//! This file handles the relationships between free regions -- //! meaning 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 infer::outlives::free_region_map::{FreeRegionMap, FreeRegionRelations}; use hir::def_id::DefId; use middle::region; use 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 /// move to NLL it'll all go away anyhow. pub struct RegionRelations<'a, 'gcx: 'tcx, 'tcx: 'a> { pub tcx: TyCtxt<'a, 'gcx, 'tcx>, /// context used to fetch the region maps pub context: DefId, /// region maps for the given context pub region_scope_tree: &'a region::ScopeTree, /// free-region relationships pub free_regions: &'a FreeRegionMap<'tcx>, } impl<'a, 'gcx, 'tcx> RegionRelations<'a, 'gcx, 'tcx> { pub fn new( tcx: TyCtxt<'a, 'gcx, '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) } }