compiler/rustc_pattern_analysis/src/errors.rs - rust-lang/rust - Git at Google

 use rustc_errors::{Diag, EmissionGuarantee, Subdiagnostic};
 use rustc_macros::{Diagnostic, LintDiagnostic, Subdiagnostic};
 use rustc_middle::ty::Ty;
 use rustc_span::Span;

 use crate::rustc::{RustcPatCtxt, WitnessPat};

 #[derive(Subdiagnostic)]
 #[label(pattern_analysis_uncovered)]
 pub struct Uncovered {
     #[primary_span]
     span: Span,
     count: usize,
     witness_1: String, // a printed pattern
     witness_2: String, // a printed pattern
     witness_3: String, // a printed pattern
     remainder: usize,
 }

 impl Uncovered {
     pub fn new<'p, 'tcx>(
         span: Span,
         cx: &RustcPatCtxt<'p, 'tcx>,
         witnesses: Vec<WitnessPat<'p, 'tcx>>,
     ) -> Self
     where
         'tcx: 'p,
     {
         let witness_1 = cx.print_witness_pat(witnesses.get(0).unwrap());
         Self {
             span,
             count: witnesses.len(),
             // Substitute dummy values if witnesses is smaller than 3. These will never be read.
             witness_2: witnesses.get(1).map(|w| cx.print_witness_pat(w)).unwrap_or_default(),
             witness_3: witnesses.get(2).map(|w| cx.print_witness_pat(w)).unwrap_or_default(),
             witness_1,
             remainder: witnesses.len().saturating_sub(3),
         }
     }
 }

 #[derive(LintDiagnostic)]
 #[diag(pattern_analysis_overlapping_range_endpoints)]
 #[note]
 pub struct OverlappingRangeEndpoints {
     #[label]
     pub range: Span,
     #[subdiagnostic]
     pub overlap: Vec<Overlap>,
 }

 pub struct Overlap {
     pub span: Span,
     pub range: String, // a printed pattern
 }

 impl Subdiagnostic for Overlap {
     fn add_to_diag<G: EmissionGuarantee>(self, diag: &mut Diag<'_, G>) {
         let Overlap { span, range } = self;

         // FIXME(mejrs) unfortunately `#[derive(LintDiagnostic)]`
         // does not support `#[subdiagnostic(eager)]`...
         let message = format!("this range overlaps on `{range}`...");
         diag.span_label(span, message);
     }
 }

 #[derive(LintDiagnostic)]
 #[diag(pattern_analysis_excluside_range_missing_max)]
 pub struct ExclusiveRangeMissingMax {
     #[label]
     #[suggestion(code = "{suggestion}", applicability = "maybe-incorrect")]
     /// This is an exclusive range that looks like `lo..max` (i.e. doesn't match `max`).
     pub first_range: Span,
     /// Suggest `lo..=max` instead.
     pub suggestion: String,
     pub max: String, // a printed pattern
 }

 #[derive(LintDiagnostic)]
 #[diag(pattern_analysis_excluside_range_missing_gap)]
 pub struct ExclusiveRangeMissingGap {
     #[label]
     #[suggestion(code = "{suggestion}", applicability = "maybe-incorrect")]
     /// This is an exclusive range that looks like `lo..gap` (i.e. doesn't match `gap`).
     pub first_range: Span,
     pub gap: String, // a printed pattern
     /// Suggest `lo..=gap` instead.
     pub suggestion: String,
     #[subdiagnostic]
     /// All these ranges skipped over `gap` which we think is probably a mistake.
     pub gap_with: Vec<GappedRange>,
 }

 pub struct GappedRange {
     pub span: Span,
     pub gap: String,         // a printed pattern
     pub first_range: String, // a printed pattern
 }

 impl Subdiagnostic for GappedRange {
     fn add_to_diag<G: EmissionGuarantee>(self, diag: &mut Diag<'_, G>) {
         let GappedRange { span, gap, first_range } = self;

         // FIXME(mejrs) unfortunately `#[derive(LintDiagnostic)]`
         // does not support `#[subdiagnostic(eager)]`...
         let message = format!(
             "this could appear to continue range `{first_range}`, but `{gap}` isn't matched by \
             either of them"
         );
         diag.span_label(span, message);
     }
 }

 #[derive(LintDiagnostic)]
 #[diag(pattern_analysis_non_exhaustive_omitted_pattern)]
 #[help]
 #[note]
 pub(crate) struct NonExhaustiveOmittedPattern<'tcx> {
     pub scrut_ty: Ty<'tcx>,
     #[subdiagnostic]
     pub uncovered: Uncovered,
 }

 #[derive(LintDiagnostic)]
 #[diag(pattern_analysis_non_exhaustive_omitted_pattern_lint_on_arm)]
 #[help]
 pub(crate) struct NonExhaustiveOmittedPatternLintOnArm {
     #[label]
     pub lint_span: Span,
     #[suggestion(code = "#[{lint_level}({lint_name})]\n", applicability = "maybe-incorrect")]
     pub suggest_lint_on_match: Option<Span>,
     pub lint_level: &'static str,
     pub lint_name: &'static str,
 }

 #[derive(Diagnostic)]
 #[diag(pattern_analysis_mixed_deref_pattern_constructors)]
 pub(crate) struct MixedDerefPatternConstructors<'tcx> {
     #[primary_span]
     pub spans: Vec<Span>,
     pub smart_pointer_ty: Ty<'tcx>,
     #[label(pattern_analysis_deref_pattern_label)]
     pub deref_pattern_label: Span,
     #[label(pattern_analysis_normal_constructor_label)]
     pub normal_constructor_label: Span,
 }
	use rustc_errors::{Diag, EmissionGuarantee, Subdiagnostic};
	use rustc_macros::{Diagnostic, LintDiagnostic, Subdiagnostic};
	use rustc_middle::ty::Ty;
	use rustc_span::Span;

	use crate::rustc::{RustcPatCtxt, WitnessPat};

	#[derive(Subdiagnostic)]
	#[label(pattern_analysis_uncovered)]
	pub struct Uncovered {
	#[primary_span]
	span: Span,
	count: usize,
	witness_1: String, // a printed pattern
	witness_2: String, // a printed pattern
	witness_3: String, // a printed pattern
	remainder: usize,
	}

	impl Uncovered {
	pub fn new<'p, 'tcx>(
	span: Span,
	cx: &RustcPatCtxt<'p, 'tcx>,
	witnesses: Vec<WitnessPat<'p, 'tcx>>,
	) -> Self
	where
	'tcx: 'p,
	{
	let witness_1 = cx.print_witness_pat(witnesses.get(0).unwrap());
	Self {
	span,
	count: witnesses.len(),
	// Substitute dummy values if witnesses is smaller than 3. These will never be read.
	witness_2: witnesses.get(1).map(\|w\| cx.print_witness_pat(w)).unwrap_or_default(),
	witness_3: witnesses.get(2).map(\|w\| cx.print_witness_pat(w)).unwrap_or_default(),
	witness_1,
	remainder: witnesses.len().saturating_sub(3),
	}
	}
	}

	#[derive(LintDiagnostic)]
	#[diag(pattern_analysis_overlapping_range_endpoints)]
	#[note]
	pub struct OverlappingRangeEndpoints {
	#[label]
	pub range: Span,
	#[subdiagnostic]
	pub overlap: Vec<Overlap>,
	}

	pub struct Overlap {
	pub span: Span,
	pub range: String, // a printed pattern
	}

	impl Subdiagnostic for Overlap {
	fn add_to_diag<G: EmissionGuarantee>(self, diag: &mut Diag<'_, G>) {
	let Overlap { span, range } = self;

	// FIXME(mejrs) unfortunately `#[derive(LintDiagnostic)]`
	// does not support `#[subdiagnostic(eager)]`...
	let message = format!("this range overlaps on `{range}`...");
	diag.span_label(span, message);
	}
	}

	#[derive(LintDiagnostic)]
	#[diag(pattern_analysis_excluside_range_missing_max)]
	pub struct ExclusiveRangeMissingMax {
	#[label]
	#[suggestion(code = "{suggestion}", applicability = "maybe-incorrect")]
	/// This is an exclusive range that looks like `lo..max` (i.e. doesn't match `max`).
	pub first_range: Span,
	/// Suggest `lo..=max` instead.
	pub suggestion: String,
	pub max: String, // a printed pattern
	}

	#[derive(LintDiagnostic)]
	#[diag(pattern_analysis_excluside_range_missing_gap)]
	pub struct ExclusiveRangeMissingGap {
	#[label]
	#[suggestion(code = "{suggestion}", applicability = "maybe-incorrect")]
	/// This is an exclusive range that looks like `lo..gap` (i.e. doesn't match `gap`).
	pub first_range: Span,
	pub gap: String, // a printed pattern
	/// Suggest `lo..=gap` instead.
	pub suggestion: String,
	#[subdiagnostic]
	/// All these ranges skipped over `gap` which we think is probably a mistake.
	pub gap_with: Vec<GappedRange>,
	}

	pub struct GappedRange {
	pub span: Span,
	pub gap: String, // a printed pattern
	pub first_range: String, // a printed pattern
	}

	impl Subdiagnostic for GappedRange {
	fn add_to_diag<G: EmissionGuarantee>(self, diag: &mut Diag<'_, G>) {
	let GappedRange { span, gap, first_range } = self;

	// FIXME(mejrs) unfortunately `#[derive(LintDiagnostic)]`
	// does not support `#[subdiagnostic(eager)]`...
	let message = format!(
	"this could appear to continue range `{first_range}`, but `{gap}` isn't matched by \
	either of them"
	);
	diag.span_label(span, message);
	}
	}

	#[derive(LintDiagnostic)]
	#[diag(pattern_analysis_non_exhaustive_omitted_pattern)]
	#[help]
	#[note]
	pub(crate) struct NonExhaustiveOmittedPattern<'tcx> {
	pub scrut_ty: Ty<'tcx>,
	#[subdiagnostic]
	pub uncovered: Uncovered,
	}

	#[derive(LintDiagnostic)]
	#[diag(pattern_analysis_non_exhaustive_omitted_pattern_lint_on_arm)]
	#[help]
	pub(crate) struct NonExhaustiveOmittedPatternLintOnArm {
	#[label]
	pub lint_span: Span,
	#[suggestion(code = "#[{lint_level}({lint_name})]\n", applicability = "maybe-incorrect")]
	pub suggest_lint_on_match: Option<Span>,
	pub lint_level: &'static str,
	pub lint_name: &'static str,
	}

	#[derive(Diagnostic)]
	#[diag(pattern_analysis_mixed_deref_pattern_constructors)]
	pub(crate) struct MixedDerefPatternConstructors<'tcx> {
	#[primary_span]
	pub spans: Vec<Span>,
	pub smart_pointer_ty: Ty<'tcx>,
	#[label(pattern_analysis_deref_pattern_label)]
	pub deref_pattern_label: Span,
	#[label(pattern_analysis_normal_constructor_label)]
	pub normal_constructor_label: Span,
	}