compiler/rustc_mir_dataflow/src/framework/lattice.rs - rust - Git at Google

 //! Traits used to represent [lattices] for use as the domain of a dataflow analysis.
 //!
 //! # Overview
 //!
 //! The most common lattice is a powerset of some set `S`, ordered by [set inclusion]. The [Hasse
 //! diagram] for the powerset of a set with two elements (`X` and `Y`) is shown below. Note that
 //! distinct elements at the same height in a Hasse diagram (e.g. `{X}` and `{Y}`) are
 //! *incomparable*, not equal.
 //!
 //! ```text
 //!      {X, Y}    <- top
 //!       /  \
 //!    {X}    {Y}
 //!       \  /
 //!        {}      <- bottom
 //!
 //! ```
 //!
 //! The defining characteristic of a lattice—the one that differentiates it from a [partially
 //! ordered set][poset]—is the existence of a *unique* least upper and greatest lower bound for
 //! every pair of elements. The lattice join operator (`∨`) returns the least upper bound, and the
 //! lattice meet operator (`∧`) returns the greatest lower bound. Types that implement one operator
 //! but not the other are known as semilattices. Dataflow analysis only uses the join operator and
 //! will work with any join-semilattice, but both should be specified when possible.
 //!
 //! ## `PartialOrd`
 //!
 //! Given that it represents a partially ordered set, you may be surprised that [`JoinSemiLattice`]
 //! does not have [`PartialOrd`] as a supertrait. This
 //! is because most standard library types use lexicographic ordering instead of set inclusion for
 //! their `PartialOrd` impl. Since we do not actually need to compare lattice elements to run a
 //! dataflow analysis, there's no need for a newtype wrapper with a custom `PartialOrd` impl. The
 //! only benefit would be the ability to check that the least upper (or greatest lower) bound
 //! returned by the lattice join (or meet) operator was in fact greater (or lower) than the inputs.
 //!
 //! [lattices]: https://en.wikipedia.org/wiki/Lattice_(order)
 //! [set inclusion]: https://en.wikipedia.org/wiki/Subset
 //! [Hasse diagram]: https://en.wikipedia.org/wiki/Hasse_diagram
 //! [poset]: https://en.wikipedia.org/wiki/Partially_ordered_set

 use rustc_index::Idx;
 use rustc_index::bit_set::{DenseBitSet, MixedBitSet};

 use crate::framework::BitSetExt;

 /// A [partially ordered set][poset] that has a [least upper bound][lub] for any pair of elements
 /// in the set.
 ///
 /// [lub]: https://en.wikipedia.org/wiki/Infimum_and_supremum
 /// [poset]: https://en.wikipedia.org/wiki/Partially_ordered_set
 pub trait JoinSemiLattice: Eq {
     /// Computes the least upper bound of two elements, storing the result in `self` and returning
     /// `true` if `self` has changed.
     ///
     /// The lattice join operator is abbreviated as `∨`.
     fn join(&mut self, other: &Self) -> bool;
 }

 /// A set that has a "bottom" element, which is less than or equal to any other element.
 pub trait HasBottom {
     const BOTTOM: Self;

     fn is_bottom(&self) -> bool;
 }

 /// A set that has a "top" element, which is greater than or equal to any other element.
 pub trait HasTop {
     const TOP: Self;
 }

 /// A `DenseBitSet` represents the lattice formed by the powerset of all possible values of the
 /// index type `T` ordered by inclusion. Equivalently, it is a tuple of "two-point" lattices, one
 /// for each possible value of `T`.
 impl<T: Idx> JoinSemiLattice for DenseBitSet<T> {
     fn join(&mut self, other: &Self) -> bool {
         self.union(other)
     }
 }

 impl<T: Idx> JoinSemiLattice for MixedBitSet<T> {
     fn join(&mut self, other: &Self) -> bool {
         self.union(other)
     }
 }

 /// Extends a type `T` with top and bottom elements to make it a partially ordered set in which no
 /// value of `T` is comparable with any other.
 ///
 /// A flat set has the following [Hasse diagram]:
 ///
 /// ```text
 ///          top
 ///  / ... / /  \ \ ... \
 /// all possible values of `T`
 ///  \ ... \ \  / / ... /
 ///         bottom
 /// ```
 ///
 /// [Hasse diagram]: https://en.wikipedia.org/wiki/Hasse_diagram
 #[derive(Clone, Copy, Debug, PartialEq, Eq)]
 pub enum FlatSet<T> {
     Bottom,
     Elem(T),
     Top,
 }

 impl<T: Clone + Eq> JoinSemiLattice for FlatSet<T> {
     fn join(&mut self, other: &Self) -> bool {
         let result = match (&*self, other) {
             (Self::Top, _) | (_, Self::Bottom) => return false,
             (Self::Elem(a), Self::Elem(b)) if a == b => return false,

             (Self::Bottom, Self::Elem(x)) => Self::Elem(x.clone()),

             _ => Self::Top,
         };

         *self = result;
         true
     }
 }

 impl<T> HasBottom for FlatSet<T> {
     const BOTTOM: Self = Self::Bottom;

     fn is_bottom(&self) -> bool {
         matches!(self, Self::Bottom)
     }
 }

 impl<T> HasTop for FlatSet<T> {
     const TOP: Self = Self::Top;
 }

 /// Extend a lattice with a bottom value to represent an unreachable execution.
 ///
 /// The only useful action on an unreachable state is joining it with a reachable one to make it
 /// reachable. All other actions, gen/kill for instance, are no-ops.
 #[derive(PartialEq, Eq, Debug)]
 pub enum MaybeReachable<T> {
     Unreachable,
     Reachable(T),
 }

 impl<T> MaybeReachable<T> {
     pub fn is_reachable(&self) -> bool {
         matches!(self, MaybeReachable::Reachable(_))
     }
 }

 impl<S> MaybeReachable<S> {
     /// Return whether the current state contains the given element. If the state is unreachable,
     /// it does no contain anything.
     pub fn contains<T>(&self, elem: T) -> bool
     where
         S: BitSetExt<T>,
     {
         match self {
             MaybeReachable::Unreachable => false,
             MaybeReachable::Reachable(set) => set.contains(elem),
         }
     }
 }

 impl<T, S: BitSetExt<T>> BitSetExt<T> for MaybeReachable<S> {
     fn contains(&self, elem: T) -> bool {
         self.contains(elem)
     }
 }

 impl<V: Clone> Clone for MaybeReachable<V> {
     fn clone(&self) -> Self {
         match self {
             MaybeReachable::Reachable(x) => MaybeReachable::Reachable(x.clone()),
             MaybeReachable::Unreachable => MaybeReachable::Unreachable,
         }
     }

     fn clone_from(&mut self, source: &Self) {
         match (&mut *self, source) {
             (MaybeReachable::Reachable(x), MaybeReachable::Reachable(y)) => {
                 x.clone_from(y);
             }
             _ => *self = source.clone(),
         }
     }
 }

 impl<T: JoinSemiLattice + Clone> JoinSemiLattice for MaybeReachable<T> {
     fn join(&mut self, other: &Self) -> bool {
         // Unreachable acts as a bottom.
         match (&mut *self, &other) {
             (_, MaybeReachable::Unreachable) => false,
             (MaybeReachable::Unreachable, _) => {
                 *self = other.clone();
                 true
             }
             (MaybeReachable::Reachable(this), MaybeReachable::Reachable(other)) => this.join(other),
         }
     }
 }
	//! Traits used to represent [lattices] for use as the domain of a dataflow analysis.
	//!
	//! # Overview
	//!
	//! The most common lattice is a powerset of some set `S`, ordered by [set inclusion]. The [Hasse
	//! diagram] for the powerset of a set with two elements (`X` and `Y`) is shown below. Note that
	//! distinct elements at the same height in a Hasse diagram (e.g. `{X}` and `{Y}`) are
	//! incomparable, not equal.
	//!
	//! ```text
	//! {X, Y} <- top
	//! / \
	//! {X} {Y}
	//! \ /
	//! {} <- bottom
	//!
	//! ```
	//!
	//! The defining characteristic of a lattice—the one that differentiates it from a [partially
	//! ordered set][poset]—is the existence of a unique least upper and greatest lower bound for
	//! every pair of elements. The lattice join operator (`∨`) returns the least upper bound, and the
	//! lattice meet operator (`∧`) returns the greatest lower bound. Types that implement one operator
	//! but not the other are known as semilattices. Dataflow analysis only uses the join operator and
	//! will work with any join-semilattice, but both should be specified when possible.
	//!
	//! ## `PartialOrd`
	//!
	//! Given that it represents a partially ordered set, you may be surprised that [`JoinSemiLattice`]
	//! does not have [`PartialOrd`] as a supertrait. This
	//! is because most standard library types use lexicographic ordering instead of set inclusion for
	//! their `PartialOrd` impl. Since we do not actually need to compare lattice elements to run a
	//! dataflow analysis, there's no need for a newtype wrapper with a custom `PartialOrd` impl. The
	//! only benefit would be the ability to check that the least upper (or greatest lower) bound
	//! returned by the lattice join (or meet) operator was in fact greater (or lower) than the inputs.
	//!
	//! [lattices]: https://en.wikipedia.org/wiki/Lattice_(order)
	//! [set inclusion]: https://en.wikipedia.org/wiki/Subset
	//! [Hasse diagram]: https://en.wikipedia.org/wiki/Hasse_diagram
	//! [poset]: https://en.wikipedia.org/wiki/Partially_ordered_set

	use rustc_index::Idx;
	use rustc_index::bit_set::{DenseBitSet, MixedBitSet};

	use crate::framework::BitSetExt;

	/// A [partially ordered set][poset] that has a [least upper bound][lub] for any pair of elements
	/// in the set.
	///
	/// [lub]: https://en.wikipedia.org/wiki/Infimum_and_supremum
	/// [poset]: https://en.wikipedia.org/wiki/Partially_ordered_set
	pub trait JoinSemiLattice: Eq {
	/// Computes the least upper bound of two elements, storing the result in `self` and returning
	/// `true` if `self` has changed.
	///
	/// The lattice join operator is abbreviated as `∨`.
	fn join(&mut self, other: &Self) -> bool;
	}

	/// A set that has a "bottom" element, which is less than or equal to any other element.
	pub trait HasBottom {
	const BOTTOM: Self;

	fn is_bottom(&self) -> bool;
	}

	/// A set that has a "top" element, which is greater than or equal to any other element.
	pub trait HasTop {
	const TOP: Self;
	}

	/// A `DenseBitSet` represents the lattice formed by the powerset of all possible values of the
	/// index type `T` ordered by inclusion. Equivalently, it is a tuple of "two-point" lattices, one
	/// for each possible value of `T`.
	impl<T: Idx> JoinSemiLattice for DenseBitSet<T> {
	fn join(&mut self, other: &Self) -> bool {
	self.union(other)
	}
	}

	impl<T: Idx> JoinSemiLattice for MixedBitSet<T> {
	fn join(&mut self, other: &Self) -> bool {
	self.union(other)
	}
	}

	/// Extends a type `T` with top and bottom elements to make it a partially ordered set in which no
	/// value of `T` is comparable with any other.
	///
	/// A flat set has the following [Hasse diagram]:
	///
	/// ```text
	/// top
	/// / ... / / \ \ ... \
	/// all possible values of `T`
	/// \ ... \ \ / / ... /
	/// bottom
	/// ```
	///
	/// [Hasse diagram]: https://en.wikipedia.org/wiki/Hasse_diagram
	#[derive(Clone, Copy, Debug, PartialEq, Eq)]
	pub enum FlatSet<T> {
	Bottom,
	Elem(T),
	Top,
	}

	impl<T: Clone + Eq> JoinSemiLattice for FlatSet<T> {
	fn join(&mut self, other: &Self) -> bool {
	let result = match (&*self, other) {
	(Self::Top, _) \| (_, Self::Bottom) => return false,
	(Self::Elem(a), Self::Elem(b)) if a == b => return false,

	(Self::Bottom, Self::Elem(x)) => Self::Elem(x.clone()),

	_ => Self::Top,
	};

	*self = result;
	true
	}
	}

	impl<T> HasBottom for FlatSet<T> {
	const BOTTOM: Self = Self::Bottom;

	fn is_bottom(&self) -> bool {
	matches!(self, Self::Bottom)
	}
	}

	impl<T> HasTop for FlatSet<T> {
	const TOP: Self = Self::Top;
	}

	/// Extend a lattice with a bottom value to represent an unreachable execution.
	///
	/// The only useful action on an unreachable state is joining it with a reachable one to make it
	/// reachable. All other actions, gen/kill for instance, are no-ops.
	#[derive(PartialEq, Eq, Debug)]
	pub enum MaybeReachable<T> {
	Unreachable,
	Reachable(T),
	}

	impl<T> MaybeReachable<T> {
	pub fn is_reachable(&self) -> bool {
	matches!(self, MaybeReachable::Reachable(_))
	}
	}

	impl<S> MaybeReachable<S> {
	/// Return whether the current state contains the given element. If the state is unreachable,
	/// it does no contain anything.
	pub fn contains<T>(&self, elem: T) -> bool
	where
	S: BitSetExt<T>,
	{
	match self {
	MaybeReachable::Unreachable => false,
	MaybeReachable::Reachable(set) => set.contains(elem),
	}
	}
	}

	impl<T, S: BitSetExt<T>> BitSetExt<T> for MaybeReachable<S> {
	fn contains(&self, elem: T) -> bool {
	self.contains(elem)
	}
	}

	impl<V: Clone> Clone for MaybeReachable<V> {
	fn clone(&self) -> Self {
	match self {
	MaybeReachable::Reachable(x) => MaybeReachable::Reachable(x.clone()),
	MaybeReachable::Unreachable => MaybeReachable::Unreachable,
	}
	}

	fn clone_from(&mut self, source: &Self) {
	match (&mut *self, source) {
	(MaybeReachable::Reachable(x), MaybeReachable::Reachable(y)) => {
	x.clone_from(y);
	}
	_ => *self = source.clone(),
	}
	}
	}

	impl<T: JoinSemiLattice + Clone> JoinSemiLattice for MaybeReachable<T> {
	fn join(&mut self, other: &Self) -> bool {
	// Unreachable acts as a bottom.
	match (&mut *self, &other) {
	(_, MaybeReachable::Unreachable) => false,
	(MaybeReachable::Unreachable, _) => {
	*self = other.clone();
	true
	}
	(MaybeReachable::Reachable(this), MaybeReachable::Reachable(other)) => this.join(other),
	}
	}
	}