use crate::borrow_check::borrow_set::BorrowSet; use crate::borrow_check::location::{LocationIndex, LocationTable}; use crate::borrow_check::nll::facts::AllFactsExt; use crate::borrow_check::nll::type_check::{MirTypeckResults, MirTypeckRegionConstraints}; use crate::borrow_check::nll::region_infer::values::RegionValueElements; use crate::dataflow::indexes::BorrowIndex; use crate::dataflow::move_paths::MoveData; use crate::dataflow::FlowAtLocation; use crate::dataflow::MaybeInitializedPlaces; use crate::transform::MirSource; use rustc::hir::def_id::DefId; use rustc::infer::InferCtxt; use rustc::mir::{ClosureOutlivesSubject, ClosureRegionRequirements, Mir}; use rustc::ty::{self, RegionKind, RegionVid}; use rustc_errors::Diagnostic; use std::fmt::Debug; use std::env; use std::io; use std::path::PathBuf; use std::rc::Rc; use std::str::FromStr; use self::mir_util::PassWhere; use polonius_engine::{Algorithm, Output}; use crate::util as mir_util; use crate::util::pretty; mod constraint_generation; pub mod explain_borrow; mod facts; mod invalidation; crate mod region_infer; mod renumber; crate mod type_check; mod universal_regions; mod constraints; use self::facts::AllFacts; use self::region_infer::RegionInferenceContext; use self::universal_regions::UniversalRegions; /// Rewrites the regions in the MIR to use NLL variables, also /// scraping out the set of universal regions (e.g., region parameters) /// declared on the function. That set will need to be given to /// `compute_regions`. pub(in crate::borrow_check) fn replace_regions_in_mir<'cx, 'gcx, 'tcx>( infcx: &InferCtxt<'cx, 'gcx, 'tcx>, def_id: DefId, param_env: ty::ParamEnv<'tcx>, mir: &mut Mir<'tcx>, ) -> UniversalRegions<'tcx> { debug!("replace_regions_in_mir(def_id={:?})", def_id); // Compute named region information. This also renumbers the inputs/outputs. let universal_regions = UniversalRegions::new(infcx, def_id, param_env); // Replace all remaining regions with fresh inference variables. renumber::renumber_mir(infcx, mir); let source = MirSource::item(def_id); mir_util::dump_mir(infcx.tcx, None, "renumber", &0, source, mir, |_, _| Ok(())); universal_regions } /// Computes the (non-lexical) regions from the input MIR. /// /// This may result in errors being reported. pub(in crate::borrow_check) fn compute_regions<'cx, 'gcx, 'tcx>( infcx: &InferCtxt<'cx, 'gcx, 'tcx>, def_id: DefId, universal_regions: UniversalRegions<'tcx>, mir: &Mir<'tcx>, location_table: &LocationTable, param_env: ty::ParamEnv<'gcx>, flow_inits: &mut FlowAtLocation<'tcx, MaybeInitializedPlaces<'cx, 'gcx, 'tcx>>, move_data: &MoveData<'tcx>, borrow_set: &BorrowSet<'tcx>, errors_buffer: &mut Vec, ) -> ( RegionInferenceContext<'tcx>, Option>>, Option>, ) { let mut all_facts = if AllFacts::enabled(infcx.tcx) { Some(AllFacts::default()) } else { None }; let universal_regions = Rc::new(universal_regions); let elements = &Rc::new(RegionValueElements::new(mir)); // Run the MIR type-checker. let MirTypeckResults { constraints, universal_region_relations, } = type_check::type_check( infcx, param_env, mir, def_id, &universal_regions, location_table, borrow_set, &mut all_facts, flow_inits, move_data, elements, ); if let Some(all_facts) = &mut all_facts { all_facts .universal_region .extend(universal_regions.universal_regions()); } // Create the region inference context, taking ownership of the // region inference data that was contained in `infcx`, and the // base constraints generated by the type-check. let var_origins = infcx.take_region_var_origins(); let MirTypeckRegionConstraints { placeholder_indices, placeholder_index_to_region: _, mut liveness_constraints, outlives_constraints, closure_bounds_mapping, type_tests, } = constraints; let placeholder_indices = Rc::new(placeholder_indices); constraint_generation::generate_constraints( infcx, &mut liveness_constraints, &mut all_facts, location_table, &mir, borrow_set, ); let mut regioncx = RegionInferenceContext::new( var_origins, universal_regions, placeholder_indices, universal_region_relations, mir, outlives_constraints, closure_bounds_mapping, type_tests, liveness_constraints, elements, ); // Generate various additional constraints. invalidation::generate_invalidates( infcx.tcx, &mut all_facts, location_table, &mir, borrow_set, ); // Dump facts if requested. let polonius_output = all_facts.and_then(|all_facts| { if infcx.tcx.sess.opts.debugging_opts.nll_facts { let def_path = infcx.tcx.hir().def_path(def_id); let dir_path = PathBuf::from("nll-facts").join(def_path.to_filename_friendly_no_crate()); all_facts.write_to_dir(dir_path, location_table).unwrap(); } if infcx.tcx.sess.opts.debugging_opts.polonius { let algorithm = env::var("POLONIUS_ALGORITHM") .unwrap_or_else(|_| String::from("DatafrogOpt")); let algorithm = Algorithm::from_str(&algorithm).unwrap(); debug!("compute_regions: using polonius algorithm {:?}", algorithm); Some(Rc::new(Output::compute( &all_facts, algorithm, false, ))) } else { None } }); // Solve the region constraints. let closure_region_requirements = regioncx.solve(infcx, &mir, def_id, errors_buffer); // Dump MIR results into a file, if that is enabled. This let us // write unit-tests, as well as helping with debugging. dump_mir_results( infcx, MirSource::item(def_id), &mir, ®ioncx, &closure_region_requirements, ); // We also have a `#[rustc_nll]` annotation that causes us to dump // information dump_annotation(infcx, &mir, def_id, ®ioncx, &closure_region_requirements, errors_buffer); (regioncx, polonius_output, closure_region_requirements) } fn dump_mir_results<'a, 'gcx, 'tcx>( infcx: &InferCtxt<'a, 'gcx, 'tcx>, source: MirSource<'tcx>, mir: &Mir<'tcx>, regioncx: &RegionInferenceContext<'_>, closure_region_requirements: &Option>, ) { if !mir_util::dump_enabled(infcx.tcx, "nll", source) { return; } mir_util::dump_mir( infcx.tcx, None, "nll", &0, source, mir, |pass_where, out| { match pass_where { // Before the CFG, dump out the values for each region variable. PassWhere::BeforeCFG => { regioncx.dump_mir(out)?; writeln!(out, "|")?; if let Some(closure_region_requirements) = closure_region_requirements { writeln!(out, "| Free Region Constraints")?; for_each_region_constraint(closure_region_requirements, &mut |msg| { writeln!(out, "| {}", msg) })?; writeln!(out, "|")?; } } PassWhere::BeforeLocation(_) => { } PassWhere::AfterTerminator(_) => { } PassWhere::BeforeBlock(_) | PassWhere::AfterLocation(_) | PassWhere::AfterCFG => {} } Ok(()) }, ); // Also dump the inference graph constraints as a graphviz file. let _: io::Result<()> = try { let mut file = pretty::create_dump_file(infcx.tcx, "regioncx.all.dot", None, "nll", &0, source)?; regioncx.dump_graphviz_raw_constraints(&mut file)?; }; // Also dump the inference graph constraints as a graphviz file. let _: io::Result<()> = try { let mut file = pretty::create_dump_file(infcx.tcx, "regioncx.scc.dot", None, "nll", &0, source)?; regioncx.dump_graphviz_scc_constraints(&mut file)?; }; } fn dump_annotation<'a, 'gcx, 'tcx>( infcx: &InferCtxt<'a, 'gcx, 'tcx>, mir: &Mir<'tcx>, mir_def_id: DefId, regioncx: &RegionInferenceContext<'tcx>, closure_region_requirements: &Option>, errors_buffer: &mut Vec, ) { let tcx = infcx.tcx; let base_def_id = tcx.closure_base_def_id(mir_def_id); if !tcx.has_attr(base_def_id, "rustc_regions") { return; } // When the enclosing function is tagged with `#[rustc_regions]`, // we dump out various bits of state as warnings. This is useful // for verifying that the compiler is behaving as expected. These // warnings focus on the closure region requirements -- for // viewing the intraprocedural state, the -Zdump-mir output is // better. if let Some(closure_region_requirements) = closure_region_requirements { let mut err = tcx .sess .diagnostic() .span_note_diag(mir.span, "External requirements"); regioncx.annotate(tcx, &mut err); err.note(&format!( "number of external vids: {}", closure_region_requirements.num_external_vids )); // Dump the region constraints we are imposing *between* those // newly created variables. for_each_region_constraint(closure_region_requirements, &mut |msg| { err.note(msg); Ok(()) }).unwrap(); err.buffer(errors_buffer); } else { let mut err = tcx .sess .diagnostic() .span_note_diag(mir.span, "No external requirements"); regioncx.annotate(tcx, &mut err); err.buffer(errors_buffer); } } fn for_each_region_constraint( closure_region_requirements: &ClosureRegionRequirements<'_>, with_msg: &mut dyn FnMut(&str) -> io::Result<()>, ) -> io::Result<()> { for req in &closure_region_requirements.outlives_requirements { let subject: &dyn Debug = match &req.subject { ClosureOutlivesSubject::Region(subject) => subject, ClosureOutlivesSubject::Ty(ty) => ty, }; with_msg(&format!( "where {:?}: {:?}", subject, req.outlived_free_region, ))?; } Ok(()) } /// Right now, we piggy back on the `ReVar` to store our NLL inference /// regions. These are indexed with `RegionVid`. This method will /// assert that the region is a `ReVar` and extract its internal index. /// This is reasonable because in our MIR we replace all universal regions /// with inference variables. pub trait ToRegionVid { fn to_region_vid(self) -> RegionVid; } impl<'tcx> ToRegionVid for &'tcx RegionKind { fn to_region_vid(self) -> RegionVid { if let ty::ReVar(vid) = self { *vid } else { bug!("region is not an ReVar: {:?}", self) } } } impl ToRegionVid for RegionVid { fn to_region_vid(self) -> RegionVid { self } } crate trait ConstraintDescription { fn description(&self) -> &'static str; }