src/librustc/middle/free_region.rs - third_party/rust - Git at Google

 //! This module handles the relationships between "free regions", i.e., lifetime parameters.
 //! Ordinarily, free regions are unrelated to one another, but they can be related via implied
 //! or explicit bounds. In that case, we track the bounds using the `TransitiveRelation` type,
 //! and use that to decide when one free region outlives another, and so forth.

 use crate::infer::outlives::free_region_map::{FreeRegionMap, FreeRegionRelations};
 use crate::hir::def_id::DefId;
 use crate::middle::region;
 use crate::ty::{self, TyCtxt, Region};

 /// Combines a `region::ScopeTree` (which governs relationships between
 /// scopes) and a `FreeRegionMap` (which governs relationships between
 /// free regions) to yield a complete relation between concrete
 /// regions.
 ///
 /// This stuff is a bit convoluted and should be refactored, but as we
 /// transition to NLL, it'll all go away anyhow.
 pub struct RegionRelations<'a, 'tcx> {
     pub tcx: TyCtxt<'tcx>,

     /// The context used to fetch the region maps.
     pub context: DefId,

     /// The region maps for the given context.
     pub region_scope_tree: &'a region::ScopeTree,

     /// Free-region relationships.
     pub free_regions: &'a FreeRegionMap<'tcx>,
 }

 impl<'a, 'tcx> RegionRelations<'a, 'tcx> {
     pub fn new(
         tcx: TyCtxt<'tcx>,
         context: DefId,
         region_scope_tree: &'a region::ScopeTree,
         free_regions: &'a FreeRegionMap<'tcx>,
     ) -> Self {
         Self {
             tcx,
             context,
             region_scope_tree,
             free_regions,
         }
     }

     /// Determines whether one region is a subregion of another. This is intended to run *after
     /// inference* and sadly the logic is somewhat duplicated with the code in infer.rs.
     pub fn is_subregion_of(&self,
                            sub_region: ty::Region<'tcx>,
                            super_region: ty::Region<'tcx>)
                            -> bool {
         let result = sub_region == super_region || {
             match (sub_region, super_region) {
                 (ty::ReEmpty, _) |
                 (_, ty::ReStatic) =>
                     true,

                 (ty::ReScope(sub_scope), ty::ReScope(super_scope)) =>
                     self.region_scope_tree.is_subscope_of(*sub_scope, *super_scope),

                 (ty::ReScope(sub_scope), ty::ReEarlyBound(ref br)) => {
                     let fr_scope = self.region_scope_tree.early_free_scope(self.tcx, br);
                     self.region_scope_tree.is_subscope_of(*sub_scope, fr_scope)
                 }

                 (ty::ReScope(sub_scope), ty::ReFree(fr)) => {
                     let fr_scope = self.region_scope_tree.free_scope(self.tcx, fr);
                     self.region_scope_tree.is_subscope_of(*sub_scope, fr_scope)
                 }

                 (ty::ReEarlyBound(_), ty::ReEarlyBound(_)) |
                 (ty::ReFree(_), ty::ReEarlyBound(_)) |
                 (ty::ReEarlyBound(_), ty::ReFree(_)) |
                 (ty::ReFree(_), ty::ReFree(_)) =>
                     self.free_regions.sub_free_regions(sub_region, super_region),

                 _ =>
                     false,
             }
         };
         let result = result || self.is_static(super_region);
         debug!("is_subregion_of(sub_region={:?}, super_region={:?}) = {:?}",
                sub_region, super_region, result);
         result
     }

     /// Determines whether this free region is required to be `'static`.
     fn is_static(&self, super_region: ty::Region<'tcx>) -> bool {
         debug!("is_static(super_region={:?})", super_region);
         match *super_region {
             ty::ReStatic => true,
             ty::ReEarlyBound(_) | ty::ReFree(_) => {
                 let re_static = self.tcx.mk_region(ty::ReStatic);
                 self.free_regions.sub_free_regions(&re_static, &super_region)
             }
             _ => false
         }
     }

     pub fn lub_free_regions(&self,
                             r_a: Region<'tcx>,
                             r_b: Region<'tcx>)
                             -> Region<'tcx> {
         self.free_regions.lub_free_regions(self.tcx, r_a, r_b)
     }
 }
	//! This module handles the relationships between "free regions", i.e., lifetime parameters.
	//! Ordinarily, free regions are unrelated to one another, but they can be related via implied
	//! or explicit bounds. In that case, we track the bounds using the `TransitiveRelation` type,
	//! and use that to decide when one free region outlives another, and so forth.

	use crate::infer::outlives::free_region_map::{FreeRegionMap, FreeRegionRelations};
	use crate::hir::def_id::DefId;
	use crate::middle::region;
	use crate::ty::{self, TyCtxt, Region};

	/// Combines a `region::ScopeTree` (which governs relationships between
	/// scopes) and a `FreeRegionMap` (which governs relationships between
	/// free regions) to yield a complete relation between concrete
	/// regions.
	///
	/// This stuff is a bit convoluted and should be refactored, but as we
	/// transition to NLL, it'll all go away anyhow.
	pub struct RegionRelations<'a, 'tcx> {
	pub tcx: TyCtxt<'tcx>,

	/// The context used to fetch the region maps.
	pub context: DefId,

	/// The region maps for the given context.
	pub region_scope_tree: &'a region::ScopeTree,

	/// Free-region relationships.
	pub free_regions: &'a FreeRegionMap<'tcx>,
	}

	impl<'a, 'tcx> RegionRelations<'a, 'tcx> {
	pub fn new(
	tcx: TyCtxt<'tcx>,
	context: DefId,
	region_scope_tree: &'a region::ScopeTree,
	free_regions: &'a FreeRegionMap<'tcx>,
	) -> Self {
	Self {
	tcx,
	context,
	region_scope_tree,
	free_regions,
	}
	}

	/// Determines whether one region is a subregion of another. This is intended to run *after
	/// inference* and sadly the logic is somewhat duplicated with the code in infer.rs.
	pub fn is_subregion_of(&self,
	sub_region: ty::Region<'tcx>,
	super_region: ty::Region<'tcx>)
	-> bool {
	let result = sub_region == super_region \|\| {
	match (sub_region, super_region) {
	(ty::ReEmpty, _) \|
	(_, ty::ReStatic) =>
	true,

	(ty::ReScope(sub_scope), ty::ReScope(super_scope)) =>
	self.region_scope_tree.is_subscope_of(sub_scope, super_scope),

	(ty::ReScope(sub_scope), ty::ReEarlyBound(ref br)) => {
	let fr_scope = self.region_scope_tree.early_free_scope(self.tcx, br);
	self.region_scope_tree.is_subscope_of(*sub_scope, fr_scope)
	}

	(ty::ReScope(sub_scope), ty::ReFree(fr)) => {
	let fr_scope = self.region_scope_tree.free_scope(self.tcx, fr);
	self.region_scope_tree.is_subscope_of(*sub_scope, fr_scope)
	}

	(ty::ReEarlyBound(_), ty::ReEarlyBound(_)) \|
	(ty::ReFree(_), ty::ReEarlyBound(_)) \|
	(ty::ReEarlyBound(_), ty::ReFree(_)) \|
	(ty::ReFree(_), ty::ReFree(_)) =>
	self.free_regions.sub_free_regions(sub_region, super_region),

	_ =>
	false,
	}
	};
	let result = result \|\| self.is_static(super_region);
	debug!("is_subregion_of(sub_region={:?}, super_region={:?}) = {:?}",
	sub_region, super_region, result);
	result
	}

	/// Determines whether this free region is required to be `'static`.
	fn is_static(&self, super_region: ty::Region<'tcx>) -> bool {
	debug!("is_static(super_region={:?})", super_region);
	match *super_region {
	ty::ReStatic => true,
	ty::ReEarlyBound(_) \| ty::ReFree(_) => {
	let re_static = self.tcx.mk_region(ty::ReStatic);
	self.free_regions.sub_free_regions(&re_static, &super_region)
	}
	_ => false
	}
	}

	pub fn lub_free_regions(&self,
	r_a: Region<'tcx>,
	r_b: Region<'tcx>)
	-> Region<'tcx> {
	self.free_regions.lub_free_regions(self.tcx, r_a, r_b)
	}
	}