use hir::GenericParamKind; use rustc_errors::{ fluent, AddToDiagnostic, Applicability, Diagnostic, DiagnosticMessage, DiagnosticStyledString, MultiSpan, SubdiagnosticMessage, }; use rustc_hir as hir; use rustc_hir::{FnRetTy, Ty}; use rustc_macros::{Diagnostic, Subdiagnostic}; use rustc_middle::ty::{Region, TyCtxt}; use rustc_span::symbol::kw; use rustc_span::{symbol::Ident, BytePos, Span}; use crate::infer::error_reporting::{ need_type_info::{GeneratorKindAsDiagArg, UnderspecifiedArgKind}, ObligationCauseAsDiagArg, }; pub mod note_and_explain; #[derive(Diagnostic)] #[diag(infer_opaque_hidden_type)] pub struct OpaqueHiddenTypeDiag { #[primary_span] #[label] pub span: Span, #[note(opaque_type)] pub opaque_type: Span, #[note(hidden_type)] pub hidden_type: Span, } #[derive(Diagnostic)] #[diag(infer_type_annotations_needed, code = "E0282")] pub struct AnnotationRequired<'a> { #[primary_span] pub span: Span, pub source_kind: &'static str, pub source_name: &'a str, #[label] pub failure_span: Option, #[subdiagnostic] pub bad_label: Option>, #[subdiagnostic] pub infer_subdiags: Vec>, #[subdiagnostic] pub multi_suggestions: Vec>, } // Copy of `AnnotationRequired` for E0283 #[derive(Diagnostic)] #[diag(infer_type_annotations_needed, code = "E0283")] pub struct AmbigousImpl<'a> { #[primary_span] pub span: Span, pub source_kind: &'static str, pub source_name: &'a str, #[label] pub failure_span: Option, #[subdiagnostic] pub bad_label: Option>, #[subdiagnostic] pub infer_subdiags: Vec>, #[subdiagnostic] pub multi_suggestions: Vec>, } // Copy of `AnnotationRequired` for E0284 #[derive(Diagnostic)] #[diag(infer_type_annotations_needed, code = "E0284")] pub struct AmbigousReturn<'a> { #[primary_span] pub span: Span, pub source_kind: &'static str, pub source_name: &'a str, #[label] pub failure_span: Option, #[subdiagnostic] pub bad_label: Option>, #[subdiagnostic] pub infer_subdiags: Vec>, #[subdiagnostic] pub multi_suggestions: Vec>, } #[derive(Diagnostic)] #[diag(infer_need_type_info_in_generator, code = "E0698")] pub struct NeedTypeInfoInGenerator<'a> { #[primary_span] pub span: Span, pub generator_kind: GeneratorKindAsDiagArg, #[subdiagnostic] pub bad_label: InferenceBadError<'a>, } // Used when a better one isn't available #[derive(Subdiagnostic)] #[label(infer_label_bad)] pub struct InferenceBadError<'a> { #[primary_span] pub span: Span, pub bad_kind: &'static str, pub prefix_kind: UnderspecifiedArgKind, pub has_parent: bool, pub prefix: &'a str, pub parent_prefix: &'a str, pub parent_name: String, pub name: String, } #[derive(Subdiagnostic)] pub enum SourceKindSubdiag<'a> { #[suggestion( infer_source_kind_subdiag_let, style = "verbose", code = ": {type_name}", applicability = "has-placeholders" )] LetLike { #[primary_span] span: Span, name: String, type_name: String, kind: &'static str, x_kind: &'static str, prefix_kind: UnderspecifiedArgKind, prefix: &'a str, arg_name: String, }, #[label(infer_source_kind_subdiag_generic_label)] GenericLabel { #[primary_span] span: Span, is_type: bool, param_name: String, parent_exists: bool, parent_prefix: String, parent_name: String, }, #[suggestion( infer_source_kind_subdiag_generic_suggestion, style = "verbose", code = "::<{args}>", applicability = "has-placeholders" )] GenericSuggestion { #[primary_span] span: Span, arg_count: usize, args: String, }, } #[derive(Subdiagnostic)] pub enum SourceKindMultiSuggestion<'a> { #[multipart_suggestion( infer_source_kind_fully_qualified, style = "verbose", applicability = "has-placeholders" )] FullyQualified { #[suggestion_part(code = "{def_path}({adjustment}")] span_lo: Span, #[suggestion_part(code = "{successor_pos}")] span_hi: Span, def_path: String, adjustment: &'a str, successor_pos: &'a str, }, #[multipart_suggestion( infer_source_kind_closure_return, style = "verbose", applicability = "has-placeholders" )] ClosureReturn { #[suggestion_part(code = "{start_span_code}")] start_span: Span, start_span_code: String, #[suggestion_part(code = " }}")] end_span: Option, }, } #[derive(Subdiagnostic)] #[suggestion( infer_suggest_add_let_for_letchains, style = "verbose", applicability = "machine-applicable", code = "let " )] pub(crate) struct SuggAddLetForLetChains { #[primary_span] pub span: Span, } impl<'a> SourceKindMultiSuggestion<'a> { pub fn new_fully_qualified( span: Span, def_path: String, adjustment: &'a str, successor: (&'a str, BytePos), ) -> Self { Self::FullyQualified { span_lo: span.shrink_to_lo(), span_hi: span.shrink_to_hi().with_hi(successor.1), def_path, adjustment, successor_pos: successor.0, } } pub fn new_closure_return( ty_info: String, data: &'a FnRetTy<'a>, should_wrap_expr: Option, ) -> Self { let (arrow, post) = match data { FnRetTy::DefaultReturn(_) => ("-> ", " "), _ => ("", ""), }; let (start_span, start_span_code, end_span) = match should_wrap_expr { Some(end_span) => { (data.span(), format!("{}{}{}{{ ", arrow, ty_info, post), Some(end_span)) } None => (data.span(), format!("{}{}{}", arrow, ty_info, post), None), }; Self::ClosureReturn { start_span, start_span_code, end_span } } } pub enum RegionOriginNote<'a> { Plain { span: Span, msg: DiagnosticMessage, }, WithName { span: Span, msg: DiagnosticMessage, name: &'a str, continues: bool, }, WithRequirement { span: Span, requirement: ObligationCauseAsDiagArg<'a>, expected_found: Option<(DiagnosticStyledString, DiagnosticStyledString)>, }, } impl AddToDiagnostic for RegionOriginNote<'_> { fn add_to_diagnostic_with(self, diag: &mut Diagnostic, _: F) where F: Fn(&mut Diagnostic, SubdiagnosticMessage) -> SubdiagnosticMessage, { let mut label_or_note = |span, msg: DiagnosticMessage| { let sub_count = diag.children.iter().filter(|d| d.span.is_dummy()).count(); let expanded_sub_count = diag.children.iter().filter(|d| !d.span.is_dummy()).count(); let span_is_primary = diag.span.primary_spans().iter().all(|&sp| sp == span); if span_is_primary && sub_count == 0 && expanded_sub_count == 0 { diag.span_label(span, msg); } else if span_is_primary && expanded_sub_count == 0 { diag.note(msg); } else { diag.span_note(span, msg); } }; match self { RegionOriginNote::Plain { span, msg } => { label_or_note(span, msg); } RegionOriginNote::WithName { span, msg, name, continues } => { label_or_note(span, msg); diag.set_arg("name", name); diag.set_arg("continues", continues); } RegionOriginNote::WithRequirement { span, requirement, expected_found: Some((expected, found)), } => { label_or_note(span, fluent::infer_subtype); diag.set_arg("requirement", requirement); diag.note_expected_found(&"", expected, &"", found); } RegionOriginNote::WithRequirement { span, requirement, expected_found: None } => { // FIXME: this really should be handled at some earlier stage. Our // handling of region checking when type errors are present is // *terrible*. label_or_note(span, fluent::infer_subtype_2); diag.set_arg("requirement", requirement); } }; } } pub enum LifetimeMismatchLabels { InRet { param_span: Span, ret_span: Span, span: Span, label_var1: Option, }, Normal { hir_equal: bool, ty_sup: Span, ty_sub: Span, span: Span, sup: Option, sub: Option, }, } impl AddToDiagnostic for LifetimeMismatchLabels { fn add_to_diagnostic_with(self, diag: &mut Diagnostic, _: F) where F: Fn(&mut Diagnostic, SubdiagnosticMessage) -> SubdiagnosticMessage, { match self { LifetimeMismatchLabels::InRet { param_span, ret_span, span, label_var1 } => { diag.span_label(param_span, fluent::infer_declared_different); diag.span_label(ret_span, fluent::infer_nothing); diag.span_label(span, fluent::infer_data_returned); diag.set_arg("label_var1_exists", label_var1.is_some()); diag.set_arg("label_var1", label_var1.map(|x| x.to_string()).unwrap_or_default()); } LifetimeMismatchLabels::Normal { hir_equal, ty_sup, ty_sub, span, sup: label_var1, sub: label_var2, } => { if hir_equal { diag.span_label(ty_sup, fluent::infer_declared_multiple); diag.span_label(ty_sub, fluent::infer_nothing); diag.span_label(span, fluent::infer_data_lifetime_flow); } else { diag.span_label(ty_sup, fluent::infer_types_declared_different); diag.span_label(ty_sub, fluent::infer_nothing); diag.span_label(span, fluent::infer_data_flows); diag.set_arg("label_var1_exists", label_var1.is_some()); diag.set_arg( "label_var1", label_var1.map(|x| x.to_string()).unwrap_or_default(), ); diag.set_arg("label_var2_exists", label_var2.is_some()); diag.set_arg( "label_var2", label_var2.map(|x| x.to_string()).unwrap_or_default(), ); } } } } } pub struct AddLifetimeParamsSuggestion<'a> { pub tcx: TyCtxt<'a>, pub sub: Region<'a>, pub ty_sup: &'a Ty<'a>, pub ty_sub: &'a Ty<'a>, pub add_note: bool, } impl AddToDiagnostic for AddLifetimeParamsSuggestion<'_> { fn add_to_diagnostic_with(self, diag: &mut Diagnostic, _: F) where F: Fn(&mut Diagnostic, SubdiagnosticMessage) -> SubdiagnosticMessage, { let mut mk_suggestion = || { let ( hir::Ty { kind: hir::TyKind::Rptr(lifetime_sub, _), .. }, hir::Ty { kind: hir::TyKind::Rptr(lifetime_sup, _), .. }, ) = (self.ty_sub, self.ty_sup) else { return false; }; if !lifetime_sub.is_anonymous() || !lifetime_sup.is_anonymous() { return false; }; let Some(anon_reg) = self.tcx.is_suitable_region(self.sub) else { return false; }; let hir_id = self.tcx.hir().local_def_id_to_hir_id(anon_reg.def_id); let node = self.tcx.hir().get(hir_id); let is_impl = matches!(&node, hir::Node::ImplItem(_)); let generics = match node { hir::Node::Item(&hir::Item { kind: hir::ItemKind::Fn(_, ref generics, ..), .. }) | hir::Node::TraitItem(&hir::TraitItem { ref generics, .. }) | hir::Node::ImplItem(&hir::ImplItem { ref generics, .. }) => generics, _ => return false, }; let suggestion_param_name = generics .params .iter() .filter(|p| matches!(p.kind, GenericParamKind::Lifetime { .. })) .map(|p| p.name.ident().name) .find(|i| *i != kw::UnderscoreLifetime); let introduce_new = suggestion_param_name.is_none(); let suggestion_param_name = suggestion_param_name.map(|n| n.to_string()).unwrap_or_else(|| "'a".to_owned()); debug!(?lifetime_sup.ident.span); debug!(?lifetime_sub.ident.span); let make_suggestion = |ident: Ident| { let sugg = if ident.name == kw::Empty { format!("{}, ", suggestion_param_name) } else if ident.name == kw::UnderscoreLifetime && ident.span.is_empty() { format!("{} ", suggestion_param_name) } else { suggestion_param_name.clone() }; (ident.span, sugg) }; let mut suggestions = vec![make_suggestion(lifetime_sub.ident), make_suggestion(lifetime_sup.ident)]; if introduce_new { let new_param_suggestion = if let Some(first) = generics.params.iter().find(|p| !p.name.ident().span.is_empty()) { (first.span.shrink_to_lo(), format!("{}, ", suggestion_param_name)) } else { (generics.span, format!("<{}>", suggestion_param_name)) }; suggestions.push(new_param_suggestion); } diag.multipart_suggestion( fluent::infer_lifetime_param_suggestion, suggestions, Applicability::MaybeIncorrect, ); diag.set_arg("is_impl", is_impl); true }; if mk_suggestion() && self.add_note { diag.note(fluent::infer_lifetime_param_suggestion_elided); } } } #[derive(Diagnostic)] #[diag(infer_lifetime_mismatch, code = "E0623")] pub struct LifetimeMismatch<'a> { #[primary_span] pub span: Span, #[subdiagnostic] pub labels: LifetimeMismatchLabels, #[subdiagnostic] pub suggestion: AddLifetimeParamsSuggestion<'a>, } pub struct IntroducesStaticBecauseUnmetLifetimeReq { pub unmet_requirements: MultiSpan, pub binding_span: Span, } impl AddToDiagnostic for IntroducesStaticBecauseUnmetLifetimeReq { fn add_to_diagnostic_with(mut self, diag: &mut Diagnostic, _: F) where F: Fn(&mut Diagnostic, SubdiagnosticMessage) -> SubdiagnosticMessage, { self.unmet_requirements .push_span_label(self.binding_span, fluent::infer_msl_introduces_static); diag.span_note(self.unmet_requirements, fluent::infer_msl_unmet_req); } } // FIXME(#100717): replace with a `Option` when subdiagnostic supports that #[derive(Subdiagnostic)] pub enum DoesNotOutliveStaticFromImpl { #[note(infer_does_not_outlive_static_from_impl)] Spanned { #[primary_span] span: Span, }, #[note(infer_does_not_outlive_static_from_impl)] Unspanned, } #[derive(Subdiagnostic)] pub enum ImplicitStaticLifetimeSubdiag { #[note(infer_implicit_static_lifetime_note)] Note { #[primary_span] span: Span, }, #[suggestion( infer_implicit_static_lifetime_suggestion, style = "verbose", code = " + '_", applicability = "maybe-incorrect" )] Sugg { #[primary_span] span: Span, }, } #[derive(Diagnostic)] #[diag(infer_mismatched_static_lifetime)] pub struct MismatchedStaticLifetime<'a> { #[primary_span] pub cause_span: Span, #[subdiagnostic] pub unmet_lifetime_reqs: IntroducesStaticBecauseUnmetLifetimeReq, #[subdiagnostic] pub expl: Option>, #[subdiagnostic] pub does_not_outlive_static_from_impl: DoesNotOutliveStaticFromImpl, #[subdiagnostic(eager)] pub implicit_static_lifetimes: Vec, }