1 //! Code related to processing overloaded binary and unary operators.
3 use super::method::MethodCallee;
4 use super::{has_expected_num_generic_args, FnCtxt};
6 use rustc_errors::{self, struct_span_err, Applicability, DiagnosticBuilder};
8 use rustc_infer::infer::type_variable::{TypeVariableOrigin, TypeVariableOriginKind};
9 use rustc_middle::ty::adjustment::{
10 Adjust, Adjustment, AllowTwoPhase, AutoBorrow, AutoBorrowMutability,
12 use rustc_middle::ty::fold::TypeFolder;
13 use rustc_middle::ty::TyKind::{Adt, Array, Char, FnDef, Never, Ref, Str, Tuple, Uint};
14 use rustc_middle::ty::{
15 self, suggest_constraining_type_param, Ty, TyCtxt, TypeFoldable, TypeVisitor,
17 use rustc_span::source_map::Spanned;
18 use rustc_span::symbol::{sym, Ident};
20 use rustc_trait_selection::infer::InferCtxtExt;
21 use rustc_trait_selection::traits::{FulfillmentError, TraitEngine, TraitEngineExt};
23 use std::ops::ControlFlow;
25 impl<'a, 'tcx> FnCtxt<'a, 'tcx> {
26 /// Checks a `a <op>= b`
27 pub fn check_binop_assign(
29 expr: &'tcx hir::Expr<'tcx>,
31 lhs: &'tcx hir::Expr<'tcx>,
32 rhs: &'tcx hir::Expr<'tcx>,
34 let (lhs_ty, rhs_ty, return_ty) =
35 self.check_overloaded_binop(expr, lhs, rhs, op, IsAssign::Yes);
38 if !lhs_ty.is_ty_var() && !rhs_ty.is_ty_var() && is_builtin_binop(lhs_ty, rhs_ty, op) {
39 self.enforce_builtin_binop_types(&lhs.span, lhs_ty, &rhs.span, rhs_ty, op);
45 self.check_lhs_assignable(lhs, "E0067", op.span);
50 /// Checks a potentially overloaded binary operator.
53 expr: &'tcx hir::Expr<'tcx>,
55 lhs_expr: &'tcx hir::Expr<'tcx>,
56 rhs_expr: &'tcx hir::Expr<'tcx>,
61 "check_binop(expr.hir_id={}, expr={:?}, op={:?}, lhs_expr={:?}, rhs_expr={:?})",
62 expr.hir_id, expr, op, lhs_expr, rhs_expr
65 match BinOpCategory::from(op) {
66 BinOpCategory::Shortcircuit => {
67 // && and || are a simple case.
68 self.check_expr_coercable_to_type(lhs_expr, tcx.types.bool, None);
69 let lhs_diverges = self.diverges.get();
70 self.check_expr_coercable_to_type(rhs_expr, tcx.types.bool, None);
72 // Depending on the LHS' value, the RHS can never execute.
73 self.diverges.set(lhs_diverges);
78 // Otherwise, we always treat operators as if they are
79 // overloaded. This is the way to be most flexible w/r/t
80 // types that get inferred.
81 let (lhs_ty, rhs_ty, return_ty) =
82 self.check_overloaded_binop(expr, lhs_expr, rhs_expr, op, IsAssign::No);
84 // Supply type inference hints if relevant. Probably these
85 // hints should be enforced during select as part of the
86 // `consider_unification_despite_ambiguity` routine, but this
87 // more convenient for now.
89 // The basic idea is to help type inference by taking
90 // advantage of things we know about how the impls for
91 // scalar types are arranged. This is important in a
92 // scenario like `1_u32 << 2`, because it lets us quickly
93 // deduce that the result type should be `u32`, even
94 // though we don't know yet what type 2 has and hence
95 // can't pin this down to a specific impl.
96 if !lhs_ty.is_ty_var()
97 && !rhs_ty.is_ty_var()
98 && is_builtin_binop(lhs_ty, rhs_ty, op)
100 let builtin_return_ty = self.enforce_builtin_binop_types(
107 self.demand_suptype(expr.span, builtin_return_ty, return_ty);
115 fn enforce_builtin_binop_types(
123 debug_assert!(is_builtin_binop(lhs_ty, rhs_ty, op));
125 // Special-case a single layer of referencing, so that things like `5.0 + &6.0f32` work.
126 // (See https://github.com/rust-lang/rust/issues/57447.)
127 let (lhs_ty, rhs_ty) = (deref_ty_if_possible(lhs_ty), deref_ty_if_possible(rhs_ty));
130 match BinOpCategory::from(op) {
131 BinOpCategory::Shortcircuit => {
132 self.demand_suptype(*lhs_span, tcx.types.bool, lhs_ty);
133 self.demand_suptype(*rhs_span, tcx.types.bool, rhs_ty);
137 BinOpCategory::Shift => {
138 // result type is same as LHS always
142 BinOpCategory::Math | BinOpCategory::Bitwise => {
143 // both LHS and RHS and result will have the same type
144 self.demand_suptype(*rhs_span, lhs_ty, rhs_ty);
148 BinOpCategory::Comparison => {
149 // both LHS and RHS and result will have the same type
150 self.demand_suptype(*rhs_span, lhs_ty, rhs_ty);
156 fn check_overloaded_binop(
158 expr: &'tcx hir::Expr<'tcx>,
159 lhs_expr: &'tcx hir::Expr<'tcx>,
160 rhs_expr: &'tcx hir::Expr<'tcx>,
163 ) -> (Ty<'tcx>, Ty<'tcx>, Ty<'tcx>) {
165 "check_overloaded_binop(expr.hir_id={}, op={:?}, is_assign={:?})",
166 expr.hir_id, op, is_assign
169 let lhs_ty = match is_assign {
171 // Find a suitable supertype of the LHS expression's type, by coercing to
172 // a type variable, to pass as the `Self` to the trait, avoiding invariant
173 // trait matching creating lifetime constraints that are too strict.
174 // e.g., adding `&'a T` and `&'b T`, given `&'x T: Add<&'x T>`, will result
175 // in `&'a T <: &'x T` and `&'b T <: &'x T`, instead of `'a = 'b = 'x`.
176 let lhs_ty = self.check_expr(lhs_expr);
177 let fresh_var = self.next_ty_var(TypeVariableOrigin {
178 kind: TypeVariableOriginKind::MiscVariable,
181 self.demand_coerce(lhs_expr, lhs_ty, fresh_var, Some(rhs_expr), AllowTwoPhase::No)
184 // rust-lang/rust#52126: We have to use strict
185 // equivalence on the LHS of an assign-op like `+=`;
186 // overwritten or mutably-borrowed places cannot be
187 // coerced to a supertype.
188 self.check_expr(lhs_expr)
191 let lhs_ty = self.resolve_vars_with_obligations(lhs_ty);
193 // N.B., as we have not yet type-checked the RHS, we don't have the
194 // type at hand. Make a variable to represent it. The whole reason
195 // for this indirection is so that, below, we can check the expr
196 // using this variable as the expected type, which sometimes lets
197 // us do better coercions than we would be able to do otherwise,
198 // particularly for things like `String + &String`.
199 let rhs_ty_var = self.next_ty_var(TypeVariableOrigin {
200 kind: TypeVariableOriginKind::MiscVariable,
204 let result = self.lookup_op_method(lhs_ty, &[rhs_ty_var], Op::Binary(op, is_assign));
207 let rhs_ty = self.check_expr_coercable_to_type(rhs_expr, rhs_ty_var, Some(lhs_expr));
208 let rhs_ty = self.resolve_vars_with_obligations(rhs_ty);
210 let return_ty = match result {
212 let by_ref_binop = !op.node.is_by_value();
213 if is_assign == IsAssign::Yes || by_ref_binop {
214 if let ty::Ref(region, _, mutbl) = method.sig.inputs()[0].kind() {
215 let mutbl = match mutbl {
216 hir::Mutability::Not => AutoBorrowMutability::Not,
217 hir::Mutability::Mut => AutoBorrowMutability::Mut {
218 // Allow two-phase borrows for binops in initial deployment
219 // since they desugar to methods
220 allow_two_phase_borrow: AllowTwoPhase::Yes,
223 let autoref = Adjustment {
224 kind: Adjust::Borrow(AutoBorrow::Ref(*region, mutbl)),
225 target: method.sig.inputs()[0],
227 self.apply_adjustments(lhs_expr, vec![autoref]);
231 if let ty::Ref(region, _, mutbl) = method.sig.inputs()[1].kind() {
232 let mutbl = match mutbl {
233 hir::Mutability::Not => AutoBorrowMutability::Not,
234 hir::Mutability::Mut => AutoBorrowMutability::Mut {
235 // Allow two-phase borrows for binops in initial deployment
236 // since they desugar to methods
237 allow_two_phase_borrow: AllowTwoPhase::Yes,
240 let autoref = Adjustment {
241 kind: Adjust::Borrow(AutoBorrow::Ref(*region, mutbl)),
242 target: method.sig.inputs()[1],
244 // HACK(eddyb) Bypass checks due to reborrows being in
245 // some cases applied on the RHS, on top of which we need
246 // to autoref, which is not allowed by apply_adjustments.
247 // self.apply_adjustments(rhs_expr, vec![autoref]);
251 .entry(rhs_expr.hir_id)
256 self.write_method_call(expr.hir_id, method);
260 // error types are considered "builtin"
261 Err(_) if lhs_ty.references_error() || rhs_ty.references_error() => self.tcx.ty_error(),
263 let source_map = self.tcx.sess.source_map();
264 let (mut err, missing_trait, use_output) = match is_assign {
266 let mut err = struct_span_err!(
270 "binary assignment operation `{}=` cannot be applied to type `{}`",
276 format!("cannot use `{}=` on type `{}`", op.node.as_str(), lhs_ty),
278 let missing_trait = match op.node {
279 hir::BinOpKind::Add => Some("std::ops::AddAssign"),
280 hir::BinOpKind::Sub => Some("std::ops::SubAssign"),
281 hir::BinOpKind::Mul => Some("std::ops::MulAssign"),
282 hir::BinOpKind::Div => Some("std::ops::DivAssign"),
283 hir::BinOpKind::Rem => Some("std::ops::RemAssign"),
284 hir::BinOpKind::BitAnd => Some("std::ops::BitAndAssign"),
285 hir::BinOpKind::BitXor => Some("std::ops::BitXorAssign"),
286 hir::BinOpKind::BitOr => Some("std::ops::BitOrAssign"),
287 hir::BinOpKind::Shl => Some("std::ops::ShlAssign"),
288 hir::BinOpKind::Shr => Some("std::ops::ShrAssign"),
291 self.note_unmet_impls_on_type(&mut err, errors);
292 (err, missing_trait, false)
295 let (message, missing_trait, use_output) = match op.node {
296 hir::BinOpKind::Add => (
297 format!("cannot add `{}` to `{}`", rhs_ty, lhs_ty),
298 Some("std::ops::Add"),
301 hir::BinOpKind::Sub => (
302 format!("cannot subtract `{}` from `{}`", rhs_ty, lhs_ty),
303 Some("std::ops::Sub"),
306 hir::BinOpKind::Mul => (
307 format!("cannot multiply `{}` by `{}`", lhs_ty, rhs_ty),
308 Some("std::ops::Mul"),
311 hir::BinOpKind::Div => (
312 format!("cannot divide `{}` by `{}`", lhs_ty, rhs_ty),
313 Some("std::ops::Div"),
316 hir::BinOpKind::Rem => (
317 format!("cannot mod `{}` by `{}`", lhs_ty, rhs_ty),
318 Some("std::ops::Rem"),
321 hir::BinOpKind::BitAnd => (
322 format!("no implementation for `{} & {}`", lhs_ty, rhs_ty),
323 Some("std::ops::BitAnd"),
326 hir::BinOpKind::BitXor => (
327 format!("no implementation for `{} ^ {}`", lhs_ty, rhs_ty),
328 Some("std::ops::BitXor"),
331 hir::BinOpKind::BitOr => (
332 format!("no implementation for `{} | {}`", lhs_ty, rhs_ty),
333 Some("std::ops::BitOr"),
336 hir::BinOpKind::Shl => (
337 format!("no implementation for `{} << {}`", lhs_ty, rhs_ty),
338 Some("std::ops::Shl"),
341 hir::BinOpKind::Shr => (
342 format!("no implementation for `{} >> {}`", lhs_ty, rhs_ty),
343 Some("std::ops::Shr"),
346 hir::BinOpKind::Eq | hir::BinOpKind::Ne => (
348 "binary operation `{}` cannot be applied to type `{}`",
352 Some("std::cmp::PartialEq"),
358 | hir::BinOpKind::Ge => (
360 "binary operation `{}` cannot be applied to type `{}`",
364 Some("std::cmp::PartialOrd"),
369 "binary operation `{}` cannot be applied to type `{}`",
378 struct_span_err!(self.tcx.sess, op.span, E0369, "{}", message.as_str());
379 if !lhs_expr.span.eq(&rhs_expr.span) {
380 self.add_type_neq_err_label(
388 self.add_type_neq_err_label(
397 self.note_unmet_impls_on_type(&mut err, errors);
398 (err, missing_trait, use_output)
401 if let Ref(_, rty, _) = lhs_ty.kind() {
402 if self.infcx.type_is_copy_modulo_regions(self.param_env, *rty, lhs_expr.span)
403 && self.lookup_op_method(*rty, &[rhs_ty], Op::Binary(op, is_assign)).is_ok()
405 if let Ok(lstring) = source_map.span_to_snippet(lhs_expr.span) {
407 "`{}{}` can be used on `{}`, you can dereference `{}`",
410 IsAssign::Yes => "=",
416 err.span_suggestion_verbose(
417 lhs_expr.span.shrink_to_lo(),
420 rustc_errors::Applicability::MachineApplicable,
425 if let Some(missing_trait) = missing_trait {
426 let mut visitor = TypeParamVisitor(vec![]);
427 visitor.visit_ty(lhs_ty);
429 if op.node == hir::BinOpKind::Add
430 && self.check_str_addition(
431 lhs_expr, rhs_expr, lhs_ty, rhs_ty, &mut err, is_assign, op,
434 // This has nothing here because it means we did string
435 // concatenation (e.g., "Hello " + "World!"). This means
436 // we don't want the note in the else clause to be emitted
437 } else if let [ty] = &visitor.0[..] {
438 if let ty::Param(p) = *ty.kind() {
439 // Check if the method would be found if the type param wasn't
440 // involved. If so, it means that adding a trait bound to the param is
441 // enough. Otherwise we do not give the suggestion.
442 let mut eraser = TypeParamEraser(self, expr.span);
443 let needs_bound = self
445 eraser.fold_ty(lhs_ty),
446 &[eraser.fold_ty(rhs_ty)],
447 Op::Binary(op, is_assign),
451 suggest_constraining_param(
461 } else if *ty != lhs_ty {
462 // When we know that a missing bound is responsible, we don't show
463 // this note as it is redundant.
465 "the trait `{}` is not implemented for `{}`",
466 missing_trait, lhs_ty
470 bug!("type param visitor stored a non type param: {:?}", ty.kind());
479 (lhs_ty, rhs_ty, return_ty)
482 /// If one of the types is an uncalled function and calling it would yield the other type,
483 /// suggest calling the function. Returns `true` if suggestion would apply (even if not given).
484 fn add_type_neq_err_label(
486 err: &mut rustc_errors::DiagnosticBuilder<'_>,
492 ) -> bool /* did we suggest to call a function because of missing parentheses? */ {
493 err.span_label(span, ty.to_string());
494 if let FnDef(def_id, _) = *ty.kind() {
495 if !self.tcx.has_typeck_results(def_id) {
498 // FIXME: Instead of exiting early when encountering bound vars in
499 // the function signature, consider keeping the binder here and
500 // propagating it downwards.
501 let Some(fn_sig) = self.tcx.fn_sig(def_id).no_bound_vars() else {
505 let other_ty = if let FnDef(def_id, _) = *other_ty.kind() {
506 if !self.tcx.has_typeck_results(def_id) {
509 // We're emitting a suggestion, so we can just ignore regions
510 self.tcx.fn_sig(def_id).skip_binder().output()
516 .lookup_op_method(fn_sig.output(), &[other_ty], Op::Binary(op, is_assign))
519 let (variable_snippet, applicability) = if !fn_sig.inputs().is_empty() {
520 ("( /* arguments */ )".to_string(), Applicability::HasPlaceholders)
522 ("()".to_string(), Applicability::MaybeIncorrect)
525 err.span_suggestion_verbose(
527 "you might have forgotten to call this function",
537 /// Provide actionable suggestions when trying to add two strings with incorrect types,
538 /// like `&str + &str`, `String + String` and `&str + &String`.
540 /// If this function returns `true` it means a note was printed, so we don't need
541 /// to print the normal "implementation of `std::ops::Add` might be missing" note
542 fn check_str_addition(
544 lhs_expr: &'tcx hir::Expr<'tcx>,
545 rhs_expr: &'tcx hir::Expr<'tcx>,
548 err: &mut rustc_errors::DiagnosticBuilder<'_>,
552 let str_concat_note = "string concatenation requires an owned `String` on the left";
553 let rm_borrow_msg = "remove the borrow to obtain an owned `String`";
554 let to_owned_msg = "create an owned `String` from a string reference";
556 let string_type = self.tcx.get_diagnostic_item(sym::String);
557 let is_std_string = |ty: Ty<'tcx>| match ty.ty_adt_def() {
558 Some(ty_def) => Some(ty_def.did) == string_type,
562 match (lhs_ty.kind(), rhs_ty.kind()) {
563 (&Ref(_, l_ty, _), &Ref(_, r_ty, _)) // &str or &String + &str, &String or &&str
564 if (*l_ty.kind() == Str || is_std_string(l_ty)) && (
565 *r_ty.kind() == Str || is_std_string(r_ty) ||
566 &format!("{:?}", rhs_ty) == "&&str"
569 if let IsAssign::No = is_assign { // Do not supply this message if `&str += &str`
570 err.span_label(op.span, "`+` cannot be used to concatenate two `&str` strings");
571 err.note(str_concat_note);
572 if let hir::ExprKind::AddrOf(_, _, lhs_inner_expr) = lhs_expr.kind {
573 err.span_suggestion_verbose(
574 lhs_expr.span.until(lhs_inner_expr.span),
577 Applicability::MachineApplicable
580 err.span_suggestion_verbose(
581 lhs_expr.span.shrink_to_hi(),
583 ".to_owned()".to_owned(),
584 Applicability::MachineApplicable
590 (&Ref(_, l_ty, _), &Adt(..)) // Handle `&str` & `&String` + `String`
591 if (*l_ty.kind() == Str || is_std_string(l_ty)) && is_std_string(rhs_ty) =>
595 "`+` cannot be used to concatenate a `&str` with a `String`",
600 let lhs_sugg = if let hir::ExprKind::AddrOf(_, _, lhs_inner_expr) = lhs_expr.kind {
601 sugg_msg = "remove the borrow on the left and add one on the right";
602 (lhs_expr.span.until(lhs_inner_expr.span), "".to_owned())
604 sugg_msg = "create an owned `String` on the left and add a borrow on the right";
605 (lhs_expr.span.shrink_to_hi(), ".to_owned()".to_owned())
607 let suggestions = vec![
609 (rhs_expr.span.shrink_to_lo(), "&".to_owned()),
611 err.multipart_suggestion_verbose(
614 Applicability::MachineApplicable,
618 err.note(str_concat_note);
627 pub fn check_user_unop(
629 ex: &'tcx hir::Expr<'tcx>,
630 operand_ty: Ty<'tcx>,
633 assert!(op.is_by_value());
634 match self.lookup_op_method(operand_ty, &[], Op::Unary(op, ex.span)) {
636 self.write_method_call(ex.hir_id, method);
640 let actual = self.resolve_vars_if_possible(operand_ty);
641 if !actual.references_error() {
642 let mut err = struct_span_err!(
646 "cannot apply unary operator `{}` to type `{}`",
652 format!("cannot apply unary operator `{}`", op.as_str()),
655 let sp = self.tcx.sess.source_map().start_point(ex.span);
657 self.tcx.sess.parse_sess.ambiguous_block_expr_parse.borrow().get(&sp)
659 // If the previous expression was a block expression, suggest parentheses
660 // (turning this into a binary subtraction operation instead.)
661 // for example, `{2} - 2` -> `({2}) - 2` (see src\test\ui\parser\expr-as-stmt.rs)
662 self.tcx.sess.parse_sess.expr_parentheses_needed(&mut err, *sp);
664 match actual.kind() {
665 Uint(_) if op == hir::UnOp::Neg => {
666 err.note("unsigned values cannot be negated");
668 if let hir::ExprKind::Unary(
672 hir::ExprKind::Lit(Spanned {
673 node: ast::LitKind::Int(1, _),
683 "you may have meant the maximum value of `{}`",
686 format!("{}::MAX", actual),
687 Applicability::MaybeIncorrect,
691 Str | Never | Char | Tuple(_) | Array(_, _) => {}
692 Ref(_, lty, _) if *lty.kind() == Str => {}
694 self.note_unmet_impls_on_type(&mut err, errors);
708 other_tys: &[Ty<'tcx>],
710 ) -> Result<MethodCallee<'tcx>, Vec<FulfillmentError<'tcx>>> {
711 let lang = self.tcx.lang_items();
713 let span = match op {
714 Op::Binary(op, _) => op.span,
715 Op::Unary(_, span) => span,
717 let (opname, trait_did) = if let Op::Binary(op, IsAssign::Yes) = op {
719 hir::BinOpKind::Add => (sym::add_assign, lang.add_assign_trait()),
720 hir::BinOpKind::Sub => (sym::sub_assign, lang.sub_assign_trait()),
721 hir::BinOpKind::Mul => (sym::mul_assign, lang.mul_assign_trait()),
722 hir::BinOpKind::Div => (sym::div_assign, lang.div_assign_trait()),
723 hir::BinOpKind::Rem => (sym::rem_assign, lang.rem_assign_trait()),
724 hir::BinOpKind::BitXor => (sym::bitxor_assign, lang.bitxor_assign_trait()),
725 hir::BinOpKind::BitAnd => (sym::bitand_assign, lang.bitand_assign_trait()),
726 hir::BinOpKind::BitOr => (sym::bitor_assign, lang.bitor_assign_trait()),
727 hir::BinOpKind::Shl => (sym::shl_assign, lang.shl_assign_trait()),
728 hir::BinOpKind::Shr => (sym::shr_assign, lang.shr_assign_trait()),
735 | hir::BinOpKind::And
736 | hir::BinOpKind::Or => {
737 span_bug!(span, "impossible assignment operation: {}=", op.node.as_str())
740 } else if let Op::Binary(op, IsAssign::No) = op {
742 hir::BinOpKind::Add => (sym::add, lang.add_trait()),
743 hir::BinOpKind::Sub => (sym::sub, lang.sub_trait()),
744 hir::BinOpKind::Mul => (sym::mul, lang.mul_trait()),
745 hir::BinOpKind::Div => (sym::div, lang.div_trait()),
746 hir::BinOpKind::Rem => (sym::rem, lang.rem_trait()),
747 hir::BinOpKind::BitXor => (sym::bitxor, lang.bitxor_trait()),
748 hir::BinOpKind::BitAnd => (sym::bitand, lang.bitand_trait()),
749 hir::BinOpKind::BitOr => (sym::bitor, lang.bitor_trait()),
750 hir::BinOpKind::Shl => (sym::shl, lang.shl_trait()),
751 hir::BinOpKind::Shr => (sym::shr, lang.shr_trait()),
752 hir::BinOpKind::Lt => (sym::lt, lang.partial_ord_trait()),
753 hir::BinOpKind::Le => (sym::le, lang.partial_ord_trait()),
754 hir::BinOpKind::Ge => (sym::ge, lang.partial_ord_trait()),
755 hir::BinOpKind::Gt => (sym::gt, lang.partial_ord_trait()),
756 hir::BinOpKind::Eq => (sym::eq, lang.eq_trait()),
757 hir::BinOpKind::Ne => (sym::ne, lang.eq_trait()),
758 hir::BinOpKind::And | hir::BinOpKind::Or => {
759 span_bug!(span, "&& and || are not overloadable")
762 } else if let Op::Unary(hir::UnOp::Not, _) = op {
763 (sym::not, lang.not_trait())
764 } else if let Op::Unary(hir::UnOp::Neg, _) = op {
765 (sym::neg, lang.neg_trait())
767 bug!("lookup_op_method: op not supported: {:?}", op)
771 "lookup_op_method(lhs_ty={:?}, op={:?}, opname={:?}, trait_did={:?})",
772 lhs_ty, op, opname, trait_did
775 // Catches cases like #83893, where a lang item is declared with the
776 // wrong number of generic arguments. Should have yielded an error
777 // elsewhere by now, but we have to catch it here so that we do not
778 // index `other_tys` out of bounds (if the lang item has too many
779 // generic arguments, `other_tys` is too short).
780 if !has_expected_num_generic_args(
784 // Binary ops have a generic right-hand side, unary ops don't
792 let opname = Ident::with_dummy_span(opname);
793 let method = trait_did.and_then(|trait_did| {
794 self.lookup_method_in_trait(span, opname, trait_did, lhs_ty, Some(other_tys))
797 match (method, trait_did) {
799 let method = self.register_infer_ok_obligations(ok);
800 self.select_obligations_where_possible(false, |_| {});
803 (None, None) => Err(vec![]),
804 (None, Some(trait_did)) => {
805 let (obligation, _) =
806 self.obligation_for_method(span, trait_did, lhs_ty, Some(other_tys));
807 let mut fulfill = <dyn TraitEngine<'_>>::new(self.tcx);
808 fulfill.register_predicate_obligation(self, obligation);
809 Err(fulfill.select_where_possible(&self.infcx))
815 // Binary operator categories. These categories summarize the behavior
816 // with respect to the builtin operationrs supported.
818 /// &&, || -- cannot be overridden
821 /// <<, >> -- when shifting a single integer, rhs can be any
822 /// integer type. For simd, types must match.
825 /// +, -, etc -- takes equal types, produces same type as input,
826 /// applicable to ints/floats/simd
829 /// &, |, ^ -- takes equal types, produces same type as input,
830 /// applicable to ints/floats/simd/bool
833 /// ==, !=, etc -- takes equal types, produces bools, except for simd,
834 /// which produce the input type
839 fn from(op: hir::BinOp) -> BinOpCategory {
841 hir::BinOpKind::Shl | hir::BinOpKind::Shr => BinOpCategory::Shift,
844 | hir::BinOpKind::Sub
845 | hir::BinOpKind::Mul
846 | hir::BinOpKind::Div
847 | hir::BinOpKind::Rem => BinOpCategory::Math,
849 hir::BinOpKind::BitXor | hir::BinOpKind::BitAnd | hir::BinOpKind::BitOr => {
850 BinOpCategory::Bitwise
858 | hir::BinOpKind::Gt => BinOpCategory::Comparison,
860 hir::BinOpKind::And | hir::BinOpKind::Or => BinOpCategory::Shortcircuit,
865 /// Whether the binary operation is an assignment (`a += b`), or not (`a + b`)
866 #[derive(Clone, Copy, Debug, PartialEq)]
872 #[derive(Clone, Copy, Debug)]
874 Binary(hir::BinOp, IsAssign),
875 Unary(hir::UnOp, Span),
878 /// Dereferences a single level of immutable referencing.
879 fn deref_ty_if_possible<'tcx>(ty: Ty<'tcx>) -> Ty<'tcx> {
881 ty::Ref(_, ty, hir::Mutability::Not) => *ty,
886 /// Returns `true` if this is a built-in arithmetic operation (e.g., u32
887 /// + u32, i16x4 == i16x4) and false if these types would have to be
888 /// overloaded to be legal. There are two reasons that we distinguish
889 /// builtin operations from overloaded ones (vs trying to drive
890 /// everything uniformly through the trait system and intrinsics or
891 /// something like that):
893 /// 1. Builtin operations can trivially be evaluated in constants.
894 /// 2. For comparison operators applied to SIMD types the result is
895 /// not of type `bool`. For example, `i16x4 == i16x4` yields a
896 /// type like `i16x4`. This means that the overloaded trait
897 /// `PartialEq` is not applicable.
899 /// Reason #2 is the killer. I tried for a while to always use
900 /// overloaded logic and just check the types in constants/codegen after
901 /// the fact, and it worked fine, except for SIMD types. -nmatsakis
902 fn is_builtin_binop<'tcx>(lhs: Ty<'tcx>, rhs: Ty<'tcx>, op: hir::BinOp) -> bool {
903 // Special-case a single layer of referencing, so that things like `5.0 + &6.0f32` work.
904 // (See https://github.com/rust-lang/rust/issues/57447.)
905 let (lhs, rhs) = (deref_ty_if_possible(lhs), deref_ty_if_possible(rhs));
907 match BinOpCategory::from(op) {
908 BinOpCategory::Shortcircuit => true,
910 BinOpCategory::Shift => {
911 lhs.references_error()
912 || rhs.references_error()
913 || lhs.is_integral() && rhs.is_integral()
916 BinOpCategory::Math => {
917 lhs.references_error()
918 || rhs.references_error()
919 || lhs.is_integral() && rhs.is_integral()
920 || lhs.is_floating_point() && rhs.is_floating_point()
923 BinOpCategory::Bitwise => {
924 lhs.references_error()
925 || rhs.references_error()
926 || lhs.is_integral() && rhs.is_integral()
927 || lhs.is_floating_point() && rhs.is_floating_point()
928 || lhs.is_bool() && rhs.is_bool()
931 BinOpCategory::Comparison => {
932 lhs.references_error() || rhs.references_error() || lhs.is_scalar() && rhs.is_scalar()
937 fn suggest_constraining_param(
940 mut err: &mut DiagnosticBuilder<'_>,
948 let msg = &format!("`{}` might need a bound for `{}`", lhs_ty, missing_trait);
949 // Try to find the def-id and details for the parameter p. We have only the index,
950 // so we have to find the enclosing function's def-id, then look through its declared
951 // generic parameters to get the declaration.
952 let def_id = hir.body_owner_def_id(hir::BodyId { hir_id: body_id });
953 let generics = tcx.generics_of(def_id);
954 let param_def_id = generics.type_param(&p, tcx).def_id;
955 if let Some(generics) = param_def_id
957 .map(|id| hir.local_def_id_to_hir_id(id))
958 .and_then(|id| hir.find_by_def_id(hir.get_parent_item(id)))
960 .and_then(|node| node.generics())
962 let output = if set_output { format!("<Output = {}>", rhs_ty) } else { String::new() };
963 suggest_constraining_type_param(
967 &format!("{}", lhs_ty),
968 &format!("{}{}", missing_trait, output),
972 let span = tcx.def_span(param_def_id);
973 err.span_label(span, msg);
977 struct TypeParamVisitor<'tcx>(Vec<Ty<'tcx>>);
979 impl<'tcx> TypeVisitor<'tcx> for TypeParamVisitor<'tcx> {
980 fn visit_ty(&mut self, ty: Ty<'tcx>) -> ControlFlow<Self::BreakTy> {
981 if let ty::Param(_) = ty.kind() {
984 ty.super_visit_with(self)
988 struct TypeParamEraser<'a, 'tcx>(&'a FnCtxt<'a, 'tcx>, Span);
990 impl<'tcx> TypeFolder<'tcx> for TypeParamEraser<'_, 'tcx> {
991 fn tcx(&self) -> TyCtxt<'tcx> {
995 fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> {
997 ty::Param(_) => self.0.next_ty_var(TypeVariableOrigin {
998 kind: TypeVariableOriginKind::MiscVariable,
1001 _ => ty.super_fold_with(self),