(* The following module defines functions to check that some invariants * are always maintained by evaluation contexts *) module T = Types module V = Values open Scalars module E = Expressions open Errors module C = Contexts module Subst = Substitute module A = CfimAst module L = Logging open TypesUtils open ValuesUtils open InterpreterUtils let debug_invariants : bool ref = ref false type borrow_info = { loan_kind : T.ref_kind; loan_in_abs : bool; (* true if the loan was found in an abstraction *) loan_ids : V.BorrowId.set_t; borrow_ids : V.BorrowId.set_t; } [@@deriving show] type outer_borrow_info = { outer_borrow : bool; (* true if the value is borrowed *) outer_shared : bool; (* true if the value is borrowed as shared *) } let borrows_infos_to_string (infos : borrow_info V.BorrowId.Map.t) : string = let bindings = V.BorrowId.Map.bindings infos in let bindings = List.map (fun (_, info) -> show_borrow_info info) bindings in String.concat "\n" bindings type borrow_kind = Mut | Shared | Inactivated (** Check that: - loans and borrows are correctly related - a two-phase borrow can't point to a value inside an abstraction *) let check_loans_borrows_relation_invariant (ctx : C.eval_ctx) : unit = (* Link all the borrow ids to a representant - necessary because of shared * borrows/loans *) let ids_reprs : V.BorrowId.id V.BorrowId.Map.t ref = ref V.BorrowId.Map.empty in (* Link all the id representants to a borrow information *) let borrows_infos : borrow_info V.BorrowId.Map.t ref = ref V.BorrowId.Map.empty in (* First, register all the loans *) (* Some utilities to register the loans *) let register_shared_loan (loan_in_abs : bool) (bids : V.BorrowId.set_t) : unit = let reprs = !ids_reprs in let infos = !borrows_infos in (* Use the first borrow id as representant *) let repr_bid = V.BorrowId.Set.min_elt bids in assert (not (V.BorrowId.Map.mem repr_bid infos)); (* Insert the mappings to the representant *) let reprs = V.BorrowId.Set.fold (fun bid reprs -> assert (not (V.BorrowId.Map.mem bid reprs)); V.BorrowId.Map.add bid repr_bid reprs) bids reprs in (* Insert the loan info *) let info = { loan_kind = T.Shared; loan_in_abs; loan_ids = bids; borrow_ids = V.BorrowId.Set.empty; } in let infos = V.BorrowId.Map.add repr_bid info infos in (* Update *) ids_reprs := reprs; borrows_infos := infos in let register_mut_loan (loan_in_abs : bool) (bid : V.BorrowId.id) : unit = let reprs = !ids_reprs in let infos = !borrows_infos in (* Sanity checks *) assert (not (V.BorrowId.Map.mem bid reprs)); assert (not (V.BorrowId.Map.mem bid infos)); (* Add the mapping for the representant *) let reprs = V.BorrowId.Map.add bid bid reprs in (* Add the mapping for the loan info *) let info = { loan_kind = T.Mut; loan_in_abs; loan_ids = V.BorrowId.Set.singleton bid; borrow_ids = V.BorrowId.Set.empty; } in let infos = V.BorrowId.Map.add bid info infos in (* Update *) ids_reprs := reprs; borrows_infos := infos in let loans_visitor = object inherit [_] C.iter_eval_ctx as super method! visit_Var inside_abs binder v = let inside_abs = false in super#visit_Var inside_abs binder v method! visit_Abs inside_abs abs = let inside_abs = true in super#visit_Abs inside_abs abs method! visit_loan_content inside_abs lc = (* Register the loan *) let _ = match lc with | V.SharedLoan (bids, tv) -> register_shared_loan inside_abs bids | V.MutLoan bid -> register_mut_loan inside_abs bid in (* Continue exploring *) super#visit_loan_content inside_abs lc method! visit_aloan_content inside_abs lc = let _ = match lc with | V.AMutLoan (bid, _) -> register_mut_loan inside_abs bid | V.ASharedLoan (bids, _, _) -> register_shared_loan inside_abs bids | V.AEndedMutLoan { given_back = _; child = _ } | V.AEndedSharedLoan (_, _) | V.AIgnoredMutLoan (_, _) (* We might want to do something here *) | V.AEndedIgnoredMutLoan { given_back = _; child = _ } | V.AIgnoredSharedLoan _ -> (* Do nothing *) () in (* Continue exploring *) super#visit_aloan_content inside_abs lc end in (* Visit *) let inside_abs = false in loans_visitor#visit_eval_ctx inside_abs ctx; (* Then, register all the borrows *) (* Some utilities to register the borrows *) let find_info (bid : V.BorrowId.id) : borrow_info = (* Find the representant *) let repr_bid = V.BorrowId.Map.find bid !ids_reprs in (* Lookup the info *) V.BorrowId.Map.find repr_bid !borrows_infos in let update_info (bid : V.BorrowId.id) (info : borrow_info) : unit = (* Find the representant *) let repr_bid = V.BorrowId.Map.find bid !ids_reprs in (* Update the info *) let infos = V.BorrowId.Map.update repr_bid (fun x -> match x with Some _ -> Some info | None -> failwith "Unreachable") !borrows_infos in borrows_infos := infos in let register_borrow (kind : borrow_kind) (bid : V.BorrowId.id) : unit = (* Lookup the info *) let info = find_info bid in (* Check that the borrow kind is consistent *) (match (info.loan_kind, kind) with | T.Shared, (Shared | Inactivated) | T.Mut, Mut -> () | _ -> failwith "Invariant not satisfied"); (* An inactivated borrow can't point to a value inside an abstraction *) assert (kind <> Inactivated || not info.loan_in_abs); (* Insert the borrow id *) let borrow_ids = info.borrow_ids in assert (not (V.BorrowId.Set.mem bid borrow_ids)); let info = { info with borrow_ids = V.BorrowId.Set.add bid borrow_ids } in (* Update the info in the map *) update_info bid info in let borrows_visitor = object inherit [_] C.iter_eval_ctx as super method! visit_abstract_shared_borrows _ asb = let visit asb = match asb with | V.AsbBorrow bid -> register_borrow Shared bid | V.AsbProjReborrows _ -> () in List.iter visit asb method! visit_borrow_content env bc = (* Register the loan *) let _ = match bc with | V.SharedBorrow bid -> register_borrow Shared bid | V.MutBorrow (bid, _) -> register_borrow Mut bid | V.InactivatedMutBorrow bid -> register_borrow Inactivated bid in (* Continue exploring *) super#visit_borrow_content env bc method! visit_aborrow_content env bc = let _ = match bc with | V.AMutBorrow (bid, _) -> register_borrow Mut bid | V.ASharedBorrow bid -> register_borrow Shared bid | V.AIgnoredMutBorrow _ | V.AProjSharedBorrow _ -> (* Do nothing *) () in (* Continue exploring *) super#visit_aborrow_content env bc end in (* Visit *) borrows_visitor#visit_eval_ctx () ctx; (* Debugging *) if !debug_invariants then ( L.log#ldebug (lazy ("\nAbout to check context invariant:\n" ^ eval_ctx_to_string ctx ^ "\n")); L.log#ldebug (lazy ("\Borrows information:\n" ^ borrows_infos_to_string !borrows_infos ^ "\n"))); (* Finally, check that everything is consistant *) V.BorrowId.Map.iter (fun _ info -> (* Note that we can't directly compare the sets - I guess they are * different depending on the order in which we add the elements... *) assert ( V.BorrowId.Set.elements info.loan_ids = V.BorrowId.Set.elements info.borrow_ids); match info.loan_kind with | T.Mut -> assert (V.BorrowId.Set.cardinal info.loan_ids = 1) | T.Shared -> ()) !borrows_infos (** Check that: - borrows/loans can't contain ⊥ or inactivated mut borrows - shared loans can't contain mutable loans *) let check_borrowed_values_invariant (ctx : C.eval_ctx) : unit = () let check_typing_invariant (ctx : C.eval_ctx) : unit = () let check_invariants (ctx : C.eval_ctx) : unit = check_loans_borrows_relation_invariant ctx; check_borrowed_values_invariant ctx; check_typing_invariant ctx