1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
|
open Types
open Values
open Expressions
open Contexts
open Cps
open ValuesUtils
open InterpreterUtils
open InterpreterBorrowsCore
open InterpreterBorrows
open InterpreterExpansion
open Errors
module Synth = SynthesizeSymbolic
(** The local logger *)
let log = Logging.paths_log
(** Paths *)
(** When we fail reading from or writing to a path, it might be because we
need to update the environment by ending borrows, expanding symbolic
values, etc. The following type is used to convey this information.
TODO: compare with borrow_lres?
*)
type path_fail_kind =
| FailSharedLoan of BorrowId.Set.t
(** Failure because we couldn't go inside a shared loan *)
| FailMutLoan of BorrowId.id
(** Failure because we couldn't go inside a mutable loan *)
| FailReservedMutBorrow of BorrowId.id
(** Failure because we couldn't go inside a reserved mutable borrow
(which should get activated) *)
| FailSymbolic of int * symbolic_value
(** Failure because we need to enter a symbolic value (and thus need to
expand it).
We return the number of elements which remained in the path when we
reached the error - this allows to retrieve the path prefix, which
is useful for the synthesis. *)
| FailBottom of int * projection_elem * ety
(** Failure because we need to enter an any value - we can expand Bottom
values if they are left values. We return the number of elements which
remained in the path when we reached the error - this allows to
properly update the Bottom value, if needs be.
*)
| FailBorrow of borrow_content
(** We got stuck because we couldn't enter a borrow *)
[@@deriving show]
(** Result of evaluating a path (reading from a path/writing to a path)
Note that when we fail, we return information used to update the
environment, as well as the
*)
type 'a path_access_result = ('a, path_fail_kind) result
(** The result of reading from/writing to a place *)
type updated_read_value = { read : typed_value; updated : typed_value }
type projection_access = {
enter_shared_loans : bool;
enter_mut_borrows : bool;
lookup_shared_borrows : bool;
}
(** Generic function to access (read/write) the value at the end of a projection.
We return the (eventually) updated value, the value we read at the end of
the place and the (eventually) updated environment.
TODO: use exceptions?
*)
let rec access_projection (meta : Meta.meta) (access : projection_access)
(ctx : eval_ctx)
(* Function to (eventually) update the value we find *)
(update : typed_value -> typed_value) (p : projection) (v : typed_value) :
(eval_ctx * updated_read_value) path_access_result =
(* For looking up/updating shared loans *)
let ek : exploration_kind =
{ enter_shared_loans = true; enter_mut_borrows = true; enter_abs = true }
in
match p with
| [] ->
let nv = update v in
(* Type checking *)
if nv.ty <> v.ty then (
log#lerror
(lazy
("Not the same type:\n- nv.ty: " ^ show_ety nv.ty ^ "\n- v.ty: "
^ show_ety v.ty));
craise __FILE__ __LINE__ meta
"Assertion failed: new value doesn't have the same type as its \
destination");
Ok (ctx, { read = v; updated = nv })
| pe :: p' -> (
(* Match on the projection element and the value *)
match (pe, v.value, v.ty) with
| ( Field ((ProjAdt (_, _) as proj_kind), field_id),
VAdt adt,
TAdt (type_id, _) ) -> (
(* Check consistency *)
(match (proj_kind, type_id) with
| ProjAdt (def_id, opt_variant_id), TAdtId def_id' ->
sanity_check __FILE__ __LINE__ (def_id = def_id') meta;
sanity_check __FILE__ __LINE__
(opt_variant_id = adt.variant_id)
meta
| _ -> craise __FILE__ __LINE__ meta "Unreachable");
(* Actually project *)
let fv = FieldId.nth adt.field_values field_id in
match access_projection meta access ctx update p' fv with
| Error err -> Error err
| Ok (ctx, res) ->
(* Update the field value *)
let nvalues =
FieldId.update_nth adt.field_values field_id res.updated
in
let nadt = VAdt { adt with field_values = nvalues } in
let updated = { v with value = nadt } in
Ok (ctx, { res with updated }))
(* Tuples *)
| Field (ProjTuple arity, field_id), VAdt adt, TAdt (TTuple, _) -> (
sanity_check __FILE__ __LINE__
(arity = List.length adt.field_values)
meta;
let fv = FieldId.nth adt.field_values field_id in
(* Project *)
match access_projection meta access ctx update p' fv with
| Error err -> Error err
| Ok (ctx, res) ->
(* Update the field value *)
let nvalues =
FieldId.update_nth adt.field_values field_id res.updated
in
let ntuple = VAdt { adt with field_values = nvalues } in
let updated = { v with value = ntuple } in
Ok (ctx, { res with updated })
(* If we reach Bottom, it may mean we need to expand an uninitialized
* enumeration value *))
| Field ((ProjAdt (_, _) | ProjTuple _), _), VBottom, _ ->
Error (FailBottom (1 + List.length p', pe, v.ty))
(* Symbolic value: needs to be expanded *)
| _, VSymbolic sp, _ ->
(* Expand the symbolic value *)
Error (FailSymbolic (1 + List.length p', sp))
(* Box dereferencement *)
| ( DerefBox,
VAdt { variant_id = None; field_values = [ bv ] },
TAdt (TAssumed TBox, _) ) -> (
(* We allow moving outside of boxes. In practice, this kind of
* manipulations should happen only inside unsafe code, so
* it shouldn't happen due to user code, and we leverage it
* when implementing box dereferencement for the concrete
* interpreter *)
match access_projection meta access ctx update p' bv with
| Error err -> Error err
| Ok (ctx, res) ->
let nv =
{
v with
value =
VAdt { variant_id = None; field_values = [ res.updated ] };
}
in
Ok (ctx, { res with updated = nv }))
(* Borrows *)
| Deref, VBorrow bc, _ -> (
match bc with
| VSharedBorrow bid ->
(* Lookup the loan content, and explore from there *)
if access.lookup_shared_borrows then
match lookup_loan meta ek bid ctx with
| _, Concrete (VMutLoan _) ->
craise __FILE__ __LINE__ meta "Expected a shared loan"
| _, Concrete (VSharedLoan (bids, sv)) -> (
(* Explore the shared value *)
match access_projection meta access ctx update p' sv with
| Error err -> Error err
| Ok (ctx, res) ->
(* Update the shared loan with the new value returned
by {!access_projection} *)
let ctx =
update_loan meta ek bid
(VSharedLoan (bids, res.updated))
ctx
in
(* Return - note that we don't need to update the borrow itself *)
Ok (ctx, { res with updated = v }))
| ( _,
Abstract
( AMutLoan (_, _)
| AEndedMutLoan
{ given_back = _; child = _; given_back_meta = _ }
| AEndedSharedLoan (_, _)
| AIgnoredMutLoan (_, _)
| AEndedIgnoredMutLoan
{ given_back = _; child = _; given_back_meta = _ }
| AIgnoredSharedLoan _ ) ) ->
craise __FILE__ __LINE__ meta
"Expected a shared (abstraction) loan"
| _, Abstract (ASharedLoan (bids, sv, _av)) -> (
(* Explore the shared value *)
match access_projection meta access ctx update p' sv with
| Error err -> Error err
| Ok (ctx, res) ->
(* Relookup the child avalue *)
let av =
match lookup_loan meta ek bid ctx with
| _, Abstract (ASharedLoan (_, _, av)) -> av
| _ -> craise __FILE__ __LINE__ meta "Unexpected"
in
(* Update the shared loan with the new value returned
by {!access_projection} *)
let ctx =
update_aloan meta ek bid
(ASharedLoan (bids, res.updated, av))
ctx
in
(* Return - note that we don't need to update the borrow itself *)
Ok (ctx, { res with updated = v }))
else Error (FailBorrow bc)
| VReservedMutBorrow bid -> Error (FailReservedMutBorrow bid)
| VMutBorrow (bid, bv) ->
if access.enter_mut_borrows then
match access_projection meta access ctx update p' bv with
| Error err -> Error err
| Ok (ctx, res) ->
let nv =
{ v with value = VBorrow (VMutBorrow (bid, res.updated)) }
in
Ok (ctx, { res with updated = nv })
else Error (FailBorrow bc))
| _, VLoan lc, _ -> (
match lc with
| VMutLoan bid -> Error (FailMutLoan bid)
| VSharedLoan (bids, sv) ->
(* If we can enter shared loan, we ignore the loan. Pay attention
to the fact that we need to reexplore the *whole* place (i.e,
we mustn't ignore the current projection element *)
if access.enter_shared_loans then
match
access_projection meta access ctx update (pe :: p') sv
with
| Error err -> Error err
| Ok (ctx, res) ->
let nv =
{ v with value = VLoan (VSharedLoan (bids, res.updated)) }
in
Ok (ctx, { res with updated = nv })
else Error (FailSharedLoan bids))
| (_, (VLiteral _ | VAdt _ | VBottom | VBorrow _), _) as r ->
let pe, v, ty = r in
let pe = "- pe: " ^ show_projection_elem pe in
let v = "- v:\n" ^ show_value v in
let ty = "- ty:\n" ^ show_ety ty in
log#serror ("Inconsistent projection:\n" ^ pe ^ "\n" ^ v ^ "\n" ^ ty);
craise __FILE__ __LINE__ meta "Inconsistent projection")
(** Generic function to access (read/write) the value at a given place.
We return the value we read at the place and the (eventually) updated
environment, if we managed to access the place, or the precise reason
why we failed.
*)
let access_place (meta : Meta.meta) (access : projection_access)
(* Function to (eventually) update the value we find *)
(update : typed_value -> typed_value) (p : place) (ctx : eval_ctx) :
(eval_ctx * typed_value) path_access_result =
(* Lookup the variable's value *)
let value = ctx_lookup_var_value meta ctx p.var_id in
(* Apply the projection *)
match access_projection meta access ctx update p.projection value with
| Error err -> Error err
| Ok (ctx, res) ->
(* Update the value *)
let ctx = ctx_update_var_value meta ctx p.var_id res.updated in
(* Return *)
Ok (ctx, res.read)
type access_kind =
| Read (** We can go inside borrows and loans *)
| Write (** Don't enter shared borrows or shared loans *)
| Move (** Don't enter borrows or loans *)
let access_kind_to_projection_access (access : access_kind) : projection_access
=
match access with
| Read ->
{
enter_shared_loans = true;
enter_mut_borrows = true;
lookup_shared_borrows = true;
}
| Write ->
{
enter_shared_loans = false;
enter_mut_borrows = true;
lookup_shared_borrows = false;
}
| Move ->
{
enter_shared_loans = false;
enter_mut_borrows = false;
lookup_shared_borrows = false;
}
(** Attempt to read the value at a given place.
Note that we only access the value at the place, and do not check that
the value is "well-formed" (for instance that it doesn't contain bottoms).
*)
let try_read_place (meta : Meta.meta) (access : access_kind) (p : place)
(ctx : eval_ctx) : typed_value path_access_result =
let access = access_kind_to_projection_access access in
(* The update function is the identity *)
let update v = v in
match access_place meta access update p ctx with
| Error err -> Error err
| Ok (ctx1, read_value) ->
(* Note that we ignore the new environment: it should be the same as the
original one.
*)
if !Config.sanity_checks then
if ctx1 <> ctx then (
let msg =
"Unexpected environment update:\nNew environment:\n"
^ show_env ctx1.env ^ "\n\nOld environment:\n" ^ show_env ctx.env
in
log#serror msg;
craise __FILE__ __LINE__ meta "Unexpected environment update");
Ok read_value
let read_place (meta : Meta.meta) (access : access_kind) (p : place)
(ctx : eval_ctx) : typed_value =
match try_read_place meta access p ctx with
| Error e ->
craise __FILE__ __LINE__ meta ("Unreachable: " ^ show_path_fail_kind e)
| Ok v -> v
(** Attempt to update the value at a given place *)
let try_write_place (meta : Meta.meta) (access : access_kind) (p : place)
(nv : typed_value) (ctx : eval_ctx) : eval_ctx path_access_result =
let access = access_kind_to_projection_access access in
(* The update function substitutes the value with the new value *)
let update _ = nv in
match access_place meta access update p ctx with
| Error err -> Error err
| Ok (ctx, _) ->
(* We ignore the read value *)
Ok ctx
let write_place (meta : Meta.meta) (access : access_kind) (p : place)
(nv : typed_value) (ctx : eval_ctx) : eval_ctx =
match try_write_place meta access p nv ctx with
| Error e ->
craise __FILE__ __LINE__ meta ("Unreachable: " ^ show_path_fail_kind e)
| Ok ctx -> ctx
let compute_expanded_bottom_adt_value (meta : Meta.meta) (ctx : eval_ctx)
(def_id : TypeDeclId.id) (opt_variant_id : VariantId.id option)
(generics : generic_args) : typed_value =
sanity_check __FILE__ __LINE__
(TypesUtils.generic_args_only_erased_regions generics)
meta;
(* Lookup the definition and check if it is an enumeration - it
should be an enumeration if and only if the projection element
is a field projection with *some* variant id. Retrieve the list
of fields at the same time. *)
let def = ctx_lookup_type_decl ctx def_id in
sanity_check __FILE__ __LINE__
(List.length generics.regions = List.length def.generics.regions)
meta;
(* Compute the field types *)
let field_types =
AssociatedTypes.type_decl_get_inst_norm_field_etypes meta ctx def
opt_variant_id generics
in
(* Initialize the expanded value *)
let fields = List.map (mk_bottom meta) field_types in
let av = VAdt { variant_id = opt_variant_id; field_values = fields } in
let ty = TAdt (TAdtId def_id, generics) in
{ value = av; ty }
let compute_expanded_bottom_tuple_value (meta : Meta.meta)
(field_types : ety list) : typed_value =
(* Generate the field values *)
let fields = List.map (mk_bottom meta) field_types in
let v = VAdt { variant_id = None; field_values = fields } in
let generics = TypesUtils.mk_generic_args [] field_types [] [] in
let ty = TAdt (TTuple, generics) in
{ value = v; ty }
(** Auxiliary helper to expand {!Bottom} values.
During compilation, rustc desaggregates the ADT initializations. The
consequence is that the following rust code:
{[
let x = Cons a b;
]}
Looks like this in MIR:
{[
(x as Cons).0 = a;
(x as Cons).1 = b;
set_discriminant(x, 0); // If [Cons] is the variant of index 0
]}
The consequence is that we may sometimes need to write fields to values
which are currently {!Bottom}. When doing this, we first expand the value
to, say, [Cons Bottom Bottom] (note that field projection contains information
about which variant we should project to, which is why we *can* set the
variant index when writing one of its fields).
*)
let expand_bottom_value_from_projection (meta : Meta.meta)
(access : access_kind) (p : place) (remaining_pes : int)
(pe : projection_elem) (ty : ety) (ctx : eval_ctx) : eval_ctx =
(* Debugging *)
log#ldebug
(lazy
("expand_bottom_value_from_projection:\n" ^ "pe: "
^ show_projection_elem pe ^ "\n" ^ "ty: " ^ show_ety ty));
(* Prepare the update: we need to take the proper prefix of the place
during whose evaluation we got stuck *)
let projection' =
fst
(Collections.List.split_at p.projection
(List.length p.projection - remaining_pes))
in
let p' = { p with projection = projection' } in
(* Compute the expanded value.
The type of the {!Bottom} value should be a tuple or an AD
Note that the projection element we got stuck at should be a
field projection, and gives the variant id if the {!Bottom} value
is an enumeration value.
Also, the expanded value should be the proper ADT variant or a tuple
with the proper arity, with all the fields initialized to {!Bottom}
*)
let nv =
match (pe, ty) with
(* "Regular" ADTs *)
| ( Field (ProjAdt (def_id, opt_variant_id), _),
TAdt (TAdtId def_id', generics) ) ->
sanity_check __FILE__ __LINE__ (def_id = def_id') meta;
compute_expanded_bottom_adt_value meta ctx def_id opt_variant_id
generics
(* Tuples *)
| ( Field (ProjTuple arity, _),
TAdt
(TTuple, { regions = []; types; const_generics = []; trait_refs = [] })
) ->
sanity_check __FILE__ __LINE__ (arity = List.length types) meta;
(* Generate the field values *)
compute_expanded_bottom_tuple_value meta types
| _ ->
craise __FILE__ __LINE__ meta
("Unreachable: " ^ show_projection_elem pe ^ ", " ^ show_ety ty)
in
(* Update the context by inserting the expanded value at the proper place *)
match try_write_place meta access p' nv ctx with
| Ok ctx -> ctx
| Error _ -> craise __FILE__ __LINE__ meta "Unreachable"
let rec update_ctx_along_read_place (config : config) (meta : Meta.meta)
(access : access_kind) (p : place) : cm_fun =
fun cf ctx ->
(* Attempt to read the place: if it fails, update the environment and retry *)
match try_read_place meta access p ctx with
| Ok _ -> cf ctx
| Error err ->
let cc =
match err with
| FailSharedLoan bids -> end_borrows config meta bids
| FailMutLoan bid -> end_borrow config meta bid
| FailReservedMutBorrow bid ->
promote_reserved_mut_borrow config meta bid
| FailSymbolic (i, sp) ->
(* Expand the symbolic value *)
let proj, _ =
Collections.List.split_at p.projection
(List.length p.projection - i)
in
let prefix = { p with projection = proj } in
expand_symbolic_value_no_branching config meta sp
(Some (Synth.mk_mplace meta prefix ctx))
| FailBottom (_, _, _) ->
(* We can't expand {!Bottom} values while reading them *)
craise __FILE__ __LINE__ meta "Found [Bottom] while reading a place"
| FailBorrow _ ->
craise __FILE__ __LINE__ meta "Could not read a borrow"
in
comp cc (update_ctx_along_read_place config meta access p) cf ctx
let rec update_ctx_along_write_place (config : config) (meta : Meta.meta)
(access : access_kind) (p : place) : cm_fun =
fun cf ctx ->
(* Attempt to *read* (yes, *read*: we check the access to the place, and
write to it later) the place: if it fails, update the environment and retry *)
match try_read_place meta access p ctx with
| Ok _ -> cf ctx
| Error err ->
(* Update the context *)
let cc =
match err with
| FailSharedLoan bids -> end_borrows config meta bids
| FailMutLoan bid -> end_borrow config meta bid
| FailReservedMutBorrow bid ->
promote_reserved_mut_borrow config meta bid
| FailSymbolic (_pe, sp) ->
(* Expand the symbolic value *)
expand_symbolic_value_no_branching config meta sp
(Some (Synth.mk_mplace meta p ctx))
| FailBottom (remaining_pes, pe, ty) ->
(* Expand the {!Bottom} value *)
fun cf ctx ->
let ctx =
expand_bottom_value_from_projection meta access p remaining_pes
pe ty ctx
in
cf ctx
| FailBorrow _ ->
craise __FILE__ __LINE__ meta "Could not write to a borrow"
in
(* Retry *)
comp cc (update_ctx_along_write_place config meta access p) cf ctx
(** Small utility used to break control-flow *)
exception UpdateCtx of cm_fun
let rec end_loans_at_place (config : config) (meta : Meta.meta)
(access : access_kind) (p : place) : cm_fun =
fun cf ctx ->
(* Iterator to explore a value and update the context whenever we find
* loans.
* We use exceptions to make it handy: whenever we update the
* context, we raise an exception wrapping the updated context.
* *)
let obj =
object
inherit [_] iter_typed_value as super
method! visit_borrow_content env bc =
match bc with
| VSharedBorrow _ | VMutBorrow (_, _) ->
(* Nothing special to do *) super#visit_borrow_content env bc
| VReservedMutBorrow bid ->
(* We need to activate reserved borrows *)
let cc = promote_reserved_mut_borrow config meta bid in
raise (UpdateCtx cc)
method! visit_loan_content env lc =
match lc with
| VSharedLoan (bids, v) -> (
(* End the loans if we need a modification access, otherwise dive into
the shared value *)
match access with
| Read -> super#visit_VSharedLoan env bids v
| Write | Move ->
let cc = end_borrows config meta bids in
raise (UpdateCtx cc))
| VMutLoan bid ->
(* We always need to end mutable borrows *)
let cc = end_borrow config meta bid in
raise (UpdateCtx cc)
end
in
(* First, retrieve the value *)
let v = read_place meta access p ctx in
(* Inspect the value and update the context while doing so.
If the context gets updated: perform a recursive call (many things
may have been updated in the context: we need to re-read the value
at place [p] - and this value may actually not be accessible
anymore...)
*)
try
obj#visit_typed_value () v;
(* No context update required: apply the continuation *)
cf ctx
with UpdateCtx cc ->
(* We need to update the context: compose the caugth continuation with
* a recursive call to reinspect the value *)
comp cc (end_loans_at_place config meta access p) cf ctx
let drop_outer_loans_at_lplace (config : config) (meta : Meta.meta) (p : place)
: cm_fun =
fun cf ctx ->
(* Move the current value in the place outside of this place and into
* a dummy variable *)
let access = Write in
let v = read_place meta access p ctx in
let ctx = write_place meta access p (mk_bottom meta v.ty) ctx in
let dummy_id = fresh_dummy_var_id () in
let ctx = ctx_push_dummy_var ctx dummy_id v in
(* Auxiliary function *)
let rec drop : cm_fun =
fun cf ctx ->
(* Read the value *)
let v = ctx_lookup_dummy_var meta ctx dummy_id in
(* Check if there are loans or borrows to end *)
let with_borrows = false in
match get_first_outer_loan_or_borrow_in_value with_borrows v with
| None ->
(* We are done: simply call the continuation *)
cf ctx
| Some c ->
(* There are: end them then retry *)
let cc =
match c with
| LoanContent (VSharedLoan (bids, _)) -> end_borrows config meta bids
| LoanContent (VMutLoan bid) -> end_borrow config meta bid
| BorrowContent _ -> craise __FILE__ __LINE__ meta "Unreachable"
in
(* Retry *)
comp cc drop cf ctx
in
(* Apply the drop function *)
let cc = drop in
(* Pop the temporary value and reinsert it *)
let cc =
comp cc (fun cf ctx ->
(* Pop *)
let ctx, v = ctx_remove_dummy_var meta ctx dummy_id in
(* Reinsert *)
let ctx = write_place meta access p v ctx in
(* Sanity check *)
sanity_check __FILE__ __LINE__ (not (outer_loans_in_value v)) meta;
(* Continue *)
cf ctx)
in
(* Continue *)
cc cf ctx
let prepare_lplace (config : config) (meta : Meta.meta) (p : place)
(cf : typed_value -> m_fun) : m_fun =
fun ctx ->
log#ldebug
(lazy
("prepare_lplace:" ^ "\n- p: " ^ place_to_string ctx p
^ "\n- Initial context:\n"
^ eval_ctx_to_string ~meta:(Some meta) ctx));
(* Access the place *)
let access = Write in
let cc = update_ctx_along_write_place config meta access p in
(* End the borrows and loans, starting with the borrows *)
let cc = comp cc (drop_outer_loans_at_lplace config meta p) in
(* Read the value and check it *)
let read_check cf : m_fun =
fun ctx ->
let v = read_place meta access p ctx in
(* Sanity checks *)
sanity_check __FILE__ __LINE__ (not (outer_loans_in_value v)) meta;
(* Continue *)
cf v ctx
in
(* Compose and apply the continuations *)
comp cc read_check cf ctx
|