compiler/rustc_infer/src/infer/lattice.rs - toolchain/rustc - Git at Google

 //! # Lattice variables
 //!
 //! Generic code for operating on [lattices] of inference variables
 //! that are characterized by an upper- and lower-bound.
 //!
 //! The code is defined quite generically so that it can be
 //! applied both to type variables, which represent types being inferred,
 //! and fn variables, which represent function types being inferred.
 //! (It may eventually be applied to their types as well.)
 //! In some cases, the functions are also generic with respect to the
 //! operation on the lattice (GLB vs LUB).
 //!
 //! ## Note
 //!
 //! Although all the functions are generic, for simplicity, comments in the source code
 //! generally refer to type variables and the LUB operation.
 //!
 //! [lattices]: https://en.wikipedia.org/wiki/Lattice_(order)

 use super::combine::ObligationEmittingRelation;
 use super::type_variable::{TypeVariableOrigin, TypeVariableOriginKind};
 use super::{DefineOpaqueTypes, InferCtxt};

 use crate::traits::ObligationCause;
 use rustc_middle::ty::relate::RelateResult;
 use rustc_middle::ty::TyVar;
 use rustc_middle::ty::{self, Ty};

 /// Trait for returning data about a lattice, and for abstracting
 /// over the "direction" of the lattice operation (LUB/GLB).
 ///
 /// GLB moves "down" the lattice (to smaller values); LUB moves
 /// "up" the lattice (to bigger values).
 pub trait LatticeDir<'f, 'tcx>: ObligationEmittingRelation<'tcx> {
     fn infcx(&self) -> &'f InferCtxt<'tcx>;

     fn cause(&self) -> &ObligationCause<'tcx>;

     fn define_opaque_types(&self) -> DefineOpaqueTypes;

     // Relates the type `v` to `a` and `b` such that `v` represents
     // the LUB/GLB of `a` and `b` as appropriate.
     //
     // Subtle hack: ordering *may* be significant here. This method
     // relates `v` to `a` first, which may help us to avoid unnecessary
     // type variable obligations. See caller for details.
     fn relate_bound(&mut self, v: Ty<'tcx>, a: Ty<'tcx>, b: Ty<'tcx>) -> RelateResult<'tcx, ()>;
 }

 /// Relates two types using a given lattice.
 #[instrument(skip(this), level = "debug")]
 pub fn super_lattice_tys<'a, 'tcx: 'a, L>(
     this: &mut L,
     a: Ty<'tcx>,
     b: Ty<'tcx>,
 ) -> RelateResult<'tcx, Ty<'tcx>>
 where
     L: LatticeDir<'a, 'tcx>,
 {
     debug!("{}", this.tag());

     if a == b {
         return Ok(a);
     }

     let infcx = this.infcx();

     let a = infcx.inner.borrow_mut().type_variables().replace_if_possible(a);
     let b = infcx.inner.borrow_mut().type_variables().replace_if_possible(b);

     match (a.kind(), b.kind()) {
         // If one side is known to be a variable and one is not,
         // create a variable (`v`) to represent the LUB. Make sure to
         // relate `v` to the non-type-variable first (by passing it
         // first to `relate_bound`). Otherwise, we would produce a
         // subtype obligation that must then be processed.
         //
         // Example: if the LHS is a type variable, and RHS is
         // `Box<i32>`, then we current compare `v` to the RHS first,
         // which will instantiate `v` with `Box<i32>`. Then when `v`
         // is compared to the LHS, we instantiate LHS with `Box<i32>`.
         // But if we did in reverse order, we would create a `v <:
         // LHS` (or vice versa) constraint and then instantiate
         // `v`. This would require further processing to achieve same
         // end-result; in particular, this screws up some of the logic
         // in coercion, which expects LUB to figure out that the LHS
         // is (e.g.) `Box<i32>`. A more obvious solution might be to
         // iterate on the subtype obligations that are returned, but I
         // think this suffices. -nmatsakis
         (&ty::Infer(TyVar(..)), _) => {
             let v = infcx.next_ty_var(TypeVariableOrigin {
                 kind: TypeVariableOriginKind::LatticeVariable,
                 span: this.cause().span,
             });
             this.relate_bound(v, b, a)?;
             Ok(v)
         }
         (_, &ty::Infer(TyVar(..))) => {
             let v = infcx.next_ty_var(TypeVariableOrigin {
                 kind: TypeVariableOriginKind::LatticeVariable,
                 span: this.cause().span,
             });
             this.relate_bound(v, a, b)?;
             Ok(v)
         }

         (
             &ty::Alias(ty::Opaque, ty::AliasTy { def_id: a_def_id, .. }),
             &ty::Alias(ty::Opaque, ty::AliasTy { def_id: b_def_id, .. }),
         ) if a_def_id == b_def_id => infcx.super_combine_tys(this, a, b),

         (&ty::Alias(ty::Opaque, ty::AliasTy { def_id, .. }), _)
         | (_, &ty::Alias(ty::Opaque, ty::AliasTy { def_id, .. }))
             if this.define_opaque_types() == DefineOpaqueTypes::Yes
                 && def_id.is_local()
                 && !this.tcx().trait_solver_next() =>
         {
             this.register_obligations(
                 infcx
                     .handle_opaque_type(a, b, this.a_is_expected(), this.cause(), this.param_env())?
                     .obligations,
             );
             Ok(a)
         }

         _ => infcx.super_combine_tys(this, a, b),
     }
 }
	//! # Lattice variables
	//!
	//! Generic code for operating on [lattices] of inference variables
	//! that are characterized by an upper- and lower-bound.
	//!
	//! The code is defined quite generically so that it can be
	//! applied both to type variables, which represent types being inferred,
	//! and fn variables, which represent function types being inferred.
	//! (It may eventually be applied to their types as well.)
	//! In some cases, the functions are also generic with respect to the
	//! operation on the lattice (GLB vs LUB).
	//!
	//! ## Note
	//!
	//! Although all the functions are generic, for simplicity, comments in the source code
	//! generally refer to type variables and the LUB operation.
	//!
	//! [lattices]: https://en.wikipedia.org/wiki/Lattice_(order)

	use super::combine::ObligationEmittingRelation;
	use super::type_variable::{TypeVariableOrigin, TypeVariableOriginKind};
	use super::{DefineOpaqueTypes, InferCtxt};

	use crate::traits::ObligationCause;
	use rustc_middle::ty::relate::RelateResult;
	use rustc_middle::ty::TyVar;
	use rustc_middle::ty::{self, Ty};

	/// Trait for returning data about a lattice, and for abstracting
	/// over the "direction" of the lattice operation (LUB/GLB).
	///
	/// GLB moves "down" the lattice (to smaller values); LUB moves
	/// "up" the lattice (to bigger values).
	pub trait LatticeDir<'f, 'tcx>: ObligationEmittingRelation<'tcx> {
	fn infcx(&self) -> &'f InferCtxt<'tcx>;

	fn cause(&self) -> &ObligationCause<'tcx>;

	fn define_opaque_types(&self) -> DefineOpaqueTypes;

	// Relates the type `v` to `a` and `b` such that `v` represents
	// the LUB/GLB of `a` and `b` as appropriate.
	//
	// Subtle hack: ordering may be significant here. This method
	// relates `v` to `a` first, which may help us to avoid unnecessary
	// type variable obligations. See caller for details.
	fn relate_bound(&mut self, v: Ty<'tcx>, a: Ty<'tcx>, b: Ty<'tcx>) -> RelateResult<'tcx, ()>;
	}

	/// Relates two types using a given lattice.
	#[instrument(skip(this), level = "debug")]
	pub fn super_lattice_tys<'a, 'tcx: 'a, L>(
	this: &mut L,
	a: Ty<'tcx>,
	b: Ty<'tcx>,
	) -> RelateResult<'tcx, Ty<'tcx>>
	where
	L: LatticeDir<'a, 'tcx>,
	{
	debug!("{}", this.tag());

	if a == b {
	return Ok(a);
	}

	let infcx = this.infcx();

	let a = infcx.inner.borrow_mut().type_variables().replace_if_possible(a);
	let b = infcx.inner.borrow_mut().type_variables().replace_if_possible(b);

	match (a.kind(), b.kind()) {
	// If one side is known to be a variable and one is not,
	// create a variable (`v`) to represent the LUB. Make sure to
	// relate `v` to the non-type-variable first (by passing it
	// first to `relate_bound`). Otherwise, we would produce a
	// subtype obligation that must then be processed.
	//
	// Example: if the LHS is a type variable, and RHS is
	// `Box<i32>`, then we current compare `v` to the RHS first,
	// which will instantiate `v` with `Box<i32>`. Then when `v`
	// is compared to the LHS, we instantiate LHS with `Box<i32>`.
	// But if we did in reverse order, we would create a `v <:
	// LHS` (or vice versa) constraint and then instantiate
	// `v`. This would require further processing to achieve same
	// end-result; in particular, this screws up some of the logic
	// in coercion, which expects LUB to figure out that the LHS
	// is (e.g.) `Box<i32>`. A more obvious solution might be to
	// iterate on the subtype obligations that are returned, but I
	// think this suffices. -nmatsakis
	(&ty::Infer(TyVar(..)), _) => {
	let v = infcx.next_ty_var(TypeVariableOrigin {
	kind: TypeVariableOriginKind::LatticeVariable,
	span: this.cause().span,
	});
	this.relate_bound(v, b, a)?;
	Ok(v)
	}
	(_, &ty::Infer(TyVar(..))) => {
	let v = infcx.next_ty_var(TypeVariableOrigin {
	kind: TypeVariableOriginKind::LatticeVariable,
	span: this.cause().span,
	});
	this.relate_bound(v, a, b)?;
	Ok(v)
	}

	(
	&ty::Alias(ty::Opaque, ty::AliasTy { def_id: a_def_id, .. }),
	&ty::Alias(ty::Opaque, ty::AliasTy { def_id: b_def_id, .. }),
	) if a_def_id == b_def_id => infcx.super_combine_tys(this, a, b),

	(&ty::Alias(ty::Opaque, ty::AliasTy { def_id, .. }), _)
	\| (_, &ty::Alias(ty::Opaque, ty::AliasTy { def_id, .. }))
	if this.define_opaque_types() == DefineOpaqueTypes::Yes
	&& def_id.is_local()
	&& !this.tcx().trait_solver_next() =>
	{
	this.register_obligations(
	infcx
	.handle_opaque_type(a, b, this.a_is_expected(), this.cause(), this.param_env())?
	.obligations,
	);
	Ok(a)
	}

	_ => infcx.super_combine_tys(this, a, b),
	}
	}