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

 //! Analysis of patterns, notably match exhaustiveness checking. The main entrypoint for this crate
 //! is [`usefulness::compute_match_usefulness`]. For rustc-specific types and entrypoints, see the
 //! [`rustc`] module.

 // tidy-alphabetical-start
 #![allow(rustc::diagnostic_outside_of_impl)]
 #![allow(rustc::untranslatable_diagnostic)]
 #![allow(unused_crate_dependencies)]
 // tidy-alphabetical-end

 pub(crate) mod checks;
 pub mod constructor;
 #[cfg(feature = "rustc")]
 pub mod errors;
 #[cfg(feature = "rustc")]
 pub(crate) mod lints;
 pub mod pat;
 pub mod pat_column;
 #[cfg(feature = "rustc")]
 pub mod rustc;
 pub mod usefulness;

 #[cfg(feature = "rustc")]
 rustc_fluent_macro::fluent_messages! { "../messages.ftl" }

 use std::fmt;

 pub use rustc_index::{Idx, IndexVec}; // re-exported to avoid rustc_index version issues

 use crate::constructor::{Constructor, ConstructorSet, IntRange};
 use crate::pat::DeconstructedPat;

 pub trait Captures<'a> {}
 impl<'a, T: ?Sized> Captures<'a> for T {}

 /// `bool` newtype that indicates whether this is a privately uninhabited field that we should skip
 /// during analysis.
 #[derive(Copy, Clone, Debug, PartialEq, Eq)]
 pub struct PrivateUninhabitedField(pub bool);

 /// Context that provides type information about constructors.
 ///
 /// Most of the crate is parameterized on a type that implements this trait.
 pub trait PatCx: Sized + fmt::Debug {
     /// The type of a pattern.
     type Ty: Clone + fmt::Debug;
     /// Errors that can abort analysis.
     type Error: fmt::Debug;
     /// The index of an enum variant.
     type VariantIdx: Clone + Idx + fmt::Debug;
     /// A string literal
     type StrLit: Clone + PartialEq + fmt::Debug;
     /// Extra data to store in a match arm.
     type ArmData: Copy + Clone + fmt::Debug;
     /// Extra data to store in a pattern.
     type PatData: Clone;

     fn is_exhaustive_patterns_feature_on(&self) -> bool;

     /// Whether to ensure the non-exhaustiveness witnesses we report for a complete set. This is
     /// `false` by default to avoid some exponential blowup cases such as
     /// <https://github.com/rust-lang/rust/issues/118437>.
     fn exhaustive_witnesses(&self) -> bool {
         false
     }

     /// The number of fields for this constructor.
     fn ctor_arity(&self, ctor: &Constructor<Self>, ty: &Self::Ty) -> usize;

     /// The types of the fields for this constructor. The result must contain `ctor_arity()` fields.
     fn ctor_sub_tys(
         &self,
         ctor: &Constructor<Self>,
         ty: &Self::Ty,
     ) -> impl Iterator<Item = (Self::Ty, PrivateUninhabitedField)> + ExactSizeIterator;

     /// The set of all the constructors for `ty`.
     ///
     /// This must follow the invariants of `ConstructorSet`
     fn ctors_for_ty(&self, ty: &Self::Ty) -> Result<ConstructorSet<Self>, Self::Error>;

     /// Write the name of the variant represented by `pat`. Used for the best-effort `Debug` impl of
     /// `DeconstructedPat`. Only invoqued when `pat.ctor()` is `Struct | Variant(_) | UnionField`.
     fn write_variant_name(
         f: &mut fmt::Formatter<'_>,
         ctor: &crate::constructor::Constructor<Self>,
         ty: &Self::Ty,
     ) -> fmt::Result;

     /// Raise a bug.
     fn bug(&self, fmt: fmt::Arguments<'_>) -> Self::Error;

     /// Lint that the range `pat` overlapped with all the ranges in `overlaps_with`, where the range
     /// they overlapped over is `overlaps_on`. We only detect singleton overlaps.
     /// The default implementation does nothing.
     fn lint_overlapping_range_endpoints(
         &self,
         _pat: &DeconstructedPat<Self>,
         _overlaps_on: IntRange,
         _overlaps_with: &[&DeconstructedPat<Self>],
     ) {
     }

     /// The maximum pattern complexity limit was reached.
     fn complexity_exceeded(&self) -> Result<(), Self::Error>;

     /// Lint that there is a gap `gap` between `pat` and all of `gapped_with` such that the gap is
     /// not matched by another range. If `gapped_with` is empty, then `gap` is `T::MAX`. We only
     /// detect singleton gaps.
     /// The default implementation does nothing.
     fn lint_non_contiguous_range_endpoints(
         &self,
         _pat: &DeconstructedPat<Self>,
         _gap: IntRange,
         _gapped_with: &[&DeconstructedPat<Self>],
     ) {
     }

     /// Check if we may need to perform additional deref-pattern-specific validation.
     fn match_may_contain_deref_pats(&self) -> bool {
         true
     }

     /// The current implementation of deref patterns requires that they can't match on the same
     /// place as a normal constructor. Since this isn't caught by type-checking, we check it in the
     /// `PatCx` before running the analysis. This reports an error if the check fails.
     fn report_mixed_deref_pat_ctors(
         &self,
         deref_pat: &DeconstructedPat<Self>,
         normal_pat: &DeconstructedPat<Self>,
     ) -> Self::Error;
 }

 /// The arm of a match expression.
 #[derive(Debug)]
 pub struct MatchArm<'p, Cx: PatCx> {
     pub pat: &'p DeconstructedPat<Cx>,
     pub has_guard: bool,
     pub arm_data: Cx::ArmData,
 }

 impl<'p, Cx: PatCx> Clone for MatchArm<'p, Cx> {
     fn clone(&self) -> Self {
         Self { pat: self.pat, has_guard: self.has_guard, arm_data: self.arm_data }
     }
 }

 impl<'p, Cx: PatCx> Copy for MatchArm<'p, Cx> {}
	//! Analysis of patterns, notably match exhaustiveness checking. The main entrypoint for this crate
	//! is [`usefulness::compute_match_usefulness`]. For rustc-specific types and entrypoints, see the
	//! [`rustc`] module.

	// tidy-alphabetical-start
	#![allow(rustc::diagnostic_outside_of_impl)]
	#![allow(rustc::untranslatable_diagnostic)]
	#![allow(unused_crate_dependencies)]
	// tidy-alphabetical-end

	pub(crate) mod checks;
	pub mod constructor;
	#[cfg(feature = "rustc")]
	pub mod errors;
	#[cfg(feature = "rustc")]
	pub(crate) mod lints;
	pub mod pat;
	pub mod pat_column;
	#[cfg(feature = "rustc")]
	pub mod rustc;
	pub mod usefulness;

	#[cfg(feature = "rustc")]
	rustc_fluent_macro::fluent_messages! { "../messages.ftl" }

	use std::fmt;

	pub use rustc_index::{Idx, IndexVec}; // re-exported to avoid rustc_index version issues

	use crate::constructor::{Constructor, ConstructorSet, IntRange};
	use crate::pat::DeconstructedPat;

	pub trait Captures<'a> {}
	impl<'a, T: ?Sized> Captures<'a> for T {}

	/// `bool` newtype that indicates whether this is a privately uninhabited field that we should skip
	/// during analysis.
	#[derive(Copy, Clone, Debug, PartialEq, Eq)]
	pub struct PrivateUninhabitedField(pub bool);

	/// Context that provides type information about constructors.
	///
	/// Most of the crate is parameterized on a type that implements this trait.
	pub trait PatCx: Sized + fmt::Debug {
	/// The type of a pattern.
	type Ty: Clone + fmt::Debug;
	/// Errors that can abort analysis.
	type Error: fmt::Debug;
	/// The index of an enum variant.
	type VariantIdx: Clone + Idx + fmt::Debug;
	/// A string literal
	type StrLit: Clone + PartialEq + fmt::Debug;
	/// Extra data to store in a match arm.
	type ArmData: Copy + Clone + fmt::Debug;
	/// Extra data to store in a pattern.
	type PatData: Clone;

	fn is_exhaustive_patterns_feature_on(&self) -> bool;

	/// Whether to ensure the non-exhaustiveness witnesses we report for a complete set. This is
	/// `false` by default to avoid some exponential blowup cases such as
	/// <https://github.com/rust-lang/rust/issues/118437>.
	fn exhaustive_witnesses(&self) -> bool {
	false
	}

	/// The number of fields for this constructor.
	fn ctor_arity(&self, ctor: &Constructor<Self>, ty: &Self::Ty) -> usize;

	/// The types of the fields for this constructor. The result must contain `ctor_arity()` fields.
	fn ctor_sub_tys(
	&self,
	ctor: &Constructor<Self>,
	ty: &Self::Ty,
	) -> impl Iterator<Item = (Self::Ty, PrivateUninhabitedField)> + ExactSizeIterator;

	/// The set of all the constructors for `ty`.
	///
	/// This must follow the invariants of `ConstructorSet`
	fn ctors_for_ty(&self, ty: &Self::Ty) -> Result<ConstructorSet<Self>, Self::Error>;

	/// Write the name of the variant represented by `pat`. Used for the best-effort `Debug` impl of
	/// `DeconstructedPat`. Only invoqued when `pat.ctor()` is `Struct \| Variant(_) \| UnionField`.
	fn write_variant_name(
	f: &mut fmt::Formatter<'_>,
	ctor: &crate::constructor::Constructor<Self>,
	ty: &Self::Ty,
	) -> fmt::Result;

	/// Raise a bug.
	fn bug(&self, fmt: fmt::Arguments<'_>) -> Self::Error;

	/// Lint that the range `pat` overlapped with all the ranges in `overlaps_with`, where the range
	/// they overlapped over is `overlaps_on`. We only detect singleton overlaps.
	/// The default implementation does nothing.
	fn lint_overlapping_range_endpoints(
	&self,
	_pat: &DeconstructedPat<Self>,
	_overlaps_on: IntRange,
	_overlaps_with: &[&DeconstructedPat<Self>],
	) {
	}

	/// The maximum pattern complexity limit was reached.
	fn complexity_exceeded(&self) -> Result<(), Self::Error>;

	/// Lint that there is a gap `gap` between `pat` and all of `gapped_with` such that the gap is
	/// not matched by another range. If `gapped_with` is empty, then `gap` is `T::MAX`. We only
	/// detect singleton gaps.
	/// The default implementation does nothing.
	fn lint_non_contiguous_range_endpoints(
	&self,
	_pat: &DeconstructedPat<Self>,
	_gap: IntRange,
	_gapped_with: &[&DeconstructedPat<Self>],
	) {
	}

	/// Check if we may need to perform additional deref-pattern-specific validation.
	fn match_may_contain_deref_pats(&self) -> bool {
	true
	}

	/// The current implementation of deref patterns requires that they can't match on the same
	/// place as a normal constructor. Since this isn't caught by type-checking, we check it in the
	/// `PatCx` before running the analysis. This reports an error if the check fails.
	fn report_mixed_deref_pat_ctors(
	&self,
	deref_pat: &DeconstructedPat<Self>,
	normal_pat: &DeconstructedPat<Self>,
	) -> Self::Error;
	}

	/// The arm of a match expression.
	#[derive(Debug)]
	pub struct MatchArm<'p, Cx: PatCx> {
	pub pat: &'p DeconstructedPat<Cx>,
	pub has_guard: bool,
	pub arm_data: Cx::ArmData,
	}

	impl<'p, Cx: PatCx> Clone for MatchArm<'p, Cx> {
	fn clone(&self) -> Self {
	Self { pat: self.pat, has_guard: self.has_guard, arm_data: self.arm_data }
	}
	}

	impl<'p, Cx: PatCx> Copy for MatchArm<'p, Cx> {}