Introduce structurally_normalize_const, use it in hir_typeck
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0af7f0f4c4
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3b8089a320
@ -1668,10 +1668,17 @@ pub enum ArrayLen<'hir> {
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}
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}
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impl ArrayLen<'_> {
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impl ArrayLen<'_> {
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pub fn hir_id(&self) -> HirId {
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pub fn span(self) -> Span {
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match self {
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match self {
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ArrayLen::Infer(InferArg { hir_id, .. }) | ArrayLen::Body(ConstArg { hir_id, .. }) => {
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ArrayLen::Infer(arg) => arg.span,
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*hir_id
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ArrayLen::Body(body) => body.span(),
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}
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}
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pub fn hir_id(self) -> HirId {
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match self {
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ArrayLen::Infer(InferArg { hir_id, .. }) | ArrayLen::Body(&ConstArg { hir_id, .. }) => {
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hir_id
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}
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}
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}
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}
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}
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}
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@ -1491,8 +1491,10 @@ fn check_expr_repeat(
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expr: &'tcx hir::Expr<'tcx>,
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expr: &'tcx hir::Expr<'tcx>,
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) -> Ty<'tcx> {
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) -> Ty<'tcx> {
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let tcx = self.tcx;
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let tcx = self.tcx;
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let count = self.lower_array_length(count);
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let count_span = count.span();
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if let Some(count) = count.try_eval_target_usize(tcx, self.param_env) {
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let count = self.try_structurally_resolve_const(count_span, self.lower_array_length(count));
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if let Some(count) = count.try_to_target_usize(tcx) {
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self.suggest_array_len(expr, count);
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self.suggest_array_len(expr, count);
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}
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}
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@ -1520,19 +1522,24 @@ fn check_expr_repeat(
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return Ty::new_error(tcx, guar);
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return Ty::new_error(tcx, guar);
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}
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}
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self.check_repeat_element_needs_copy_bound(element, count, element_ty);
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// If the length is 0, we don't create any elements, so we don't copy any.
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// If the length is 1, we don't copy that one element, we move it. Only check
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// for `Copy` if the length is larger, or unevaluated.
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// FIXME(min_const_generic_exprs): We could perhaps defer this check so that
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// we don't require `<?0t as Tr>::CONST` doesn't unnecessarily require `Copy`.
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if count.try_to_target_usize(tcx).is_none_or(|x| x > 1) {
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self.enforce_repeat_element_needs_copy_bound(element, element_ty);
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}
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let ty = Ty::new_array_with_const_len(tcx, t, count);
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let ty = Ty::new_array_with_const_len(tcx, t, count);
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self.register_wf_obligation(ty.into(), expr.span, ObligationCauseCode::WellFormed(None));
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self.register_wf_obligation(ty.into(), expr.span, ObligationCauseCode::WellFormed(None));
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ty
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ty
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}
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}
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fn check_repeat_element_needs_copy_bound(
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/// Requires that `element_ty` is `Copy` (unless it's a const expression itself).
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fn enforce_repeat_element_needs_copy_bound(
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&self,
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&self,
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element: &hir::Expr<'_>,
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element: &hir::Expr<'_>,
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count: ty::Const<'tcx>,
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element_ty: Ty<'tcx>,
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element_ty: Ty<'tcx>,
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) {
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) {
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let tcx = self.tcx;
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let tcx = self.tcx;
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@ -1565,27 +1572,23 @@ fn check_repeat_element_needs_copy_bound(
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_ => traits::IsConstable::No,
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_ => traits::IsConstable::No,
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};
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};
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// If the length is 0, we don't create any elements, so we don't copy any. If the length is 1, we
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let lang_item = self.tcx.require_lang_item(LangItem::Copy, None);
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// don't copy that one element, we move it. Only check for Copy if the length is larger.
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let code = traits::ObligationCauseCode::RepeatElementCopy {
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if count.try_eval_target_usize(tcx, self.param_env).is_none_or(|len| len > 1) {
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is_constable,
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let lang_item = self.tcx.require_lang_item(LangItem::Copy, None);
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elt_type: element_ty,
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let code = traits::ObligationCauseCode::RepeatElementCopy {
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elt_span: element.span,
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is_constable,
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elt_stmt_span: self
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elt_type: element_ty,
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.tcx
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elt_span: element.span,
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.hir()
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elt_stmt_span: self
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.parent_iter(element.hir_id)
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.tcx
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.find_map(|(_, node)| match node {
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.hir()
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hir::Node::Item(it) => Some(it.span),
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.parent_iter(element.hir_id)
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hir::Node::Stmt(stmt) => Some(stmt.span),
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.find_map(|(_, node)| match node {
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_ => None,
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hir::Node::Item(it) => Some(it.span),
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})
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hir::Node::Stmt(stmt) => Some(stmt.span),
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.expect("array repeat expressions must be inside an item or statement"),
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_ => None,
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};
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})
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self.require_type_meets(element_ty, element.span, code, lang_item);
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.expect("array repeat expressions must be inside an item or statement"),
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};
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self.require_type_meets(element_ty, element.span, code, lang_item);
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}
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}
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}
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fn check_expr_tuple(
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fn check_expr_tuple(
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@ -2800,9 +2803,10 @@ fn maybe_suggest_array_indexing(
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len: ty::Const<'tcx>,
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len: ty::Const<'tcx>,
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) {
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) {
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err.span_label(field.span, "unknown field");
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err.span_label(field.span, "unknown field");
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if let (Some(len), Ok(user_index)) =
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if let (Some(len), Ok(user_index)) = (
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(len.try_eval_target_usize(self.tcx, self.param_env), field.as_str().parse::<u64>())
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self.try_structurally_resolve_const(base.span, len).try_to_target_usize(self.tcx),
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{
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field.as_str().parse::<u64>(),
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) {
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let help = "instead of using tuple indexing, use array indexing";
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let help = "instead of using tuple indexing, use array indexing";
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let applicability = if len < user_index {
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let applicability = if len < user_index {
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Applicability::MachineApplicable
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Applicability::MachineApplicable
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@ -1477,6 +1477,33 @@ pub fn try_structurally_resolve_type(&self, sp: Span, ty: Ty<'tcx>) -> Ty<'tcx>
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}
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}
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}
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}
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#[instrument(level = "debug", skip(self, sp), ret)]
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pub fn try_structurally_resolve_const(&self, sp: Span, ct: ty::Const<'tcx>) -> ty::Const<'tcx> {
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// FIXME(min_const_generic_exprs): We could process obligations here if `ct` is a var.
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if self.next_trait_solver()
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&& let ty::ConstKind::Unevaluated(..) = ct.kind()
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{
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// We need to use a separate variable here as otherwise the temporary for
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// `self.fulfillment_cx.borrow_mut()` is alive in the `Err` branch, resulting
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// in a reentrant borrow, causing an ICE.
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let result = self
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.at(&self.misc(sp), self.param_env)
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.structurally_normalize_const(ct, &mut **self.fulfillment_cx.borrow_mut());
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match result {
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Ok(normalized_ct) => normalized_ct,
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Err(errors) => {
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let guar = self.err_ctxt().report_fulfillment_errors(errors);
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return ty::Const::new_error(self.tcx, guar);
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}
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}
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} else if self.tcx.features().generic_const_exprs {
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ct.normalize(self.tcx, self.param_env)
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} else {
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ct
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}
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}
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/// Resolves `ty` by a single level if `ty` is a type variable.
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/// Resolves `ty` by a single level if `ty` is a type variable.
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///
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///
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/// When the new solver is enabled, this will also attempt to normalize
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/// When the new solver is enabled, this will also attempt to normalize
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@ -1502,7 +1502,10 @@ pub(crate) fn suggest_deref_unwrap_or(
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// Create an dummy type `&[_]` so that both &[] and `&Vec<T>` can coerce to it.
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// Create an dummy type `&[_]` so that both &[] and `&Vec<T>` can coerce to it.
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let dummy_ty = if let ty::Array(elem_ty, size) = peeled.kind()
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let dummy_ty = if let ty::Array(elem_ty, size) = peeled.kind()
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&& let ty::Infer(_) = elem_ty.kind()
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&& let ty::Infer(_) = elem_ty.kind()
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&& size.try_eval_target_usize(self.tcx, self.param_env) == Some(0)
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&& self
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.try_structurally_resolve_const(provided_expr.span, *size)
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.try_to_target_usize(self.tcx)
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== Some(0)
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{
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{
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let slice = Ty::new_slice(self.tcx, *elem_ty);
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let slice = Ty::new_slice(self.tcx, *elem_ty);
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Ty::new_imm_ref(self.tcx, self.tcx.lifetimes.re_static, slice)
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Ty::new_imm_ref(self.tcx, self.tcx.lifetimes.re_static, slice)
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@ -101,7 +101,9 @@ pub(crate) fn check_transmute(&self, from: Ty<'tcx>, to: Ty<'tcx>, hir_id: HirId
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}
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}
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}
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}
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Ok(SizeSkeleton::Generic(size)) => {
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Ok(SizeSkeleton::Generic(size)) => {
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if let Some(size) = size.try_eval_target_usize(tcx, self.param_env) {
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if let Some(size) =
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self.try_structurally_resolve_const(span, size).try_to_target_usize(tcx)
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{
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format!("{size} bytes")
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format!("{size} bytes")
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} else {
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} else {
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format!("generic size {size}")
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format!("generic size {size}")
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@ -2412,7 +2412,7 @@ fn check_array_pat_len(
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len: ty::Const<'tcx>,
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len: ty::Const<'tcx>,
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min_len: u64,
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min_len: u64,
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) -> (Option<Ty<'tcx>>, Ty<'tcx>) {
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) -> (Option<Ty<'tcx>>, Ty<'tcx>) {
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let len = len.try_eval_target_usize(self.tcx, self.param_env);
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let len = self.try_structurally_resolve_const(span, len).try_to_target_usize(self.tcx);
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let guar = if let Some(len) = len {
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let guar = if let Some(len) = len {
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// Now we know the length...
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// Now we know the length...
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@ -46,4 +46,44 @@ fn structurally_normalize<E: 'tcx>(
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Ok(self.normalize(ty).into_value_registering_obligations(self.infcx, fulfill_cx))
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Ok(self.normalize(ty).into_value_registering_obligations(self.infcx, fulfill_cx))
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}
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}
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}
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}
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fn structurally_normalize_const<E: 'tcx>(
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&self,
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ct: ty::Const<'tcx>,
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fulfill_cx: &mut dyn TraitEngine<'tcx, E>,
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) -> Result<ty::Const<'tcx>, Vec<E>> {
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assert!(!ct.is_ct_infer(), "should have resolved vars before calling");
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if self.infcx.next_trait_solver() {
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let ty::ConstKind::Unevaluated(..) = ct.kind() else {
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return Ok(ct);
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};
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let new_infer_ct = self.infcx.next_const_var(self.cause.span);
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// We simply emit an `alias-eq` goal here, since that will take care of
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// normalizing the LHS of the projection until it is a rigid projection
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// (or a not-yet-defined opaque in scope).
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let obligation = Obligation::new(
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self.infcx.tcx,
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self.cause.clone(),
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self.param_env,
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ty::PredicateKind::AliasRelate(
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ct.into(),
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new_infer_ct.into(),
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ty::AliasRelationDirection::Equate,
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),
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);
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fulfill_cx.register_predicate_obligation(self.infcx, obligation);
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let errors = fulfill_cx.select_where_possible(self.infcx);
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if !errors.is_empty() {
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return Err(errors);
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}
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Ok(self.infcx.resolve_vars_if_possible(new_infer_ct))
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} else {
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Ok(self.normalize(ct).into_value_registering_obligations(self.infcx, fulfill_cx))
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}
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}
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}
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}
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@ -2,10 +2,10 @@ error[E0308]: mismatched types
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--> $DIR/different-fn.rs:10:5
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--> $DIR/different-fn.rs:10:5
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LL | [0; size_of::<Foo<T>>()]
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LL | [0; size_of::<Foo<T>>()]
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| ^^^^^^^^^^^^^^^^^^^^^^^^ expected `size_of::<T>()`, found `size_of::<Foo<T>>()`
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| ^^^^^^^^^^^^^^^^^^^^^^^^ expected `size_of::<T>()`, found `0`
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= note: expected constant `size_of::<T>()`
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= note: expected constant `size_of::<T>()`
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found constant `size_of::<Foo<T>>()`
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found constant `0`
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error: unconstrained generic constant
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error: unconstrained generic constant
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--> $DIR/different-fn.rs:10:9
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--> $DIR/different-fn.rs:10:9
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