summaryrefslogtreecommitdiff
diff options
context:
space:
mode:
authorSon Ho2022-01-06 10:21:39 +0100
committerSon Ho2022-01-06 10:21:39 +0100
commitc794ffc73738393850fc257a7916d0fd2c87d87f (patch)
treedeb8a66bbd508ca12f24363392e775475b69f356
parent6179fed42a11365c753aee55470bb69dc780e1ba (diff)
Move some functions from Interpreter to InterpreterProjectors
-rw-r--r--src/Interpreter.ml637
-rw-r--r--src/InterpreterProjectors.ml505
-rw-r--r--src/InterpreterUtils.ml160
3 files changed, 667 insertions, 635 deletions
diff --git a/src/Interpreter.ml b/src/Interpreter.ml
index a3f22660..afe513be 100644
--- a/src/Interpreter.ml
+++ b/src/Interpreter.ml
@@ -10,9 +10,10 @@ module L = Logging
open TypesUtils
open ValuesUtils
module Inv = Invariants
-open InterpreterUtils
module S = Synthesis
open Utils
+open InterpreterUtils
+open InterpreterProjectors
(* TODO: check that the value types are correct when evaluating *)
(* TODO: for debugging purposes, we might want to put use eval_ctx everywhere
@@ -34,450 +35,6 @@ type eval_error = Panic
type 'a eval_result = ('a, eval_error) result
-(** The following type identifies the relative position of expressions (in
- particular borrows) in other expressions.
-
- For instance, it is used to control [end_borrow]: we usually only allow
- to end "outer" borrows, unless we perform a drop.
-*)
-type inner_outer = Inner | Outer
-
-type borrow_ids = Borrows of V.BorrowId.Set.t | Borrow of V.BorrowId.id
-
-exception FoundBorrowIds of borrow_ids
-
-let update_if_none opt x = match opt with None -> Some x | _ -> opt
-
-(** Auxiliary function: see its usage in [end_borrow_get_borrow_in_value] *)
-let update_outer_borrows (io : inner_outer)
- (outer : V.AbstractionId.id option * borrow_ids option) (x : borrow_ids) :
- V.AbstractionId.id option * borrow_ids option =
- match io with
- | Inner ->
- (* If we can end inner borrows, we don't keep track of the outer borrows *)
- outer
- | Outer ->
- let abs, opt = outer in
- (abs, update_if_none opt x)
-
-(** Return the first loan we find in a value *)
-let get_first_loan_in_value (v : V.typed_value) : V.loan_content option =
- let obj =
- object
- inherit [_] V.iter_typed_value
-
- method! visit_loan_content _ lc = raise (FoundLoanContent lc)
- end
- in
- (* We use exceptions *)
- try
- obj#visit_typed_value () v;
- None
- with FoundLoanContent lc -> Some lc
-
-(** Check if two different projections intersect. This is necessary when
- giving a symbolic value to an abstraction: we need to check that
- the regions which are already ended inside the abstraction don't
- intersect the regions over which we project in the new abstraction.
- Note that the two abstractions have different views (in terms of regions)
- of the symbolic value (hence the two region types).
-*)
-let rec projections_intersect (ty1 : T.rty) (rset1 : T.RegionId.set_t)
- (ty2 : T.rty) (rset2 : T.RegionId.set_t) : bool =
- match (ty1, ty2) with
- | T.Bool, T.Bool | T.Char, T.Char | T.Str, T.Str -> false
- | T.Integer int_ty1, T.Integer int_ty2 ->
- assert (int_ty1 = int_ty2);
- false
- | T.Adt (id1, regions1, tys1), T.Adt (id2, regions2, tys2) ->
- assert (id1 = id2);
- (* The intersection check for the ADTs is very crude:
- * we check if some arguments intersect. As all the type and region
- * parameters should be used somewhere in the ADT (otherwise rustc
- * generates an error), it means that it should be equivalent to checking
- * whether two fields intersect (and anyway comparing the field types is
- * difficult in case of enumerations...).
- * If we didn't have the above property enforced by the rust compiler,
- * this check would still be a reasonable conservative approximation. *)
- let regions = List.combine regions1 regions2 in
- let tys = List.combine tys1 tys2 in
- List.exists
- (fun (r1, r2) -> region_in_set r1 rset1 && region_in_set r2 rset2)
- regions
- || List.exists
- (fun (ty1, ty2) -> projections_intersect ty1 rset1 ty2 rset2)
- tys
- | T.Array ty1, T.Array ty2 | T.Slice ty1, T.Slice ty2 ->
- projections_intersect ty1 rset1 ty2 rset2
- | T.Ref (r1, ty1, kind1), T.Ref (r2, ty2, kind2) ->
- (* Sanity check *)
- assert (kind1 = kind2);
- (* The projections intersect if the borrows intersect or their contents
- * intersect *)
- (region_in_set r1 rset1 && region_in_set r2 rset2)
- || projections_intersect ty1 rset1 ty2 rset2
- | _ -> failwith "Unreachable"
-
-(** Check if the ended regions of a comp projector over a symbolic value
- intersect the regions listed in another projection *)
-let symbolic_proj_comp_ended_regions_intersect_proj (s : V.symbolic_proj_comp)
- (ty : T.rty) (regions : T.RegionId.set_t) : bool =
- projections_intersect s.V.svalue.V.sv_ty s.V.rset_ended ty regions
-
-(** Check that a symbolic value doesn't contain ended regions.
-
- Note that we don't check that the set of ended regions is empty: we
- check that the set of ended regions doesn't intersect the set of
- regions used in the type (this is more general).
-*)
-let symbolic_proj_comp_ended_regions (s : V.symbolic_proj_comp) : bool =
- let regions = rty_regions s.V.svalue.V.sv_ty in
- not (T.RegionId.Set.disjoint regions s.rset_ended)
-
-(** Check if a [value] contains ⊥.
-
- Note that this function is very general: it also checks wether
- symbolic values contain already ended regions.
- *)
-let bottom_in_value (v : V.typed_value) : bool =
- let obj =
- object
- inherit [_] V.iter_typed_value
-
- method! visit_Bottom _ = raise Found
-
- method! visit_symbolic_proj_comp _ s =
- if symbolic_proj_comp_ended_regions s then raise Found else ()
- end
- in
- (* We use exceptions *)
- try
- obj#visit_typed_value () v;
- false
- with Found -> true
-
-(** Check if an [avalue] contains ⊥.
-
- Note that this function is very general: it also checks wether
- symbolic values contain already ended regions.
-
- TODO: remove?
-*)
-let bottom_in_avalue (v : V.typed_avalue) (_abs_regions : T.RegionId.set_t) :
- bool =
- let obj =
- object
- inherit [_] V.iter_typed_avalue
-
- method! visit_Bottom _ = raise Found
-
- method! visit_symbolic_proj_comp _ sv =
- if symbolic_proj_comp_ended_regions sv then raise Found else ()
-
- method! visit_aproj _ ap =
- (* Nothing to do actually *)
- match ap with
- | V.AProjLoans _sv -> ()
- | V.AProjBorrows (_sv, _rty) -> ()
- end
- in
- (* We use exceptions *)
- try
- obj#visit_typed_avalue () v;
- false
- with Found -> true
-
-type outer_borrows_or_abs =
- | OuterBorrows of borrow_ids
- | OuterAbs of V.AbstractionId.id
-
-exception FoundOuter of outer_borrows_or_abs
-(** Utility exception *)
-
-(** Auxiliary function.
-
- Apply a proj_borrows on a shared borrow.
- In the case of shared borrows, we return [abstract_shared_borrows],
- not avalues.
-*)
-let rec apply_proj_borrows_on_shared_borrow (ctx : C.eval_ctx)
- (fresh_reborrow : V.BorrowId.id -> V.BorrowId.id)
- (regions : T.RegionId.set_t) (v : V.typed_value) (ty : T.rty) :
- V.abstract_shared_borrows =
- (* Sanity check - TODO: move this elsewhere (here we perform the check at every
- * recursive call which is a bit overkill...) *)
- let ety = Substitute.erase_regions ty in
- assert (ety = v.V.ty);
- (* Project *)
- match (v.V.value, ty) with
- | V.Concrete _, (T.Bool | T.Char | T.Integer _ | T.Str) -> []
- | V.Adt adt, T.Adt (id, region_params, tys) ->
- (* Retrieve the types of the fields *)
- let field_types =
- Subst.ctx_adt_value_get_instantiated_field_rtypes ctx adt id
- region_params tys
- in
- (* Project over the field values *)
- let fields_types = List.combine adt.V.field_values field_types in
- let proj_fields =
- List.map
- (fun (fv, fty) ->
- apply_proj_borrows_on_shared_borrow ctx fresh_reborrow regions fv
- fty)
- fields_types
- in
- List.concat proj_fields
- | V.Bottom, _ -> failwith "Unreachable"
- | V.Borrow bc, T.Ref (r, ref_ty, kind) ->
- (* Retrieve the bid of the borrow and the asb of the projected borrowed value *)
- let bid, asb =
- (* Not in the set: dive *)
- match (bc, kind) with
- | V.MutBorrow (bid, bv), T.Mut ->
- (* Apply the projection on the borrowed value *)
- let asb =
- apply_proj_borrows_on_shared_borrow ctx fresh_reborrow regions bv
- ref_ty
- in
- (bid, asb)
- | V.SharedBorrow bid, T.Shared ->
- (* Lookup the shared value *)
- let ek = ek_all in
- let sv = lookup_loan ek bid ctx in
- let asb =
- match sv with
- | _, Concrete (V.SharedLoan (_, sv))
- | _, Abstract (V.ASharedLoan (_, sv, _)) ->
- apply_proj_borrows_on_shared_borrow ctx fresh_reborrow regions
- sv ref_ty
- | _ -> failwith "Unexpected"
- in
- (bid, asb)
- | V.InactivatedMutBorrow _, _ ->
- failwith
- "Can't apply a proj_borrow over an inactivated mutable borrow"
- | _ -> failwith "Unreachable"
- in
- let asb =
- (* Check if the region is in the set of projected regions (note that
- * we never project over static regions) *)
- if region_in_set r regions then
- let bid' = fresh_reborrow bid in
- V.AsbBorrow bid' :: asb
- else asb
- in
- asb
- | V.Loan _, _ -> failwith "Unreachable"
- | V.Symbolic s, _ ->
- assert (not (symbolic_proj_comp_ended_regions_intersect_proj s ty regions));
- [ V.AsbProjReborrows (s.V.svalue, ty) ]
- | _ -> failwith "Unreachable"
-
-(** Apply (and reduce) a projector over borrows to a value.
-
- - [regions]: the regions we project
- - [v]: the value over which we project
- - [ty]: the projection type (is used to map borrows to regions, or to
- interpret the borrows as belonging to some regions...). Remember that
- `v` doesn't contain region information.
- For instance, if we have:
- `v <: ty` where:
- - `v = mut_borrow l ...`
- - `ty = Ref (r, ...)`
- then we interpret the borrow `l` as belonging to region `r`
-
- Also, when applying projections on shared values, we need to apply
- reborrows. This is a bit annoying because, with the way we compute
- the projection on borrows, we can't update the context immediately.
- Instead, we remember the list of borrows we have to insert in the
- context *afterwards*.
-
- [check_symbolic_no_ended] controls whether we check or not whether
- symbolic values don't contain already ended regions.
- This check is activated when applying projectors upon calling a function
- (because we need to check that function arguments don't contain ⊥),
- but deactivated when expanding symbolic values:
- ```
- fn f<'a,'b>(x : &'a mut u32, y : &'b mut u32) -> (&'a mut u32, &'b mut u32);
-
- let p = f(&mut x, &mut y); // p -> @s0
- assert(x == ...); // end 'a
- let z = p.1; // HERE: the symbolic expansion of @s0 contains ended regions
- ```
-*)
-let rec apply_proj_borrows (check_symbolic_no_ended : bool) (ctx : C.eval_ctx)
- (fresh_reborrow : V.BorrowId.id -> V.BorrowId.id)
- (regions : T.RegionId.set_t) (v : V.typed_value) (ty : T.rty) :
- V.typed_avalue =
- (* Sanity check - TODO: move this elsewhere (here we perform the check at every
- * recursive call which is a bit overkill...) *)
- let ety = Substitute.erase_regions ty in
- assert (ety = v.V.ty);
- (* Match *)
- let value : V.avalue =
- match (v.V.value, ty) with
- | V.Concrete cv, (T.Bool | T.Char | T.Integer _ | T.Str) -> V.AConcrete cv
- | V.Adt adt, T.Adt (id, region_params, tys) ->
- (* Retrieve the types of the fields *)
- let field_types =
- Subst.ctx_adt_value_get_instantiated_field_rtypes ctx adt id
- region_params tys
- in
- (* Project over the field values *)
- let fields_types = List.combine adt.V.field_values field_types in
- let proj_fields =
- List.map
- (fun (fv, fty) ->
- apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow
- regions fv fty)
- fields_types
- in
- V.AAdt { V.variant_id = adt.V.variant_id; field_values = proj_fields }
- | V.Bottom, _ -> failwith "Unreachable"
- | V.Borrow bc, T.Ref (r, ref_ty, kind) ->
- if
- (* Check if the region is in the set of projected regions (note that
- * we never project over static regions) *)
- region_in_set r regions
- then
- (* In the set *)
- let bc =
- match (bc, kind) with
- | V.MutBorrow (bid, bv), T.Mut ->
- (* Apply the projection on the borrowed value *)
- let bv =
- apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow
- regions bv ref_ty
- in
- V.AMutBorrow (bid, bv)
- | V.SharedBorrow bid, T.Shared -> V.ASharedBorrow bid
- | V.InactivatedMutBorrow _, _ ->
- failwith
- "Can't apply a proj_borrow over an inactivated mutable borrow"
- | _ -> failwith "Unreachable"
- in
- V.ABorrow bc
- else
- (* Not in the set: ignore *)
- let bc =
- match (bc, kind) with
- | V.MutBorrow (_bid, bv), T.Mut ->
- (* Apply the projection on the borrowed value *)
- let bv =
- apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow
- regions bv ref_ty
- in
- V.AIgnoredMutBorrow bv
- | V.SharedBorrow bid, T.Shared ->
- (* Lookup the shared value *)
- let ek = ek_all in
- let sv = lookup_loan ek bid ctx in
- let asb =
- match sv with
- | _, Concrete (V.SharedLoan (_, sv))
- | _, Abstract (V.ASharedLoan (_, sv, _)) ->
- apply_proj_borrows_on_shared_borrow ctx fresh_reborrow
- regions sv ref_ty
- | _ -> failwith "Unexpected"
- in
- V.AProjSharedBorrow asb
- | V.InactivatedMutBorrow _, _ ->
- failwith
- "Can't apply a proj_borrow over an inactivated mutable borrow"
- | _ -> failwith "Unreachable"
- in
- V.ABorrow bc
- | V.Loan _, _ -> failwith "Unreachable"
- | V.Symbolic s, _ ->
- (* Check that the symbolic value doesn't contain already ended regions,
- * if necessary *)
- if check_symbolic_no_ended then
- assert (
- not (symbolic_proj_comp_ended_regions_intersect_proj s ty regions));
- V.ASymbolic (V.AProjBorrows (s.V.svalue, ty))
- | _ -> failwith "Unreachable"
- in
- { V.value; V.ty }
-
-(** Convert a symbolic expansion *which is not a borrow* to a value *)
-let symbolic_expansion_non_borrow_to_value (sv : V.symbolic_value)
- (see : symbolic_expansion) : V.typed_value =
- let ty = Subst.erase_regions sv.V.sv_ty in
- let value =
- match see with
- | SeConcrete cv -> V.Concrete cv
- | SeAdt (variant_id, field_values) ->
- let field_values =
- List.map mk_typed_value_from_proj_comp field_values
- in
- V.Adt { V.variant_id; V.field_values }
- | SeMutRef (_, _) | SeSharedRef (_, _) ->
- failwith "Unexpected symbolic reference expansion"
- in
- { V.value; V.ty }
-
-(** Convert a symbolic expansion to a value.
-
- If the expansion is a mutable reference expansion, it converts it to a borrow.
- This function is meant to be used when reducing projectors over borrows,
- during a symbolic expansion.
- *)
-let symbolic_expansion_non_shared_borrow_to_value (sv : V.symbolic_value)
- (see : symbolic_expansion) : V.typed_value =
- match see with
- | SeMutRef (bid, bv) ->
- let ty = Subst.erase_regions sv.V.sv_ty in
- let bv = mk_typed_value_from_proj_comp bv in
- let value = V.Borrow (V.MutBorrow (bid, bv)) in
- { V.value; ty }
- | SeSharedRef (_, _) ->
- failwith "Unexpected symbolic shared reference expansion"
- | _ -> symbolic_expansion_non_borrow_to_value sv see
-
-(** Apply (and reduce) a projector over loans to a value.
-
- TODO: detailed comments. See [apply_proj_borrows]
-*)
-let apply_proj_loans_on_symbolic_expansion (regions : T.RegionId.set_t)
- (see : symbolic_expansion) (original_sv_ty : T.rty) : V.typed_avalue =
- (* Match *)
- let (value, ty) : V.avalue * T.rty =
- match (see, original_sv_ty) with
- | SeConcrete cv, (T.Bool | T.Char | T.Integer _ | T.Str) ->
- (V.AConcrete cv, original_sv_ty)
- | SeAdt (variant_id, field_values), T.Adt (_id, _region_params, _tys) ->
- (* Project over the field values *)
- let field_values =
- List.map mk_aproj_loans_from_proj_comp field_values
- in
- (V.AAdt { V.variant_id; field_values }, original_sv_ty)
- | SeMutRef (bid, spc), T.Ref (r, ref_ty, T.Mut) ->
- (* Apply the projector to the borrowed value *)
- let child_av = mk_aproj_loans_from_proj_comp spc in
- (* Check if the region is in the set of projected regions (note that
- * we never project over static regions) *)
- if region_in_set r regions then
- (* In the set: keep *)
- (V.ALoan (V.AMutLoan (bid, child_av)), ref_ty)
- else
- (* Not in the set: ignore *)
- (V.ALoan (V.AIgnoredMutLoan (bid, child_av)), ref_ty)
- | SeSharedRef (bids, spc), T.Ref (r, ref_ty, T.Shared) ->
- (* Apply the projector to the borrowed value *)
- let child_av = mk_aproj_loans_from_proj_comp spc in
- (* Check if the region is in the set of projected regions (note that
- * we never project over static regions) *)
- if region_in_set r regions then
- (* In the set: keep *)
- let shared_value = mk_typed_value_from_proj_comp spc in
- (V.ALoan (V.ASharedLoan (bids, shared_value, child_av)), ref_ty)
- else
- (* Not in the set: ignore *)
- (V.ALoan (V.AIgnoredSharedLoan child_av), ref_ty)
- | _ -> failwith "Unreachable"
- in
- { V.value; V.ty }
-
(** Auxiliary function to end borrows: lookup a borrow in the environment,
update it (by returning an updated environment where the borrow has been
replaced by [Bottom])) if we can end the borrow (for instance, it is not
@@ -672,196 +229,6 @@ let end_borrow_get_borrow (io : inner_outer)
Ok (ctx, !replaced_bc)
with FoundOuter outers -> Error outers
-(** Auxiliary function. See [give_back_value].
-
- Apply reborrows to a context.
-
- The [reborrows] input is a list of pairs (shared loan id, id to insert in the shared loan).
-*)
-let apply_reborrows (reborrows : (V.BorrowId.id * V.BorrowId.id) list)
- (ctx : C.eval_ctx) : C.eval_ctx =
- (* This is a bit brutal, but whenever we insert a reborrow, we remove
- * it from the list. This allows us to check that all the reborrows were
- * applied before returning.
- * We might reimplement that in a more efficient manner by using maps. *)
- let reborrows = ref reborrows in
-
- (* Check if a value is a mutable borrow, and return its identifier if
- it is the case *)
- let get_borrow_in_mut_borrow (v : V.typed_value) : V.BorrowId.id option =
- match v.V.value with
- | V.Borrow lc -> (
- match lc with
- | V.SharedBorrow _ | V.InactivatedMutBorrow _ -> None
- | V.MutBorrow (id, _) -> Some id)
- | _ -> None
- in
-
- (* Add the proper reborrows to a set of borrow ids (for a shared loan) *)
- let insert_reborrows bids =
- (* Find the reborrows to apply *)
- let insert, reborrows' =
- List.partition (fun (bid, _) -> V.BorrowId.Set.mem bid bids) !reborrows
- in
- reborrows := reborrows';
- let insert = List.map snd insert in
- (* Insert the borrows *)
- List.fold_left (fun bids bid -> V.BorrowId.Set.add bid bids) bids insert
- in
-
- (* Get the list of reborrows for a given borrow id *)
- let get_reborrows_for_bid bid =
- (* Find the reborrows to apply *)
- let insert, reborrows' =
- List.partition (fun (bid', _) -> bid' = bid) !reborrows
- in
- reborrows := reborrows';
- List.map snd insert
- in
-
- let borrows_to_set bids =
- List.fold_left
- (fun bids bid -> V.BorrowId.Set.add bid bids)
- V.BorrowId.Set.empty bids
- in
-
- (* Insert reborrows for a given borrow id into a given set of borrows *)
- let insert_reborrows_for_bid bids bid =
- (* Find the reborrows to apply *)
- let insert = get_reborrows_for_bid bid in
- (* Insert the borrows *)
- List.fold_left (fun bids bid -> V.BorrowId.Set.add bid bids) bids insert
- in
-
- let obj =
- object
- inherit [_] C.map_eval_ctx as super
-
- method! visit_typed_value env v =
- match v.V.value with
- | V.Borrow (V.MutBorrow (bid, bv)) ->
- let insert = get_reborrows_for_bid bid in
- let nbc = super#visit_MutBorrow env bid bv in
- let nbc = { v with V.value = V.Borrow nbc } in
- if insert = [] then (* No reborrows: do nothing special *)
- nbc
- else
- (* There are reborrows: insert a shared loan *)
- let insert = borrows_to_set insert in
- let value = V.Loan (V.SharedLoan (insert, nbc)) in
- let ty = v.V.ty in
- { V.value; ty }
- | _ -> super#visit_typed_value env v
- (** We may need to reborrow mutable borrows. Note that this doesn't
- happen for aborrows *)
-
- method! visit_loan_content env lc =
- match lc with
- | V.SharedLoan (bids, sv) ->
- (* Insert the reborrows *)
- let bids = insert_reborrows bids in
- (* Check if the contained value is a mutable borrow, in which
- * case we might need to reborrow it by adding more borrow ids
- * to the current set of borrows - by doing this small
- * manipulation here, we accumulate the borrow ids in the same
- * shared loan, right above the mutable borrow, and avoid
- * stacking shared loans (note that doing this is not a problem
- * from a soundness point of view, but it is a bit ugly...) *)
- let bids =
- match get_borrow_in_mut_borrow sv with
- | None -> bids
- | Some bid -> insert_reborrows_for_bid bids bid
- in
- (* Update and explore *)
- super#visit_SharedLoan env bids sv
- | V.MutLoan bid ->
- (* Nothing special to do *)
- super#visit_MutLoan env bid
- (** We reimplement [visit_loan_content] (rather than one of the sub-
- functions) on purpose: exhaustive matches are good for maintenance *)
-
- method! visit_aloan_content env lc =
- (* TODO: ashared_loan (amut_loan ) case *)
- match lc with
- | V.ASharedLoan (bids, v, av) ->
- (* Insert the reborrows *)
- let bids = insert_reborrows bids in
- (* Update and explore *)
- super#visit_ASharedLoan env bids v av
- | V.AIgnoredSharedLoan _
- | V.AMutLoan (_, _)
- | V.AEndedMutLoan { given_back = _; child = _ }
- | V.AEndedSharedLoan (_, _)
- | V.AIgnoredMutLoan (_, _)
- | V.AEndedIgnoredMutLoan { given_back = _; child = _ } ->
- (* Nothing particular to do *)
- super#visit_aloan_content env lc
- end
- in
-
- (* Visit *)
- let ctx = obj#visit_eval_ctx () ctx in
- (* Check that there are no reborrows remaining *)
- assert (!reborrows = []);
- (* Return *)
- ctx
-
-(** Auxiliary function to prepare reborrowing operations (used when
- applying projectors).
-
- Returns two functions:
- - a function to generate fresh re-borrow ids, and register the reborrows
- - a function to apply the reborrows in a context
- Those functions are of course stateful.
- *)
-let prepare_reborrows (config : C.config) (allow_reborrows : bool)
- (ctx : C.eval_ctx) :
- (V.BorrowId.id -> V.BorrowId.id) * (C.eval_ctx -> C.eval_ctx) =
- let reborrows : (V.BorrowId.id * V.BorrowId.id) list ref = ref [] in
- let borrow_counter = ref ctx.C.borrow_counter in
- (* The function to generate and register fresh reborrows *)
- let fresh_reborrow (bid : V.BorrowId.id) : V.BorrowId.id =
- if allow_reborrows then (
- let bid', cnt' = V.BorrowId.fresh !borrow_counter in
- borrow_counter := cnt';
- reborrows := (bid, bid') :: !reborrows;
- bid')
- else failwith "Unexpected reborrow"
- in
- (* The function to apply the reborrows in a context *)
- let apply_registered_reborrows (ctx : C.eval_ctx) : C.eval_ctx =
- match config.C.mode with
- | C.ConcreteMode ->
- (* Reborrows are introduced when applying projections in symbolic mode *)
- assert (!borrow_counter = ctx.C.borrow_counter);
- assert (!reborrows = []);
- ctx
- | C.SymbolicMode ->
- (* Update the borrow counter *)
- let ctx = { ctx with C.borrow_counter = !borrow_counter } in
- (* Apply the reborrows *)
- apply_reborrows !reborrows ctx
- in
- (fresh_reborrow, apply_registered_reborrows)
-
-let apply_proj_borrows_on_input_value (config : C.config) (ctx : C.eval_ctx)
- (regions : T.RegionId.set_t) (v : V.typed_value) (ty : T.rty) :
- C.eval_ctx * V.typed_avalue =
- let check_symbolic_no_ended = true in
- let allow_reborrows = true in
- (* Prepare the reborrows *)
- let fresh_reborrow, apply_registered_reborrows =
- prepare_reborrows config allow_reborrows ctx
- in
- (* Apply the projector *)
- let av =
- apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow regions v ty
- in
- (* Apply the reborrows *)
- let ctx = apply_registered_reborrows ctx in
- (* Return *)
- (ctx, av)
-
(** Auxiliary function to end borrows. See [give_back].
When we end a mutable borrow, we need to "give back" the value it contained
diff --git a/src/InterpreterProjectors.ml b/src/InterpreterProjectors.ml
new file mode 100644
index 00000000..9c99f8c9
--- /dev/null
+++ b/src/InterpreterProjectors.ml
@@ -0,0 +1,505 @@
+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
+module Inv = Invariants
+module S = Synthesis
+open Utils
+open InterpreterUtils
+
+(** Auxiliary function.
+
+ Apply a proj_borrows on a shared borrow.
+ In the case of shared borrows, we return [abstract_shared_borrows],
+ not avalues.
+*)
+let rec apply_proj_borrows_on_shared_borrow (ctx : C.eval_ctx)
+ (fresh_reborrow : V.BorrowId.id -> V.BorrowId.id)
+ (regions : T.RegionId.set_t) (v : V.typed_value) (ty : T.rty) :
+ V.abstract_shared_borrows =
+ (* Sanity check - TODO: move this elsewhere (here we perform the check at every
+ * recursive call which is a bit overkill...) *)
+ let ety = Substitute.erase_regions ty in
+ assert (ety = v.V.ty);
+ (* Project *)
+ match (v.V.value, ty) with
+ | V.Concrete _, (T.Bool | T.Char | T.Integer _ | T.Str) -> []
+ | V.Adt adt, T.Adt (id, region_params, tys) ->
+ (* Retrieve the types of the fields *)
+ let field_types =
+ Subst.ctx_adt_value_get_instantiated_field_rtypes ctx adt id
+ region_params tys
+ in
+ (* Project over the field values *)
+ let fields_types = List.combine adt.V.field_values field_types in
+ let proj_fields =
+ List.map
+ (fun (fv, fty) ->
+ apply_proj_borrows_on_shared_borrow ctx fresh_reborrow regions fv
+ fty)
+ fields_types
+ in
+ List.concat proj_fields
+ | V.Bottom, _ -> failwith "Unreachable"
+ | V.Borrow bc, T.Ref (r, ref_ty, kind) ->
+ (* Retrieve the bid of the borrow and the asb of the projected borrowed value *)
+ let bid, asb =
+ (* Not in the set: dive *)
+ match (bc, kind) with
+ | V.MutBorrow (bid, bv), T.Mut ->
+ (* Apply the projection on the borrowed value *)
+ let asb =
+ apply_proj_borrows_on_shared_borrow ctx fresh_reborrow regions bv
+ ref_ty
+ in
+ (bid, asb)
+ | V.SharedBorrow bid, T.Shared ->
+ (* Lookup the shared value *)
+ let ek = ek_all in
+ let sv = lookup_loan ek bid ctx in
+ let asb =
+ match sv with
+ | _, Concrete (V.SharedLoan (_, sv))
+ | _, Abstract (V.ASharedLoan (_, sv, _)) ->
+ apply_proj_borrows_on_shared_borrow ctx fresh_reborrow regions
+ sv ref_ty
+ | _ -> failwith "Unexpected"
+ in
+ (bid, asb)
+ | V.InactivatedMutBorrow _, _ ->
+ failwith
+ "Can't apply a proj_borrow over an inactivated mutable borrow"
+ | _ -> failwith "Unreachable"
+ in
+ let asb =
+ (* Check if the region is in the set of projected regions (note that
+ * we never project over static regions) *)
+ if region_in_set r regions then
+ let bid' = fresh_reborrow bid in
+ V.AsbBorrow bid' :: asb
+ else asb
+ in
+ asb
+ | V.Loan _, _ -> failwith "Unreachable"
+ | V.Symbolic s, _ ->
+ assert (not (symbolic_proj_comp_ended_regions_intersect_proj s ty regions));
+ [ V.AsbProjReborrows (s.V.svalue, ty) ]
+ | _ -> failwith "Unreachable"
+
+(** Apply (and reduce) a projector over borrows to a value.
+
+ - [regions]: the regions we project
+ - [v]: the value over which we project
+ - [ty]: the projection type (is used to map borrows to regions, or to
+ interpret the borrows as belonging to some regions...). Remember that
+ `v` doesn't contain region information.
+ For instance, if we have:
+ `v <: ty` where:
+ - `v = mut_borrow l ...`
+ - `ty = Ref (r, ...)`
+ then we interpret the borrow `l` as belonging to region `r`
+
+ Also, when applying projections on shared values, we need to apply
+ reborrows. This is a bit annoying because, with the way we compute
+ the projection on borrows, we can't update the context immediately.
+ Instead, we remember the list of borrows we have to insert in the
+ context *afterwards*.
+
+ [check_symbolic_no_ended] controls whether we check or not whether
+ symbolic values don't contain already ended regions.
+ This check is activated when applying projectors upon calling a function
+ (because we need to check that function arguments don't contain ⊥),
+ but deactivated when expanding symbolic values:
+ ```
+ fn f<'a,'b>(x : &'a mut u32, y : &'b mut u32) -> (&'a mut u32, &'b mut u32);
+
+ let p = f(&mut x, &mut y); // p -> @s0
+ assert(x == ...); // end 'a
+ let z = p.1; // HERE: the symbolic expansion of @s0 contains ended regions
+ ```
+*)
+let rec apply_proj_borrows (check_symbolic_no_ended : bool) (ctx : C.eval_ctx)
+ (fresh_reborrow : V.BorrowId.id -> V.BorrowId.id)
+ (regions : T.RegionId.set_t) (v : V.typed_value) (ty : T.rty) :
+ V.typed_avalue =
+ (* Sanity check - TODO: move this elsewhere (here we perform the check at every
+ * recursive call which is a bit overkill...) *)
+ let ety = Substitute.erase_regions ty in
+ assert (ety = v.V.ty);
+ (* Match *)
+ let value : V.avalue =
+ match (v.V.value, ty) with
+ | V.Concrete cv, (T.Bool | T.Char | T.Integer _ | T.Str) -> V.AConcrete cv
+ | V.Adt adt, T.Adt (id, region_params, tys) ->
+ (* Retrieve the types of the fields *)
+ let field_types =
+ Subst.ctx_adt_value_get_instantiated_field_rtypes ctx adt id
+ region_params tys
+ in
+ (* Project over the field values *)
+ let fields_types = List.combine adt.V.field_values field_types in
+ let proj_fields =
+ List.map
+ (fun (fv, fty) ->
+ apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow
+ regions fv fty)
+ fields_types
+ in
+ V.AAdt { V.variant_id = adt.V.variant_id; field_values = proj_fields }
+ | V.Bottom, _ -> failwith "Unreachable"
+ | V.Borrow bc, T.Ref (r, ref_ty, kind) ->
+ if
+ (* Check if the region is in the set of projected regions (note that
+ * we never project over static regions) *)
+ region_in_set r regions
+ then
+ (* In the set *)
+ let bc =
+ match (bc, kind) with
+ | V.MutBorrow (bid, bv), T.Mut ->
+ (* Apply the projection on the borrowed value *)
+ let bv =
+ apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow
+ regions bv ref_ty
+ in
+ V.AMutBorrow (bid, bv)
+ | V.SharedBorrow bid, T.Shared -> V.ASharedBorrow bid
+ | V.InactivatedMutBorrow _, _ ->
+ failwith
+ "Can't apply a proj_borrow over an inactivated mutable borrow"
+ | _ -> failwith "Unreachable"
+ in
+ V.ABorrow bc
+ else
+ (* Not in the set: ignore *)
+ let bc =
+ match (bc, kind) with
+ | V.MutBorrow (_bid, bv), T.Mut ->
+ (* Apply the projection on the borrowed value *)
+ let bv =
+ apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow
+ regions bv ref_ty
+ in
+ V.AIgnoredMutBorrow bv
+ | V.SharedBorrow bid, T.Shared ->
+ (* Lookup the shared value *)
+ let ek = ek_all in
+ let sv = lookup_loan ek bid ctx in
+ let asb =
+ match sv with
+ | _, Concrete (V.SharedLoan (_, sv))
+ | _, Abstract (V.ASharedLoan (_, sv, _)) ->
+ apply_proj_borrows_on_shared_borrow ctx fresh_reborrow
+ regions sv ref_ty
+ | _ -> failwith "Unexpected"
+ in
+ V.AProjSharedBorrow asb
+ | V.InactivatedMutBorrow _, _ ->
+ failwith
+ "Can't apply a proj_borrow over an inactivated mutable borrow"
+ | _ -> failwith "Unreachable"
+ in
+ V.ABorrow bc
+ | V.Loan _, _ -> failwith "Unreachable"
+ | V.Symbolic s, _ ->
+ (* Check that the symbolic value doesn't contain already ended regions,
+ * if necessary *)
+ if check_symbolic_no_ended then
+ assert (
+ not (symbolic_proj_comp_ended_regions_intersect_proj s ty regions));
+ V.ASymbolic (V.AProjBorrows (s.V.svalue, ty))
+ | _ -> failwith "Unreachable"
+ in
+ { V.value; V.ty }
+
+(** Convert a symbolic expansion *which is not a borrow* to a value *)
+let symbolic_expansion_non_borrow_to_value (sv : V.symbolic_value)
+ (see : symbolic_expansion) : V.typed_value =
+ let ty = Subst.erase_regions sv.V.sv_ty in
+ let value =
+ match see with
+ | SeConcrete cv -> V.Concrete cv
+ | SeAdt (variant_id, field_values) ->
+ let field_values =
+ List.map mk_typed_value_from_proj_comp field_values
+ in
+ V.Adt { V.variant_id; V.field_values }
+ | SeMutRef (_, _) | SeSharedRef (_, _) ->
+ failwith "Unexpected symbolic reference expansion"
+ in
+ { V.value; V.ty }
+
+(** Convert a symbolic expansion to a value.
+
+ If the expansion is a mutable reference expansion, it converts it to a borrow.
+ This function is meant to be used when reducing projectors over borrows,
+ during a symbolic expansion.
+ *)
+let symbolic_expansion_non_shared_borrow_to_value (sv : V.symbolic_value)
+ (see : symbolic_expansion) : V.typed_value =
+ match see with
+ | SeMutRef (bid, bv) ->
+ let ty = Subst.erase_regions sv.V.sv_ty in
+ let bv = mk_typed_value_from_proj_comp bv in
+ let value = V.Borrow (V.MutBorrow (bid, bv)) in
+ { V.value; ty }
+ | SeSharedRef (_, _) ->
+ failwith "Unexpected symbolic shared reference expansion"
+ | _ -> symbolic_expansion_non_borrow_to_value sv see
+
+(** Apply (and reduce) a projector over loans to a value.
+
+ TODO: detailed comments. See [apply_proj_borrows]
+*)
+let apply_proj_loans_on_symbolic_expansion (regions : T.RegionId.set_t)
+ (see : symbolic_expansion) (original_sv_ty : T.rty) : V.typed_avalue =
+ (* Match *)
+ let (value, ty) : V.avalue * T.rty =
+ match (see, original_sv_ty) with
+ | SeConcrete cv, (T.Bool | T.Char | T.Integer _ | T.Str) ->
+ (V.AConcrete cv, original_sv_ty)
+ | SeAdt (variant_id, field_values), T.Adt (_id, _region_params, _tys) ->
+ (* Project over the field values *)
+ let field_values =
+ List.map mk_aproj_loans_from_proj_comp field_values
+ in
+ (V.AAdt { V.variant_id; field_values }, original_sv_ty)
+ | SeMutRef (bid, spc), T.Ref (r, ref_ty, T.Mut) ->
+ (* Apply the projector to the borrowed value *)
+ let child_av = mk_aproj_loans_from_proj_comp spc in
+ (* Check if the region is in the set of projected regions (note that
+ * we never project over static regions) *)
+ if region_in_set r regions then
+ (* In the set: keep *)
+ (V.ALoan (V.AMutLoan (bid, child_av)), ref_ty)
+ else
+ (* Not in the set: ignore *)
+ (V.ALoan (V.AIgnoredMutLoan (bid, child_av)), ref_ty)
+ | SeSharedRef (bids, spc), T.Ref (r, ref_ty, T.Shared) ->
+ (* Apply the projector to the borrowed value *)
+ let child_av = mk_aproj_loans_from_proj_comp spc in
+ (* Check if the region is in the set of projected regions (note that
+ * we never project over static regions) *)
+ if region_in_set r regions then
+ (* In the set: keep *)
+ let shared_value = mk_typed_value_from_proj_comp spc in
+ (V.ALoan (V.ASharedLoan (bids, shared_value, child_av)), ref_ty)
+ else
+ (* Not in the set: ignore *)
+ (V.ALoan (V.AIgnoredSharedLoan child_av), ref_ty)
+ | _ -> failwith "Unreachable"
+ in
+ { V.value; V.ty }
+
+(** Auxiliary function. See [give_back_value].
+
+ Apply reborrows to a context.
+
+ The [reborrows] input is a list of pairs (shared loan id, id to insert
+ in the shared loan).
+ This function is used when applying projectors on shared borrows: when
+ doing so, we might need to reborrow subvalues from the shared value.
+ For instance:
+ ```
+ fn f<'a,'b,'c>(x : &'a 'b 'c u32)
+ ```
+ When introducing the abstractions for 'a, 'b and 'c, we apply a projector
+ on some value `shared_borrow l : &'a &'b &'c u32`.
+ In the 'a abstraction, this shared borrow gets projected. However, when
+ reducing the projectors for the 'b and 'c abstractions, we need to make
+ sure that the borrows living in regions 'b and 'c live as long as those
+ regions. This is done by looking up the shared value and applying reborrows
+ on the borrows we find there (note that those reborrows apply on shared
+ borrows - easy - and mutable borrows - in this case, we reborrow the whole
+ borrow: `mut_borrow ... ~~> shared_loan {...} (mut_borrow ...)`).
+*)
+let apply_reborrows (reborrows : (V.BorrowId.id * V.BorrowId.id) list)
+ (ctx : C.eval_ctx) : C.eval_ctx =
+ (* This is a bit brutal, but whenever we insert a reborrow, we remove
+ * it from the list. This allows us to check that all the reborrows were
+ * applied before returning.
+ * We might reimplement that in a more efficient manner by using maps. *)
+ let reborrows = ref reborrows in
+
+ (* Check if a value is a mutable borrow, and return its identifier if
+ it is the case *)
+ let get_borrow_in_mut_borrow (v : V.typed_value) : V.BorrowId.id option =
+ match v.V.value with
+ | V.Borrow lc -> (
+ match lc with
+ | V.SharedBorrow _ | V.InactivatedMutBorrow _ -> None
+ | V.MutBorrow (id, _) -> Some id)
+ | _ -> None
+ in
+
+ (* Add the proper reborrows to a set of borrow ids (for a shared loan) *)
+ let insert_reborrows bids =
+ (* Find the reborrows to apply *)
+ let insert, reborrows' =
+ List.partition (fun (bid, _) -> V.BorrowId.Set.mem bid bids) !reborrows
+ in
+ reborrows := reborrows';
+ let insert = List.map snd insert in
+ (* Insert the borrows *)
+ List.fold_left (fun bids bid -> V.BorrowId.Set.add bid bids) bids insert
+ in
+
+ (* Get the list of reborrows for a given borrow id *)
+ let get_reborrows_for_bid bid =
+ (* Find the reborrows to apply *)
+ let insert, reborrows' =
+ List.partition (fun (bid', _) -> bid' = bid) !reborrows
+ in
+ reborrows := reborrows';
+ List.map snd insert
+ in
+
+ let borrows_to_set bids =
+ List.fold_left
+ (fun bids bid -> V.BorrowId.Set.add bid bids)
+ V.BorrowId.Set.empty bids
+ in
+
+ (* Insert reborrows for a given borrow id into a given set of borrows *)
+ let insert_reborrows_for_bid bids bid =
+ (* Find the reborrows to apply *)
+ let insert = get_reborrows_for_bid bid in
+ (* Insert the borrows *)
+ List.fold_left (fun bids bid -> V.BorrowId.Set.add bid bids) bids insert
+ in
+
+ let obj =
+ object
+ inherit [_] C.map_eval_ctx as super
+
+ method! visit_typed_value env v =
+ match v.V.value with
+ | V.Borrow (V.MutBorrow (bid, bv)) ->
+ let insert = get_reborrows_for_bid bid in
+ let nbc = super#visit_MutBorrow env bid bv in
+ let nbc = { v with V.value = V.Borrow nbc } in
+ if insert = [] then (* No reborrows: do nothing special *)
+ nbc
+ else
+ (* There are reborrows: insert a shared loan *)
+ let insert = borrows_to_set insert in
+ let value = V.Loan (V.SharedLoan (insert, nbc)) in
+ let ty = v.V.ty in
+ { V.value; ty }
+ | _ -> super#visit_typed_value env v
+ (** We may need to reborrow mutable borrows. Note that this doesn't
+ happen for aborrows *)
+
+ method! visit_loan_content env lc =
+ match lc with
+ | V.SharedLoan (bids, sv) ->
+ (* Insert the reborrows *)
+ let bids = insert_reborrows bids in
+ (* Check if the contained value is a mutable borrow, in which
+ * case we might need to reborrow it by adding more borrow ids
+ * to the current set of borrows - by doing this small
+ * manipulation here, we accumulate the borrow ids in the same
+ * shared loan, right above the mutable borrow, and avoid
+ * stacking shared loans (note that doing this is not a problem
+ * from a soundness point of view, but it is a bit ugly...) *)
+ let bids =
+ match get_borrow_in_mut_borrow sv with
+ | None -> bids
+ | Some bid -> insert_reborrows_for_bid bids bid
+ in
+ (* Update and explore *)
+ super#visit_SharedLoan env bids sv
+ | V.MutLoan bid ->
+ (* Nothing special to do *)
+ super#visit_MutLoan env bid
+ (** We reimplement [visit_loan_content] (rather than one of the sub-
+ functions) on purpose: exhaustive matches are good for maintenance *)
+
+ method! visit_aloan_content env lc =
+ (* TODO: ashared_loan (amut_loan ) case *)
+ match lc with
+ | V.ASharedLoan (bids, v, av) ->
+ (* Insert the reborrows *)
+ let bids = insert_reborrows bids in
+ (* Update and explore *)
+ super#visit_ASharedLoan env bids v av
+ | V.AIgnoredSharedLoan _
+ | V.AMutLoan (_, _)
+ | V.AEndedMutLoan { given_back = _; child = _ }
+ | V.AEndedSharedLoan (_, _)
+ | V.AIgnoredMutLoan (_, _)
+ | V.AEndedIgnoredMutLoan { given_back = _; child = _ } ->
+ (* Nothing particular to do *)
+ super#visit_aloan_content env lc
+ end
+ in
+
+ (* Visit *)
+ let ctx = obj#visit_eval_ctx () ctx in
+ (* Check that there are no reborrows remaining *)
+ assert (!reborrows = []);
+ (* Return *)
+ ctx
+
+(** Auxiliary function to prepare reborrowing operations (used when
+ applying projectors).
+
+ Returns two functions:
+ - a function to generate fresh re-borrow ids, and register the reborrows
+ - a function to apply the reborrows in a context
+ Those functions are of course stateful.
+ *)
+let prepare_reborrows (config : C.config) (allow_reborrows : bool)
+ (ctx : C.eval_ctx) :
+ (V.BorrowId.id -> V.BorrowId.id) * (C.eval_ctx -> C.eval_ctx) =
+ let reborrows : (V.BorrowId.id * V.BorrowId.id) list ref = ref [] in
+ let borrow_counter = ref ctx.C.borrow_counter in
+ (* The function to generate and register fresh reborrows *)
+ let fresh_reborrow (bid : V.BorrowId.id) : V.BorrowId.id =
+ if allow_reborrows then (
+ let bid', cnt' = V.BorrowId.fresh !borrow_counter in
+ borrow_counter := cnt';
+ reborrows := (bid, bid') :: !reborrows;
+ bid')
+ else failwith "Unexpected reborrow"
+ in
+ (* The function to apply the reborrows in a context *)
+ let apply_registered_reborrows (ctx : C.eval_ctx) : C.eval_ctx =
+ match config.C.mode with
+ | C.ConcreteMode ->
+ (* Reborrows are introduced when applying projections in symbolic mode *)
+ assert (!borrow_counter = ctx.C.borrow_counter);
+ assert (!reborrows = []);
+ ctx
+ | C.SymbolicMode ->
+ (* Update the borrow counter *)
+ let ctx = { ctx with C.borrow_counter = !borrow_counter } in
+ (* Apply the reborrows *)
+ apply_reborrows !reborrows ctx
+ in
+ (fresh_reborrow, apply_registered_reborrows)
+
+let apply_proj_borrows_on_input_value (config : C.config) (ctx : C.eval_ctx)
+ (regions : T.RegionId.set_t) (v : V.typed_value) (ty : T.rty) :
+ C.eval_ctx * V.typed_avalue =
+ let check_symbolic_no_ended = true in
+ let allow_reborrows = true in
+ (* Prepare the reborrows *)
+ let fresh_reborrow, apply_registered_reborrows =
+ prepare_reborrows config allow_reborrows ctx
+ in
+ (* Apply the projector *)
+ let av =
+ apply_proj_borrows check_symbolic_no_ended ctx fresh_reborrow regions v ty
+ in
+ (* Apply the reborrows *)
+ let ctx = apply_registered_reborrows ctx in
+ (* Return *)
+ (ctx, av)
diff --git a/src/InterpreterUtils.ml b/src/InterpreterUtils.ml
index edc8594c..c652a1d3 100644
--- a/src/InterpreterUtils.ml
+++ b/src/InterpreterUtils.ml
@@ -632,3 +632,163 @@ type symbolic_expansion =
| SeAdt of (T.VariantId.id option * V.symbolic_proj_comp list)
| SeMutRef of V.BorrowId.id * V.symbolic_proj_comp
| SeSharedRef of V.BorrowId.set_t * V.symbolic_proj_comp
+
+(** The following type identifies the relative position of expressions (in
+ particular borrows) in other expressions.
+
+ For instance, it is used to control [end_borrow]: we usually only allow
+ to end "outer" borrows, unless we perform a drop.
+*)
+type inner_outer = Inner | Outer
+
+type borrow_ids = Borrows of V.BorrowId.Set.t | Borrow of V.BorrowId.id
+
+exception FoundBorrowIds of borrow_ids
+
+let update_if_none opt x = match opt with None -> Some x | _ -> opt
+
+(** Auxiliary function: see its usage in [end_borrow_get_borrow_in_value] *)
+let update_outer_borrows (io : inner_outer)
+ (outer : V.AbstractionId.id option * borrow_ids option) (x : borrow_ids) :
+ V.AbstractionId.id option * borrow_ids option =
+ match io with
+ | Inner ->
+ (* If we can end inner borrows, we don't keep track of the outer borrows *)
+ outer
+ | Outer ->
+ let abs, opt = outer in
+ (abs, update_if_none opt x)
+
+(** Return the first loan we find in a value *)
+let get_first_loan_in_value (v : V.typed_value) : V.loan_content option =
+ let obj =
+ object
+ inherit [_] V.iter_typed_value
+
+ method! visit_loan_content _ lc = raise (FoundLoanContent lc)
+ end
+ in
+ (* We use exceptions *)
+ try
+ obj#visit_typed_value () v;
+ None
+ with FoundLoanContent lc -> Some lc
+
+(** Check if two different projections intersect. This is necessary when
+ giving a symbolic value to an abstraction: we need to check that
+ the regions which are already ended inside the abstraction don't
+ intersect the regions over which we project in the new abstraction.
+ Note that the two abstractions have different views (in terms of regions)
+ of the symbolic value (hence the two region types).
+*)
+let rec projections_intersect (ty1 : T.rty) (rset1 : T.RegionId.set_t)
+ (ty2 : T.rty) (rset2 : T.RegionId.set_t) : bool =
+ match (ty1, ty2) with
+ | T.Bool, T.Bool | T.Char, T.Char | T.Str, T.Str -> false
+ | T.Integer int_ty1, T.Integer int_ty2 ->
+ assert (int_ty1 = int_ty2);
+ false
+ | T.Adt (id1, regions1, tys1), T.Adt (id2, regions2, tys2) ->
+ assert (id1 = id2);
+ (* The intersection check for the ADTs is very crude:
+ * we check if some arguments intersect. As all the type and region
+ * parameters should be used somewhere in the ADT (otherwise rustc
+ * generates an error), it means that it should be equivalent to checking
+ * whether two fields intersect (and anyway comparing the field types is
+ * difficult in case of enumerations...).
+ * If we didn't have the above property enforced by the rust compiler,
+ * this check would still be a reasonable conservative approximation. *)
+ let regions = List.combine regions1 regions2 in
+ let tys = List.combine tys1 tys2 in
+ List.exists
+ (fun (r1, r2) -> region_in_set r1 rset1 && region_in_set r2 rset2)
+ regions
+ || List.exists
+ (fun (ty1, ty2) -> projections_intersect ty1 rset1 ty2 rset2)
+ tys
+ | T.Array ty1, T.Array ty2 | T.Slice ty1, T.Slice ty2 ->
+ projections_intersect ty1 rset1 ty2 rset2
+ | T.Ref (r1, ty1, kind1), T.Ref (r2, ty2, kind2) ->
+ (* Sanity check *)
+ assert (kind1 = kind2);
+ (* The projections intersect if the borrows intersect or their contents
+ * intersect *)
+ (region_in_set r1 rset1 && region_in_set r2 rset2)
+ || projections_intersect ty1 rset1 ty2 rset2
+ | _ -> failwith "Unreachable"
+
+(** Check if the ended regions of a comp projector over a symbolic value
+ intersect the regions listed in another projection *)
+let symbolic_proj_comp_ended_regions_intersect_proj (s : V.symbolic_proj_comp)
+ (ty : T.rty) (regions : T.RegionId.set_t) : bool =
+ projections_intersect s.V.svalue.V.sv_ty s.V.rset_ended ty regions
+
+(** Check that a symbolic value doesn't contain ended regions.
+
+ Note that we don't check that the set of ended regions is empty: we
+ check that the set of ended regions doesn't intersect the set of
+ regions used in the type (this is more general).
+*)
+let symbolic_proj_comp_ended_regions (s : V.symbolic_proj_comp) : bool =
+ let regions = rty_regions s.V.svalue.V.sv_ty in
+ not (T.RegionId.Set.disjoint regions s.rset_ended)
+
+(** Check if a [value] contains ⊥.
+
+ Note that this function is very general: it also checks wether
+ symbolic values contain already ended regions.
+ *)
+let bottom_in_value (v : V.typed_value) : bool =
+ let obj =
+ object
+ inherit [_] V.iter_typed_value
+
+ method! visit_Bottom _ = raise Found
+
+ method! visit_symbolic_proj_comp _ s =
+ if symbolic_proj_comp_ended_regions s then raise Found else ()
+ end
+ in
+ (* We use exceptions *)
+ try
+ obj#visit_typed_value () v;
+ false
+ with Found -> true
+
+(** Check if an [avalue] contains ⊥.
+
+ Note that this function is very general: it also checks wether
+ symbolic values contain already ended regions.
+
+ TODO: remove?
+*)
+let bottom_in_avalue (v : V.typed_avalue) (_abs_regions : T.RegionId.set_t) :
+ bool =
+ let obj =
+ object
+ inherit [_] V.iter_typed_avalue
+
+ method! visit_Bottom _ = raise Found
+
+ method! visit_symbolic_proj_comp _ sv =
+ if symbolic_proj_comp_ended_regions sv then raise Found else ()
+
+ method! visit_aproj _ ap =
+ (* Nothing to do actually *)
+ match ap with
+ | V.AProjLoans _sv -> ()
+ | V.AProjBorrows (_sv, _rty) -> ()
+ end
+ in
+ (* We use exceptions *)
+ try
+ obj#visit_typed_avalue () v;
+ false
+ with Found -> true
+
+type outer_borrows_or_abs =
+ | OuterBorrows of borrow_ids
+ | OuterAbs of V.AbstractionId.id
+
+exception FoundOuter of outer_borrows_or_abs
+(** Utility exception *)