1 // Copyright 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 // Type resolution: the phase that finds all the types in the AST with
12 // unresolved type variables and replaces "ty_var" types with their
14 use self::ResolveReason::*;
18 use middle::def_id::DefId;
20 use middle::ty::{self, Ty, MethodCall, MethodCallee, HasTypeFlags};
21 use middle::ty::adjustment;
22 use middle::ty::fold::{TypeFolder,TypeFoldable};
24 use write_substs_to_tcx;
30 use syntax::codemap::{DUMMY_SP, Span};
31 use rustc_front::print::pprust::pat_to_string;
32 use rustc_front::visit;
33 use rustc_front::visit::Visitor;
34 use rustc_front::util as hir_util;
37 ///////////////////////////////////////////////////////////////////////////
38 // Entry point functions
40 pub fn resolve_type_vars_in_expr(fcx: &FnCtxt, e: &hir::Expr) {
41 assert_eq!(fcx.writeback_errors.get(), false);
42 let mut wbcx = WritebackCx::new(fcx);
44 wbcx.visit_upvar_borrow_map();
45 wbcx.visit_closures();
48 pub fn resolve_type_vars_in_fn(fcx: &FnCtxt,
51 assert_eq!(fcx.writeback_errors.get(), false);
52 let mut wbcx = WritebackCx::new(fcx);
53 wbcx.visit_block(blk);
54 for arg in &decl.inputs {
55 wbcx.visit_node_id(ResolvingPattern(arg.pat.span), arg.id);
56 wbcx.visit_pat(&*arg.pat);
58 // Privacy needs the type for the whole pattern, not just each binding
59 if !pat_util::pat_is_binding(&fcx.tcx().def_map, &*arg.pat) {
60 wbcx.visit_node_id(ResolvingPattern(arg.pat.span),
64 wbcx.visit_upvar_borrow_map();
65 wbcx.visit_closures();
68 ///////////////////////////////////////////////////////////////////////////
69 // The Writerback context. This visitor walks the AST, checking the
70 // fn-specific tables to find references to types or regions. It
71 // resolves those regions to remove inference variables and writes the
72 // final result back into the master tables in the tcx. Here and
73 // there, it applies a few ad-hoc checks that were not convenient to
76 struct WritebackCx<'cx, 'tcx: 'cx> {
77 fcx: &'cx FnCtxt<'cx, 'tcx>,
80 impl<'cx, 'tcx> WritebackCx<'cx, 'tcx> {
81 fn new(fcx: &'cx FnCtxt<'cx, 'tcx>) -> WritebackCx<'cx, 'tcx> {
82 WritebackCx { fcx: fcx }
85 fn tcx(&self) -> &'cx ty::ctxt<'tcx> {
89 // Hacky hack: During type-checking, we treat *all* operators
90 // as potentially overloaded. But then, during writeback, if
91 // we observe that something like `a+b` is (known to be)
92 // operating on scalars, we clear the overload.
93 fn fix_scalar_binary_expr(&mut self, e: &hir::Expr) {
95 hir::ExprBinary(ref op, ref lhs, ref rhs) |
96 hir::ExprAssignOp(ref op, ref lhs, ref rhs) => {
97 let lhs_ty = self.fcx.node_ty(lhs.id);
98 let lhs_ty = self.fcx.infcx().resolve_type_vars_if_possible(&lhs_ty);
100 let rhs_ty = self.fcx.node_ty(rhs.id);
101 let rhs_ty = self.fcx.infcx().resolve_type_vars_if_possible(&rhs_ty);
103 if lhs_ty.is_scalar() && rhs_ty.is_scalar() {
104 self.fcx.inh.tables.borrow_mut().method_map.remove(&MethodCall::expr(e.id));
106 // weird but true: the by-ref binops put an
107 // adjustment on the lhs but not the rhs; the
108 // adjustment for rhs is kind of baked into the
111 hir::ExprBinary(..) => {
112 if !hir_util::is_by_value_binop(op.node) {
113 self.fcx.inh.tables.borrow_mut().adjustments.remove(&lhs.id);
116 hir::ExprAssignOp(..) => {
117 self.fcx.inh.tables.borrow_mut().adjustments.remove(&lhs.id);
122 let tcx = self.tcx();
124 if let hir::ExprAssignOp(..) = e.node {
126 !tcx.sess.features.borrow().augmented_assignments &&
127 !self.fcx.expr_ty(e).references_error()
131 "overloaded augmented assignments are not stable");
134 "add #![feature(augmented_assignments)] to the crate features \
145 ///////////////////////////////////////////////////////////////////////////
146 // Impl of Visitor for Resolver
148 // This is the master code which walks the AST. It delegates most of
149 // the heavy lifting to the generic visit and resolve functions
150 // below. In general, a function is made into a `visitor` if it must
151 // traffic in node-ids or update tables in the type context etc.
153 impl<'cx, 'tcx, 'v> Visitor<'v> for WritebackCx<'cx, 'tcx> {
154 fn visit_item(&mut self, _: &hir::Item) {
158 fn visit_stmt(&mut self, s: &hir::Stmt) {
159 if self.fcx.writeback_errors.get() {
163 self.visit_node_id(ResolvingExpr(s.span), hir_util::stmt_id(s));
164 visit::walk_stmt(self, s);
167 fn visit_expr(&mut self, e: &hir::Expr) {
168 if self.fcx.writeback_errors.get() {
172 self.fix_scalar_binary_expr(e);
174 self.visit_node_id(ResolvingExpr(e.span), e.id);
175 self.visit_method_map_entry(ResolvingExpr(e.span),
176 MethodCall::expr(e.id));
178 if let hir::ExprClosure(_, ref decl, _) = e.node {
179 for input in &decl.inputs {
180 self.visit_node_id(ResolvingExpr(e.span), input.id);
184 visit::walk_expr(self, e);
187 fn visit_block(&mut self, b: &hir::Block) {
188 if self.fcx.writeback_errors.get() {
192 self.visit_node_id(ResolvingExpr(b.span), b.id);
193 visit::walk_block(self, b);
196 fn visit_pat(&mut self, p: &hir::Pat) {
197 if self.fcx.writeback_errors.get() {
201 self.visit_node_id(ResolvingPattern(p.span), p.id);
203 debug!("Type for pattern binding {} (id {}) resolved to {:?}",
206 self.tcx().node_id_to_type(p.id));
208 visit::walk_pat(self, p);
211 fn visit_local(&mut self, l: &hir::Local) {
212 if self.fcx.writeback_errors.get() {
216 let var_ty = self.fcx.local_ty(l.span, l.id);
217 let var_ty = self.resolve(&var_ty, ResolvingLocal(l.span));
218 write_ty_to_tcx(self.tcx(), l.id, var_ty);
219 visit::walk_local(self, l);
222 fn visit_ty(&mut self, t: &hir::Ty) {
224 hir::TyFixedLengthVec(ref ty, ref count_expr) => {
225 self.visit_ty(&**ty);
226 write_ty_to_tcx(self.tcx(), count_expr.id, self.tcx().types.usize);
228 _ => visit::walk_ty(self, t)
233 impl<'cx, 'tcx> WritebackCx<'cx, 'tcx> {
234 fn visit_upvar_borrow_map(&self) {
235 if self.fcx.writeback_errors.get() {
239 for (upvar_id, upvar_capture) in self.fcx.inh.tables.borrow().upvar_capture_map.iter() {
240 let new_upvar_capture = match *upvar_capture {
241 ty::UpvarCapture::ByValue => ty::UpvarCapture::ByValue,
242 ty::UpvarCapture::ByRef(ref upvar_borrow) => {
243 let r = upvar_borrow.region;
244 let r = self.resolve(&r, ResolvingUpvar(*upvar_id));
245 ty::UpvarCapture::ByRef(
246 ty::UpvarBorrow { kind: upvar_borrow.kind, region: r })
249 debug!("Upvar capture for {:?} resolved to {:?}",
256 .insert(*upvar_id, new_upvar_capture);
260 fn visit_closures(&self) {
261 if self.fcx.writeback_errors.get() {
265 for (def_id, closure_ty) in self.fcx.inh.tables.borrow().closure_tys.iter() {
266 let closure_ty = self.resolve(closure_ty, ResolvingClosure(*def_id));
267 self.fcx.tcx().tables.borrow_mut().closure_tys.insert(*def_id, closure_ty);
270 for (def_id, &closure_kind) in self.fcx.inh.tables.borrow().closure_kinds.iter() {
271 self.fcx.tcx().tables.borrow_mut().closure_kinds.insert(*def_id, closure_kind);
275 fn visit_node_id(&self, reason: ResolveReason, id: ast::NodeId) {
276 // Resolve any borrowings for the node with id `id`
277 self.visit_adjustments(reason, id);
279 // Resolve the type of the node with id `id`
280 let n_ty = self.fcx.node_ty(id);
281 let n_ty = self.resolve(&n_ty, reason);
282 write_ty_to_tcx(self.tcx(), id, n_ty);
283 debug!("Node {} has type {:?}", id, n_ty);
285 // Resolve any substitutions
286 self.fcx.opt_node_ty_substs(id, |item_substs| {
287 write_substs_to_tcx(self.tcx(), id,
288 self.resolve(item_substs, reason));
292 fn visit_adjustments(&self, reason: ResolveReason, id: ast::NodeId) {
293 let adjustments = self.fcx.inh.tables.borrow_mut().adjustments.remove(&id);
296 debug!("No adjustments for node {}", id);
299 Some(adjustment) => {
300 let resolved_adjustment = match adjustment {
301 adjustment::AdjustReifyFnPointer => {
302 adjustment::AdjustReifyFnPointer
305 adjustment::AdjustUnsafeFnPointer => {
306 adjustment::AdjustUnsafeFnPointer
309 adjustment::AdjustDerefRef(adj) => {
310 for autoderef in 0..adj.autoderefs {
311 let method_call = MethodCall::autoderef(id, autoderef as u32);
312 self.visit_method_map_entry(reason, method_call);
315 adjustment::AdjustDerefRef(adjustment::AutoDerefRef {
316 autoderefs: adj.autoderefs,
317 autoref: self.resolve(&adj.autoref, reason),
318 unsize: self.resolve(&adj.unsize, reason),
322 debug!("Adjustments for node {}: {:?}", id, resolved_adjustment);
323 self.tcx().tables.borrow_mut().adjustments.insert(
324 id, resolved_adjustment);
329 fn visit_method_map_entry(&self,
330 reason: ResolveReason,
331 method_call: MethodCall) {
332 // Resolve any method map entry
333 let new_method = match self.fcx.inh.tables.borrow_mut().method_map.remove(&method_call) {
335 debug!("writeback::resolve_method_map_entry(call={:?}, entry={:?})",
338 let new_method = MethodCallee {
339 def_id: method.def_id,
340 ty: self.resolve(&method.ty, reason),
341 substs: self.tcx().mk_substs(self.resolve(method.substs, reason)),
349 //NB(jroesch): We need to match twice to avoid a double borrow which would cause an ICE
352 self.tcx().tables.borrow_mut().method_map.insert(
360 fn resolve<T:TypeFoldable<'tcx>>(&self, t: &T, reason: ResolveReason) -> T {
361 t.fold_with(&mut Resolver::new(self.fcx, reason))
365 ///////////////////////////////////////////////////////////////////////////
366 // Resolution reason.
368 #[derive(Copy, Clone)]
371 ResolvingLocal(Span),
372 ResolvingPattern(Span),
373 ResolvingUpvar(ty::UpvarId),
374 ResolvingClosure(DefId),
378 fn span(&self, tcx: &ty::ctxt) -> Span {
380 ResolvingExpr(s) => s,
381 ResolvingLocal(s) => s,
382 ResolvingPattern(s) => s,
383 ResolvingUpvar(upvar_id) => {
384 tcx.expr_span(upvar_id.closure_expr_id)
386 ResolvingClosure(did) => {
388 tcx.expr_span(did.node)
397 ///////////////////////////////////////////////////////////////////////////
398 // The Resolver. This is the type folding engine that detects
399 // unresolved types and so forth.
401 struct Resolver<'cx, 'tcx: 'cx> {
402 tcx: &'cx ty::ctxt<'tcx>,
403 infcx: &'cx infer::InferCtxt<'cx, 'tcx>,
404 writeback_errors: &'cx Cell<bool>,
405 reason: ResolveReason,
408 impl<'cx, 'tcx> Resolver<'cx, 'tcx> {
409 fn new(fcx: &'cx FnCtxt<'cx, 'tcx>,
410 reason: ResolveReason)
411 -> Resolver<'cx, 'tcx>
413 Resolver::from_infcx(fcx.infcx(), &fcx.writeback_errors, reason)
416 fn from_infcx(infcx: &'cx infer::InferCtxt<'cx, 'tcx>,
417 writeback_errors: &'cx Cell<bool>,
418 reason: ResolveReason)
419 -> Resolver<'cx, 'tcx>
421 Resolver { infcx: infcx,
423 writeback_errors: writeback_errors,
427 fn report_error(&self, e: infer::FixupError) {
428 self.writeback_errors.set(true);
429 if !self.tcx.sess.has_errors() {
431 ResolvingExpr(span) => {
432 span_err!(self.tcx.sess, span, E0101,
433 "cannot determine a type for this expression: {}",
434 infer::fixup_err_to_string(e));
437 ResolvingLocal(span) => {
438 span_err!(self.tcx.sess, span, E0102,
439 "cannot determine a type for this local variable: {}",
440 infer::fixup_err_to_string(e));
443 ResolvingPattern(span) => {
444 span_err!(self.tcx.sess, span, E0103,
445 "cannot determine a type for this pattern binding: {}",
446 infer::fixup_err_to_string(e));
449 ResolvingUpvar(upvar_id) => {
450 let span = self.reason.span(self.tcx);
451 span_err!(self.tcx.sess, span, E0104,
452 "cannot resolve lifetime for captured variable `{}`: {}",
453 self.tcx.local_var_name_str(upvar_id.var_id).to_string(),
454 infer::fixup_err_to_string(e));
457 ResolvingClosure(_) => {
458 let span = self.reason.span(self.tcx);
459 span_err!(self.tcx.sess, span, E0196,
460 "cannot determine a type for this closure")
467 impl<'cx, 'tcx> TypeFolder<'tcx> for Resolver<'cx, 'tcx> {
468 fn tcx<'a>(&'a self) -> &'a ty::ctxt<'tcx> {
472 fn fold_ty(&mut self, t: Ty<'tcx>) -> Ty<'tcx> {
473 match self.infcx.fully_resolve(&t) {
476 debug!("Resolver::fold_ty: input type `{:?}` not fully resolvable",
478 self.report_error(e);
484 fn fold_region(&mut self, r: ty::Region) -> ty::Region {
485 match self.infcx.fully_resolve(&r) {
488 self.report_error(e);
495 ///////////////////////////////////////////////////////////////////////////
496 // During type check, we store promises with the result of trait
497 // lookup rather than the actual results (because the results are not
498 // necessarily available immediately). These routines unwind the
499 // promises. It is expected that we will have already reported any
500 // errors that may be encountered, so if the promises store an error,
501 // a dummy result is returned.