(fname))) => {
1325 self.append_autoderefd_loan_path_to_string(&lp_base, out);
1327 mc::NamedField(fname) => {
1329 out.push_str(&fname.as_str());
1331 mc::PositionalField(idx) => {
1333 out.push_str(&idx.to_string());
1338 LpExtend(ref lp_base, _, LpInterior(_, InteriorElement)) => {
1339 self.append_autoderefd_loan_path_to_string(&lp_base, out);
1340 out.push_str("[..]");
1343 LpExtend(ref lp_base, _, LpDeref(_)) => {
1345 self.append_loan_path_to_string(&lp_base, out);
1350 pub fn append_autoderefd_loan_path_to_string(&self,
1351 loan_path: &LoanPath<'tcx>,
1353 match loan_path.kind {
1354 LpExtend(ref lp_base, _, LpDeref(_)) => {
1355 // For a path like `(*x).f` or `(*x)[3]`, autoderef
1356 // rules would normally allow users to omit the `*x`.
1357 // So just serialize such paths to `x.f` or x[3]` respectively.
1358 self.append_autoderefd_loan_path_to_string(&lp_base, out)
1361 LpDowncast(ref lp_base, variant_def_id) => {
1363 self.append_autoderefd_loan_path_to_string(&lp_base, out);
1365 out.push_str(&self.tcx.item_path_str(variant_def_id));
1369 LpVar(..) | LpUpvar(..) | LpExtend(.., LpInterior(..)) => {
1370 self.append_loan_path_to_string(loan_path, out)
1375 pub fn loan_path_to_string(&self, loan_path: &LoanPath<'tcx>) -> String {
1376 let mut result = String::new();
1377 self.append_loan_path_to_string(loan_path, &mut result);
1381 pub fn cmt_to_string(&self, cmt: &mc::cmt_<'tcx>) -> String {
1382 cmt.descriptive_string(self.tcx)
1385 pub fn cmt_to_path_or_string(&self, cmt: &mc::cmt<'tcx>) -> String {
1386 match opt_loan_path(cmt) {
1387 Some(lp) => format!("`{}`", self.loan_path_to_string(&lp)),
1388 None => self.cmt_to_string(cmt),
1393 impl BitwiseOperator for LoanDataFlowOperator {
1395 fn join(&self, succ: usize, pred: usize) -> usize {
1396 succ | pred // loans from both preds are in scope
1400 impl DataFlowOperator for LoanDataFlowOperator {
1402 fn initial_value(&self) -> bool {
1403 false // no loans in scope by default
1407 impl<'tcx> fmt::Debug for InteriorKind {
1408 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1410 InteriorField(mc::NamedField(fld)) => write!(f, "{}", fld),
1411 InteriorField(mc::PositionalField(i)) => write!(f, "#{}", i),
1412 InteriorElement => write!(f, "[]"),
1417 impl<'tcx> fmt::Debug for Loan<'tcx> {
1418 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1419 write!(f, "Loan_{}({:?}, {:?}, {:?}-{:?}, {:?})",
1425 self.restricted_paths)
1429 impl<'tcx> fmt::Debug for LoanPath<'tcx> {
1430 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1433 write!(f, "$({})", ty::tls::with(|tcx| tcx.hir.node_to_string(id)))
1436 LpUpvar(ty::UpvarId{ var_id, closure_expr_id }) => {
1437 let s = ty::tls::with(|tcx| {
1438 let var_node_id = tcx.hir.hir_to_node_id(var_id);
1439 tcx.hir.node_to_string(var_node_id)
1441 write!(f, "$({} captured by id={:?})", s, closure_expr_id)
1444 LpDowncast(ref lp, variant_def_id) => {
1445 let variant_str = if variant_def_id.is_local() {
1446 ty::tls::with(|tcx| tcx.item_path_str(variant_def_id))
1448 format!("{:?}", variant_def_id)
1450 write!(f, "({:?}{}{})", lp, DOWNCAST_PRINTED_OPERATOR, variant_str)
1453 LpExtend(ref lp, _, LpDeref(_)) => {
1454 write!(f, "{:?}.*", lp)
1457 LpExtend(ref lp, _, LpInterior(_, ref interior)) => {
1458 write!(f, "{:?}.{:?}", lp, interior)
1464 impl<'tcx> fmt::Display for LoanPath<'tcx> {
1465 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1468 write!(f, "$({})", ty::tls::with(|tcx| tcx.hir.node_to_user_string(id)))
1471 LpUpvar(ty::UpvarId{ var_id, closure_expr_id: _ }) => {
1472 let s = ty::tls::with(|tcx| {
1473 let var_node_id = tcx.hir.hir_to_node_id(var_id);
1474 tcx.hir.node_to_string(var_node_id)
1476 write!(f, "$({} captured by closure)", s)
1479 LpDowncast(ref lp, variant_def_id) => {
1480 let variant_str = if variant_def_id.is_local() {
1481 ty::tls::with(|tcx| tcx.item_path_str(variant_def_id))
1483 format!("{:?}", variant_def_id)
1485 write!(f, "({}{}{})", lp, DOWNCAST_PRINTED_OPERATOR, variant_str)
1488 LpExtend(ref lp, _, LpDeref(_)) => {
1489 write!(f, "{}.*", lp)
1492 LpExtend(ref lp, _, LpInterior(_, ref interior)) => {
1493 write!(f, "{}.{:?}", lp, interior)