open Types open Values open Contexts open Utils open TypesUtils open ValuesUtils open InterpreterUtils open InterpreterBorrows open InterpreterLoopsCore open InterpreterLoopsMatchCtxs open Errors (** The local logger *) let log = Logging.loops_join_ctxs_log (** Utility. An environment augmented with information about its borrows/loans/abstractions for the purpose of merging abstractions together. We provide functions to update this information when merging two abstractions together. We use it in {!reduce_ctx} and {!collapse_ctx}. *) type ctx_with_info = { ctx : eval_ctx; info : abs_borrows_loans_maps } let ctx_with_info_merge_into_first_abs (span : Meta.span) (abs_kind : abs_kind) (can_end : bool) (merge_funs : merge_duplicates_funcs option) (ctx : ctx_with_info) (abs_id0 : AbstractionId.id) (abs_id1 : AbstractionId.id) : ctx_with_info = (* Compute the new context and the new abstraction id *) let nctx, nabs_id = merge_into_first_abstraction span abs_kind can_end merge_funs ctx.ctx abs_id0 abs_id1 in let nabs = ctx_lookup_abs nctx nabs_id in (* Update the information *) let { abs_to_borrows = nabs_to_borrows; abs_to_loans = nabs_to_loans; borrow_to_abs = borrow_to_nabs; loan_to_abs = loan_to_nabs; _; } = compute_abs_borrows_loans_maps span (fun _ -> true) [ EAbs nabs ] in let { abs_ids; abs_to_borrows; abs_to_loans; borrow_to_abs; loan_to_abs } = ctx.info in let abs_ids = List.filter_map (fun id -> if id = abs_id0 then Some nabs_id else if id = abs_id1 then None else Some id) abs_ids in (* Update the maps from makred borrows/loans to abstractions *) let update_to_abs abs_to to_nabs to_abs = (* Remove the old bindings *) let abs0_elems = AbstractionId.Map.find abs_id0 abs_to in let abs1_elems = AbstractionId.Map.find abs_id1 abs_to in let abs01_elems = MarkerBorrowId.Set.union abs0_elems abs1_elems in let to_abs = MarkerBorrowId.Map.filter (fun id _ -> not (MarkerBorrowId.Set.mem id abs01_elems)) to_abs in (* Add the new ones *) let merge _ _ _ = (* We shouldn't have twice the same key *) craise __FILE__ __LINE__ span "Unreachable" in MarkerBorrowId.Map.union merge to_nabs to_abs in let borrow_to_abs = update_to_abs abs_to_borrows borrow_to_nabs borrow_to_abs in let loan_to_abs = update_to_abs abs_to_loans loan_to_nabs loan_to_abs in (* Update the maps from abstractions to marked borrows/loans *) let update_abs_to nabs_to abs_to = AbstractionId.Map.add_strict nabs_id (AbstractionId.Map.find nabs_id nabs_to) (AbstractionId.Map.remove abs_id0 (AbstractionId.Map.remove abs_id1 abs_to)) in let abs_to_borrows = update_abs_to nabs_to_borrows abs_to_borrows in let abs_to_loans = update_abs_to nabs_to_loans abs_to_loans in let info = { abs_ids; abs_to_borrows; abs_to_loans; borrow_to_abs; loan_to_abs } in { ctx = nctx; info } exception AbsToMerge of abstraction_id * abstraction_id (** Repeatedly iterate through the borrows/loans in an environment and merge the abstractions that have to be merged according to a user-provided policy. *) let repeat_iter_borrows_merge (span : Meta.span) (old_ids : ids_sets) (abs_kind : abs_kind) (can_end : bool) (merge_funs : merge_duplicates_funcs option) (iter : ctx_with_info -> ('a -> unit) -> unit) (policy : ctx_with_info -> 'a -> (abstraction_id * abstraction_id) option) (ctx : eval_ctx) : eval_ctx = (* Compute the information *) let ctx = let is_fresh_abs_id (id : AbstractionId.id) : bool = not (AbstractionId.Set.mem id old_ids.aids) in let explore (abs : abs) = is_fresh_abs_id abs.abs_id in let info = compute_abs_borrows_loans_maps span explore ctx.env in { ctx; info } in (* Explore and merge *) let rec explore_merge (ctx : ctx_with_info) : eval_ctx = try iter ctx (fun x -> (* Check if we need to merge some abstractions *) match policy ctx x with | None -> (* No *) () | Some (abs_id0, abs_id1) -> (* Yes: raise an exception *) raise (AbsToMerge (abs_id0, abs_id1))); (* No exception raise: return the current context *) ctx.ctx with AbsToMerge (abs_id0, abs_id1) -> (* Merge and recurse *) let ctx = ctx_with_info_merge_into_first_abs span abs_kind can_end merge_funs ctx abs_id0 abs_id1 in explore_merge ctx in explore_merge ctx (** Reduce an environment. We do this to simplify an environment, for the purpose of finding a loop fixed point. We do the following: - we look for all the *new* dummy values (we use sets of old ids to decide wether a value is new or not) and convert them into abstractions - whenever there is a new abstraction in the context, and some of its its borrows are associated to loans in another new abstraction, we merge them. In effect, this allows us to merge newly introduced abstractions/borrows with their parent abstractions. For instance, looking at the [list_nth_mut] example, when evaluating the first loop iteration, we start in the following environment: {[ abs@0 { ML l0 } ls -> MB l0 (s2 : loops::List) i -> s1 : u32 ]} and get the following environment upon reaching the [Continue] statement: {[ abs@0 { ML l0 } ls -> MB l4 (s@6 : loops::List) i -> s@7 : u32 _@1 -> MB l0 (loops::List::Cons (ML l1, ML l2)) _@2 -> MB l2 (@Box (ML l4)) // tail _@3 -> MB l1 (s@3 : T) // hd ]} In this new environment, the dummy variables [_@1], [_@2] and [_@3] are considered as new. We first convert the new dummy values to abstractions. It gives: {[ abs@0 { ML l0 } ls -> MB l4 (s@6 : loops::List) i -> s@7 : u32 abs@1 { MB l0, ML l1, ML l2 } abs@2 { MB l2, ML l4 } abs@3 { MB l1 } ]} We finally merge the new abstractions together (abs@1 and abs@2 because of l2, and abs@1 and abs@3 because of l1). It gives: {[ abs@0 { ML l0 } ls -> MB l4 (s@6 : loops::List) i -> s@7 : u32 abs@4 { MB l0, ML l4 } ]} - If [merge_funs] is [None], we check that there are no markers in the environments. This is the "reduce" operation. - If [merge_funs] is [Some _], when merging abstractions together, we merge the pairs of borrows and the pairs of loans with the same markers **if this marker is not** [PNone]. This is useful to reuse the reduce operation to implement the collapse. Note that we ignore borrows/loans with the [PNone] marker: the goal of the collapse operation is to *eliminate* markers, not to simplify the environment. For instance, when merging: {[ abs@0 { ML l0, |MB l1| } abs@1 { MB l0, ︙MB l1︙ } ]} We get: {[ abs@2 { MB l1 } ]} *) let reduce_ctx_with_markers (merge_funs : merge_duplicates_funcs option) (span : Meta.span) (loop_id : LoopId.id) (old_ids : ids_sets) (ctx0 : eval_ctx) : eval_ctx = (* Debug *) log#ldebug (lazy ("reduce_ctx:\n\n- fixed_ids:\n" ^ show_ids_sets old_ids ^ "\n\n- ctx0:\n" ^ eval_ctx_to_string ~span:(Some span) ctx0 ^ "\n\n")); let with_markers = merge_funs <> None in let abs_kind : abs_kind = Loop (loop_id, None, LoopSynthInput) in let can_end = true in let destructure_shared_values = true in let is_fresh_did (id : DummyVarId.id) : bool = not (DummyVarId.Set.mem id old_ids.dids) in (* Convert the dummy values to abstractions (note that when we convert values to abstractions, the resulting abstraction should be destructured) *) (* Note that we preserve the order of the dummy values: we replace them with abstractions in place - this makes matching easier *) let env = List.concat (List.map (fun ee -> match ee with | EAbs _ | EFrame | EBinding (BVar _, _) -> [ ee ] | EBinding (BDummy id, v) -> if is_fresh_did id then let absl = convert_value_to_abstractions span abs_kind can_end destructure_shared_values ctx0 v in List.map (fun abs -> EAbs abs) absl else [ ee ]) ctx0.env) in let ctx = { ctx0 with env } in log#ldebug (lazy ("reduce_ctx: after converting values to abstractions:\n" ^ show_ids_sets old_ids ^ "\n\n- ctx:\n" ^ eval_ctx_to_string ~span:(Some span) ctx ^ "\n\n")); log#ldebug (lazy ("reduce_ctx: after decomposing the shared values in the abstractions:\n" ^ show_ids_sets old_ids ^ "\n\n- ctx:\n" ^ eval_ctx_to_string ~span:(Some span) ctx ^ "\n\n")); (* Merge all the mergeable abs. We iterate over the *new* abstractions, then over the loans in the abstractions. We do this because we want to control the order in which abstractions are merged (the ids are iterated in increasing order). Otherwise, we could simply iterate over all the borrows in [loan_to_abs]... *) let ctx = repeat_iter_borrows_merge span old_ids abs_kind can_end merge_funs (fun ctx f -> List.iter (fun abs_id0 -> let lids = AbstractionId.Map.find abs_id0 ctx.info.abs_to_loans in MarkerBorrowId.Set.iter (fun lid -> f (abs_id0, lid)) lids) ctx.info.abs_ids) (fun ctx (abs_id0, lid) -> if not with_markers then sanity_check __FILE__ __LINE__ (fst lid = PNone) span; (* If we use markers: we are doing a collapse, which means we attempt to eliminate markers (and this is the only goal of the operation). We thus ignore the non-marked values (we merge non-marked values when doing a "real" reduce, to simplify the environment in order to converge to a fixed-point, for instance). *) if with_markers && fst lid = PNone then None else (* Find the borrow corresponding to the loan we want to eliminate *) match MarkerBorrowId.Map.find_opt lid ctx.info.borrow_to_abs with | None -> (* Nothing to to *) None | Some abs_ids1 -> ( (* We need to merge *) match AbstractionId.Set.elements abs_ids1 with | [] -> None | abs_id1 :: _ -> log#ldebug (lazy ("reduce_ctx: merging abstraction " ^ AbstractionId.to_string abs_id1 ^ " into " ^ AbstractionId.to_string abs_id0 ^ ":\n\n" ^ eval_ctx_to_string ~span:(Some span) ctx.ctx)); Some (abs_id0, abs_id1))) ctx in log#ldebug (lazy ("reduce_ctx:\n\n- fixed_ids:\n" ^ show_ids_sets old_ids ^ "\n\n- after reduce:\n" ^ eval_ctx_to_string ~span:(Some span) ctx ^ "\n\n")); (* Reorder the loans and borrows in the fresh abstractions - note that we may not have eliminated all the markers at this point. *) let ctx = reorder_loans_borrows_in_fresh_abs span true old_ids.aids ctx in log#ldebug (lazy ("reduce_ctx:\n\n- fixed_ids:\n" ^ show_ids_sets old_ids ^ "\n\n- after reduce and reorder borrows/loans:\n" ^ eval_ctx_to_string ~span:(Some span) ctx ^ "\n\n")); (* Return the new context *) ctx (** Reduce_ctx can only be called in a context with no markers *) let reduce_ctx = reduce_ctx_with_markers None (** Auxiliary function for collapse (see below). We traverse all abstractions, and merge abstractions when they contain the same element, but with dual markers (i.e., [PLeft] and [PRight]). For instance, if we have the abstractions {[ abs@0 { | MB l0 _ |, ML l1 } abs@1 { ︙MB l0 _ ︙, ML l2 } ]} We merge abs@0 and abs@1 into a new abstraction abs@2. This allows us to eliminate the markers used for [MB l0]: {[ abs@2 { MB l0 _, ML l1, ML l2 } ]} *) let collapse_ctx_collapse (span : Meta.span) (loop_id : LoopId.id) (merge_funs : merge_duplicates_funcs) (old_ids : ids_sets) (ctx : eval_ctx) : eval_ctx = (* Debug *) log#ldebug (lazy ("collapse_ctx:\n\n- fixed_ids:\n" ^ show_ids_sets old_ids ^ "\n\n- initial ctx:\n" ^ eval_ctx_to_string ~span:(Some span) ctx ^ "\n\n")); let abs_kind : abs_kind = Loop (loop_id, None, LoopSynthInput) in let can_end = true in let invert_proj_marker = function | PNone -> craise __FILE__ __LINE__ span "Unreachable" | PLeft -> PRight | PRight -> PLeft in (* Merge all the mergeable abs where the same element in present in both abs, but with left and right markers respectively. *) (* The iter function: iterate over the abstractions, and inside an abstraction over the borrows then the loans *) let iter ctx f = List.iter (fun abs_id0 -> (* Small helper *) let iterate is_borrow = let m = if is_borrow then ctx.info.abs_to_borrows else ctx.info.abs_to_loans in let ids = AbstractionId.Map.find abs_id0 m in MarkerBorrowId.Set.iter (fun id -> f (abs_id0, is_borrow, id)) ids in (* Iterate over the borrows *) iterate true; (* Iterate over the loans *) iterate false) ctx.info.abs_ids in (* Check if there is an abstraction with the same borrow/loan id and the dual marker, and merge them if it is the case. *) let merge_policy ctx (abs_id0, is_borrow, (pm, bid)) = if pm = PNone then None else (* Look for an element with the dual marker *) match MarkerBorrowId.Map.find_opt (invert_proj_marker pm, bid) (if is_borrow then ctx.info.borrow_to_abs else ctx.info.loan_to_abs) with | None -> (* Nothing to do *) None | Some abs_ids1 -> ( (* We need to merge *) match AbstractionId.Set.elements abs_ids1 with | [] -> None | abs_id1 :: _ -> Some (abs_id0, abs_id1)) in (* Iterate and merge *) let ctx = repeat_iter_borrows_merge span old_ids abs_kind can_end (Some merge_funs) iter merge_policy ctx in log#ldebug (lazy ("collapse_ctx:\n\n- fixed_ids:\n" ^ show_ids_sets old_ids ^ "\n\n- after collapse:\n" ^ eval_ctx_to_string ~span:(Some span) ctx ^ "\n\n")); (* Reorder the loans and borrows in the fresh abstractions - note that we may not have eliminated all the markers yet *) let ctx = reorder_loans_borrows_in_fresh_abs span true old_ids.aids ctx in log#ldebug (lazy ("collapse_ctx:\n\n- fixed_ids:\n" ^ show_ids_sets old_ids ^ "\n\n- after collapse and reorder borrows/loans:\n" ^ eval_ctx_to_string ~span:(Some span) ctx ^ "\n\n")); (* Return the new context *) ctx (** Small utility: check whether an environment contains markers *) let eval_ctx_has_markers (ctx : eval_ctx) : bool = let visitor = object inherit [_] iter_eval_ctx method! visit_proj_marker _ pm = match pm with PNone -> () | PLeft | PRight -> raise Found end in try visitor#visit_eval_ctx () ctx; false with Found -> true (** Collapse two environments containing projection markers; this function is called after joining environments. The collapse is done in two steps. First, we reduce the environment, merging any two pair of fresh abstractions which contain a loan (in one) and its corresponding borrow (in the other). For instance, we merge abs@0 and abs@1 below: {[ abs@0 { |ML l0|, ML l1 } abs@1 { |MB l0 _|, ML l2 } ~~> abs@2 { ML l1, ML l2 } ]} Note that we also merge abstractions when the loan/borrow don't have the same markers. For instance, below: {[ abs@0 { ML l0, ML l1 } // ML l0 doesn't have markers abs@1 { |MB l0 _|, ML l2 } ~~> abs@2 { ︙ML l0︙, ML l1, ML l2 } ]} Second, we merge abstractions containing the same element with left and right markers respectively. For instance: {[ abs@0 { | MB l0 _ |, ML l1 } abs@1 { ︙MB l0 _ ︙, ML l2 } ~~> abs@2 { MB l0 _, ML l1, ML l2 } ]} At the end of the second step, all markers should have been removed from the resulting environment. *) let collapse_ctx (span : Meta.span) (loop_id : LoopId.id) (merge_funs : merge_duplicates_funcs) (old_ids : ids_sets) (ctx0 : eval_ctx) : eval_ctx = let ctx = reduce_ctx_with_markers (Some merge_funs) span loop_id old_ids ctx0 in let ctx = collapse_ctx_collapse span loop_id merge_funs old_ids ctx in (* Sanity check: there are no markers remaining *) sanity_check __FILE__ __LINE__ (not (eval_ctx_has_markers ctx)) span; ctx let mk_collapse_ctx_merge_duplicate_funs (span : Meta.span) (loop_id : LoopId.id) (ctx : eval_ctx) : merge_duplicates_funcs = (* Rem.: the merge functions raise exceptions (that we catch). *) let module S : MatchJoinState = struct let span = span let loop_id = loop_id let nabs = ref [] end in let module JM = MakeJoinMatcher (S) in let module M = MakeMatcher (JM) in (* Functions to match avalues (see {!merge_duplicates_funcs}). Those functions are used to merge borrows/loans with the *same ids*. They will always be called on destructured avalues (whose children are [AIgnored] - we enforce that through sanity checks). We rely on the join matcher [JM] to match the concrete values (for shared loans for instance). Note that the join matcher doesn't implement match functions for avalues (see the comments in {!MakeJoinMatcher}. *) let merge_amut_borrows id ty0 _pm0 child0 _ty1 _pm1 child1 = (* Sanity checks *) sanity_check __FILE__ __LINE__ (is_aignored child0.value) span; sanity_check __FILE__ __LINE__ (is_aignored child1.value) span; (* We need to pick a type for the avalue. The types on the left and on the right may use different regions: it doesn't really matter (here, we pick the one from the left), because we will merge those regions together anyway (see the comments for {!merge_into_first_abstraction}). *) let ty = ty0 in let child = child0 in let value = ABorrow (AMutBorrow (PNone, id, child)) in { value; ty } in let merge_ashared_borrows id ty0 _pm0 ty1 _pm1 = (* Sanity checks *) let _ = let _, ty0, _ = ty_as_ref ty0 in let _, ty1, _ = ty_as_ref ty1 in sanity_check __FILE__ __LINE__ (not (ty_has_borrows ctx.type_ctx.type_infos ty0)) span; sanity_check __FILE__ __LINE__ (not (ty_has_borrows ctx.type_ctx.type_infos ty1)) span in (* Same remarks as for [merge_amut_borrows] *) let ty = ty0 in let value = ABorrow (ASharedBorrow (PNone, id)) in { value; ty } in let merge_amut_loans id ty0 _pm0 child0 _ty1 _pm1 child1 = (* Sanity checks *) sanity_check __FILE__ __LINE__ (is_aignored child0.value) span; sanity_check __FILE__ __LINE__ (is_aignored child1.value) span; (* Same remarks as for [merge_amut_borrows] *) let ty = ty0 in let child = child0 in let value = ALoan (AMutLoan (PNone, id, child)) in { value; ty } in let merge_ashared_loans ids ty0 _pm0 (sv0 : typed_value) child0 _ty1 _pm1 (sv1 : typed_value) child1 = (* Sanity checks *) sanity_check __FILE__ __LINE__ (is_aignored child0.value) span; sanity_check __FILE__ __LINE__ (is_aignored child1.value) span; (* Same remarks as for [merge_amut_borrows]. This time we need to also merge the shared values. We rely on the join matcher [JM] to do so. *) sanity_check __FILE__ __LINE__ (not (value_has_loans_or_borrows ctx sv0.value)) span; sanity_check __FILE__ __LINE__ (not (value_has_loans_or_borrows ctx sv1.value)) span; let ty = ty0 in let child = child0 in let sv = M.match_typed_values ctx ctx sv0 sv1 in let value = ALoan (ASharedLoan (PNone, ids, sv, child)) in { value; ty } in { merge_amut_borrows; merge_ashared_borrows; merge_amut_loans; merge_ashared_loans; } let merge_into_first_abstraction (span : Meta.span) (loop_id : LoopId.id) (abs_kind : abs_kind) (can_end : bool) (ctx : eval_ctx) (aid0 : AbstractionId.id) (aid1 : AbstractionId.id) : eval_ctx * AbstractionId.id = let merge_funs = mk_collapse_ctx_merge_duplicate_funs span loop_id ctx in merge_into_first_abstraction span abs_kind can_end (Some merge_funs) ctx aid0 aid1 (** Collapse an environment, merging the duplicated borrows/loans. This function simply calls {!collapse_ctx} with the proper merging functions. We do this because when we join environments, we may introduce duplicated loans and borrows. See the explanations for {!join_ctxs}. *) let collapse_ctx_with_merge (span : Meta.span) (loop_id : LoopId.id) (old_ids : ids_sets) (ctx : eval_ctx) : eval_ctx = let merge_funs = mk_collapse_ctx_merge_duplicate_funs span loop_id ctx in try collapse_ctx span loop_id merge_funs old_ids ctx with ValueMatchFailure _ -> craise __FILE__ __LINE__ span "Unexpected" let join_ctxs (span : Meta.span) (loop_id : LoopId.id) (fixed_ids : ids_sets) (ctx0 : eval_ctx) (ctx1 : eval_ctx) : ctx_or_update = (* Debug *) log#ldebug (lazy ("join_ctxs:\n\n- fixed_ids:\n" ^ show_ids_sets fixed_ids ^ "\n\n- ctx0:\n" ^ eval_ctx_to_string_no_filter ~span:(Some span) ctx0 ^ "\n\n- ctx1:\n" ^ eval_ctx_to_string_no_filter ~span:(Some span) ctx1 ^ "\n\n")); let env0 = List.rev ctx0.env in let env1 = List.rev ctx1.env in let nabs = ref [] in (* Explore the environments. *) let join_suffixes (env0 : env) (env1 : env) : env = (* Debug *) log#ldebug (lazy ("join_suffixes:\n\n- fixed_ids:\n" ^ show_ids_sets fixed_ids ^ "\n\n- ctx0:\n" ^ eval_ctx_to_string_no_filter ~span:(Some span) { ctx0 with env = List.rev env0 } ^ "\n\n- ctx1:\n" ^ eval_ctx_to_string_no_filter ~span:(Some span) { ctx1 with env = List.rev env1 } ^ "\n\n")); (* Sanity check: there are no values/abstractions which should be in the prefix *) let check_valid (ee : env_elem) : unit = match ee with | EBinding (BVar _, _) -> (* Variables are necessarily in the prefix *) craise __FILE__ __LINE__ span "Unreachable" | EBinding (BDummy did, _) -> sanity_check __FILE__ __LINE__ (not (DummyVarId.Set.mem did fixed_ids.dids)) span | EAbs abs -> sanity_check __FILE__ __LINE__ (not (AbstractionId.Set.mem abs.abs_id fixed_ids.aids)) span | EFrame -> (* This should have been eliminated *) craise __FILE__ __LINE__ span "Unreachable" in (* Add projection marker to all abstractions in the left and right environments *) let add_marker (pm : proj_marker) (ee : env_elem) : env_elem = match ee with | EAbs abs -> EAbs (abs_add_marker span ctx0 pm abs) | x -> x in let env0 = List.map (add_marker PLeft) env0 in let env1 = List.map (add_marker PRight) env1 in List.iter check_valid env0; List.iter check_valid env1; (* Concatenate the suffixes and append the abstractions introduced while joining the prefixes *) let absl = List.map (fun abs -> EAbs abs) (List.rev !nabs) in List.concat [ env0; env1; absl ] in let module S : MatchJoinState = struct let span = span let loop_id = loop_id let nabs = nabs end in let module JM = MakeJoinMatcher (S) in let module M = MakeMatcher (JM) in (* Rem.: this function raises exceptions *) let rec join_prefixes (env0 : env) (env1 : env) : env = match (env0, env1) with | ( (EBinding (BDummy b0, v0) as var0) :: env0', (EBinding (BDummy b1, v1) as var1) :: env1' ) -> (* Debug *) log#ldebug (lazy ("join_prefixes: BDummys:\n\n- fixed_ids:\n" ^ "\n" ^ show_ids_sets fixed_ids ^ "\n\n- value0:\n" ^ env_elem_to_string span ctx0 var0 ^ "\n\n- value1:\n" ^ env_elem_to_string span ctx1 var1 ^ "\n\n")); (* Two cases: the dummy value is an old value, in which case the bindings must be the same and we must join their values. Otherwise, it means we are not in the prefix anymore *) if DummyVarId.Set.mem b0 fixed_ids.dids then ( (* Still in the prefix: match the values *) sanity_check __FILE__ __LINE__ (b0 = b1) span; let b = b0 in let v = M.match_typed_values ctx0 ctx1 v0 v1 in let var = EBinding (BDummy b, v) in (* Continue *) var :: join_prefixes env0' env1') else (* Not in the prefix anymore *) join_suffixes env0 env1 | ( (EBinding (BVar b0, v0) as var0) :: env0', (EBinding (BVar b1, v1) as var1) :: env1' ) -> (* Debug *) log#ldebug (lazy ("join_prefixes: BVars:\n\n- fixed_ids:\n" ^ "\n" ^ show_ids_sets fixed_ids ^ "\n\n- value0:\n" ^ env_elem_to_string span ctx0 var0 ^ "\n\n- value1:\n" ^ env_elem_to_string span ctx1 var1 ^ "\n\n")); (* Variable bindings *must* be in the prefix and consequently their ids must be the same *) sanity_check __FILE__ __LINE__ (b0 = b1) span; (* Match the values *) let b = b0 in let v = M.match_typed_values ctx0 ctx1 v0 v1 in let var = EBinding (BVar b, v) in (* Continue *) var :: join_prefixes env0' env1' | (EAbs abs0 as abs) :: env0', EAbs abs1 :: env1' -> (* Debug *) log#ldebug (lazy ("join_prefixes: Abs:\n\n- fixed_ids:\n" ^ "\n" ^ show_ids_sets fixed_ids ^ "\n\n- abs0:\n" ^ abs_to_string span ctx0 abs0 ^ "\n\n- abs1:\n" ^ abs_to_string span ctx1 abs1 ^ "\n\n")); (* Same as for the dummy values: there are two cases *) if AbstractionId.Set.mem abs0.abs_id fixed_ids.aids then ( (* Still in the prefix: the abstractions must be the same *) sanity_check __FILE__ __LINE__ (abs0 = abs1) span; (* Continue *) abs :: join_prefixes env0' env1') else (* Not in the prefix anymore *) join_suffixes env0 env1 | _ -> (* The elements don't match: we are not in the prefix anymore *) join_suffixes env0 env1 in try (* Remove the frame delimiter (the first element of an environment is a frame delimiter) *) let env0, env1 = match (env0, env1) with | EFrame :: env0, EFrame :: env1 -> (env0, env1) | _ -> craise __FILE__ __LINE__ span "Unreachable" in log#ldebug (lazy ("- env0:\n" ^ show_env env0 ^ "\n\n- env1:\n" ^ show_env env1 ^ "\n\n")); let env = List.rev (EFrame :: join_prefixes env0 env1) in (* Construct the joined context - of course, the type, fun, etc. contexts * should be the same in the two contexts *) let { type_ctx; fun_ctx; global_ctx; trait_decls_ctx; trait_impls_ctx; region_groups; type_vars; const_generic_vars; const_generic_vars_map; norm_trait_types; env = _; ended_regions = ended_regions0; } = ctx0 in let { type_ctx = _; fun_ctx = _; global_ctx = _; trait_decls_ctx = _; trait_impls_ctx = _; region_groups = _; type_vars = _; const_generic_vars = _; const_generic_vars_map = _; norm_trait_types = _; env = _; ended_regions = ended_regions1; } = ctx1 in let ended_regions = RegionId.Set.union ended_regions0 ended_regions1 in Ok { type_ctx; fun_ctx; global_ctx; trait_decls_ctx; trait_impls_ctx; region_groups; type_vars; const_generic_vars; const_generic_vars_map; norm_trait_types; env; ended_regions; } with ValueMatchFailure e -> Error e (** Destructure all the new abstractions *) let destructure_new_abs (span : Meta.span) (loop_id : LoopId.id) (old_abs_ids : AbstractionId.Set.t) (ctx : eval_ctx) : eval_ctx = let abs_kind : abs_kind = Loop (loop_id, None, LoopSynthInput) in let can_end = true in let destructure_shared_values = true in let is_fresh_abs_id (id : AbstractionId.id) : bool = not (AbstractionId.Set.mem id old_abs_ids) in let env = env_map_abs (fun abs -> if is_fresh_abs_id abs.abs_id then let abs = destructure_abs span abs_kind can_end destructure_shared_values ctx abs in abs else abs) ctx.env in { ctx with env } (** Refresh the ids of the fresh abstractions. We do this because {!prepare_ashared_loans} introduces some non-fixed abstractions in contexts which are later joined: we have to make sure two contexts we join don't have non-fixed abstractions with the same ids. *) let refresh_abs (old_abs : AbstractionId.Set.t) (ctx : eval_ctx) : eval_ctx = let ids, _ = compute_ctx_ids ctx in let abs_to_refresh = AbstractionId.Set.diff ids.aids old_abs in let aids_subst = List.map (fun id -> (id, fresh_abstraction_id ())) (AbstractionId.Set.elements abs_to_refresh) in let aids_subst = AbstractionId.Map.of_list aids_subst in let subst id = match AbstractionId.Map.find_opt id aids_subst with | None -> id | Some id -> id in let env = Substitute.env_subst_ids (fun x -> x) (fun x -> x) (fun x -> x) (fun x -> x) (fun x -> x) subst ctx.env in { ctx with env } let loop_join_origin_with_continue_ctxs (config : config) (span : Meta.span) (loop_id : LoopId.id) (fixed_ids : ids_sets) (old_ctx : eval_ctx) (ctxl : eval_ctx list) : (eval_ctx * eval_ctx list) * eval_ctx = (* # Join with the new contexts, one by one For every context, we repeteadly attempt to join it with the current result of the join: if we fail (because we need to end loans for instance), we update the context and retry. Rem.: we should never have to end loans in the aggregated context, only in the one we are trying to add to the join. *) let joined_ctx = ref old_ctx in let rec join_one_aux (ctx : eval_ctx) : eval_ctx = match join_ctxs span loop_id fixed_ids !joined_ctx ctx with | Ok nctx -> joined_ctx := nctx; ctx | Error err -> let ctx = match err with | LoanInRight bid -> InterpreterBorrows.end_borrow_no_synth config span bid ctx | LoansInRight bids -> InterpreterBorrows.end_borrows_no_synth config span bids ctx | AbsInRight _ | AbsInLeft _ | LoanInLeft _ | LoansInLeft _ -> craise __FILE__ __LINE__ span "Unexpected" in join_one_aux ctx in let join_one (ctx : eval_ctx) : eval_ctx = log#ldebug (lazy ("loop_join_origin_with_continue_ctxs:join_one: initial ctx:\n" ^ eval_ctx_to_string ~span:(Some span) ctx)); (* Destructure the abstractions introduced in the new context *) let ctx = destructure_new_abs span loop_id fixed_ids.aids ctx in log#ldebug (lazy ("loop_join_origin_with_continue_ctxs:join_one: after destructure:\n" ^ eval_ctx_to_string ~span:(Some span) ctx)); (* Reduce the context we want to add to the join *) let ctx = reduce_ctx span loop_id fixed_ids ctx in log#ldebug (lazy ("loop_join_origin_with_continue_ctxs:join_one: after reduce:\n" ^ eval_ctx_to_string ~span:(Some span) ctx)); (* Refresh the fresh abstractions *) let ctx = refresh_abs fixed_ids.aids ctx in (* Join the two contexts *) let ctx1 = join_one_aux ctx in log#ldebug (lazy ("loop_join_origin_with_continue_ctxs:join_one: after join:\n" ^ eval_ctx_to_string ~span:(Some span) ctx1)); (* Collapse to eliminate the markers *) joined_ctx := collapse_ctx_with_merge span loop_id fixed_ids !joined_ctx; log#ldebug (lazy ("loop_join_origin_with_continue_ctxs:join_one: after join-collapse:\n" ^ eval_ctx_to_string ~span:(Some span) !joined_ctx)); (* Reduce again to reach a fixed point *) joined_ctx := reduce_ctx span loop_id fixed_ids !joined_ctx; log#ldebug (lazy ("loop_join_origin_with_continue_ctxs:join_one: after last reduce:\n" ^ eval_ctx_to_string ~span:(Some span) !joined_ctx)); (* Sanity check *) if !Config.sanity_checks then Invariants.check_invariants span !joined_ctx; (* Return *) ctx1 in let ctxl = List.map join_one ctxl in (* # Return *) ((old_ctx, ctxl), !joined_ctx)