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
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
919
920
921
922
923
924
925
926
927
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
1001
1002
1003
1004
1005
1006
1007
1008
1009
1010
1011
1012
1013
1014
1015
1016
1017
1018
1019
1020
1021
1022
1023
1024
1025
1026
1027
1028
1029
1030
1031
1032
1033
1034
1035
1036
1037
1038
1039
1040
1041
1042
1043
1044
1045
1046
1047
1048
1049
1050
1051
1052
1053
1054
1055
1056
1057
1058
1059
1060
1061
1062
1063
1064
1065
1066
1067
1068
1069
1070
1071
1072
1073
1074
1075
1076
1077
1078
1079
1080
1081
1082
1083
1084
1085
1086
1087
1088
1089
1090
1091
1092
1093
1094
1095
1096
1097
1098
1099
1100
1101
1102
1103
1104
1105
1106
1107
1108
1109
1110
1111
1112
1113
1114
1115
1116
1117
1118
1119
1120
1121
1122
1123
1124
1125
1126
1127
1128
1129
1130
1131
1132
1133
1134
1135
1136
1137
1138
1139
1140
1141
1142
1143
1144
1145
1146
1147
1148
1149
1150
1151
1152
1153
1154
1155
1156
1157
1158
1159
1160
1161
1162
1163
1164
1165
1166
1167
1168
1169
1170
1171
1172
1173
1174
1175
1176
1177
1178
1179
1180
1181
1182
1183
1184
1185
1186
1187
1188
1189
1190
1191
1192
1193
1194
1195
1196
1197
1198
1199
1200
1201
1202
1203
1204
1205
1206
1207
1208
1209
1210
1211
1212
1213
1214
1215
1216
1217
1218
1219
1220
1221
1222
1223
1224
1225
1226
1227
1228
1229
1230
1231
1232
1233
1234
1235
1236
1237
1238
1239
1240
1241
1242
1243
1244
1245
1246
1247
1248
1249
1250
1251
1252
1253
1254
1255
1256
1257
1258
1259
1260
1261
1262
1263
1264
1265
1266
1267
1268
1269
1270
1271
1272
1273
1274
1275
1276
1277
1278
1279
1280
1281
1282
1283
1284
1285
1286
1287
1288
1289
1290
1291
1292
1293
1294
1295
1296
1297
1298
1299
1300
1301
1302
1303
1304
1305
1306
1307
1308
1309
1310
1311
|
(************************************************************************)
(* * The Coq Proof Assistant / The Coq Development Team *)
(* v * INRIA, CNRS and contributors - Copyright 1999-2018 *)
(* <O___,, * (see CREDITS file for the list of authors) *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(* * (see LICENSE file for the text of the license) *)
(************************************************************************)
(** This files defines the basic mechanism of proofs: the [proofview]
type is the state which tactics manipulate (a global state for
existential variables, together with the list of goals), and the type
['a tactic] is the (abstract) type of tactics modifying the proof
state and returning a value of type ['a]. *)
open Pp
open Util
open Proofview_monad
open Context.Named.Declaration
(** Main state of tactics *)
type proofview = Proofview_monad.proofview
(* The first items in pairs below are proofs (under construction).
The second items in the pairs below are statements that are being proved. *)
type entry = (EConstr.constr * EConstr.types) list
(** Returns a stylised view of a proofview for use by, for instance,
ide-s. *)
(* spiwack: the type of [proofview] will change as we push more
refined functions to ide-s. This would be better than spawning a
new nearly identical function everytime. Hence the generic name. *)
(* In this version: returns the list of focused goals together with
the [evar_map] context. *)
let proofview p =
List.map drop_state p.comb , p.solution
let compact el ({ solution } as pv) =
let nf c = Evarutil.nf_evar solution c in
let nf0 c = EConstr.(to_constr solution (of_constr c)) in
let size = Evd.fold (fun _ _ i -> i+1) solution 0 in
let new_el = List.map (fun (t,ty) -> nf t, nf ty) el in
let pruned_solution = Evd.drop_all_defined solution in
let apply_subst_einfo _ ei =
Evd.({ ei with
evar_concl = nf ei.evar_concl;
evar_hyps = Environ.map_named_val nf0 ei.evar_hyps;
evar_candidates = Option.map (List.map nf) ei.evar_candidates }) in
let new_solution = Evd.raw_map_undefined apply_subst_einfo pruned_solution in
let new_size = Evd.fold (fun _ _ i -> i+1) new_solution 0 in
Feedback.msg_info (Pp.str (Printf.sprintf "Evars: %d -> %d\n" size new_size));
new_el, { pv with solution = new_solution; }
(** {6 Starting and querying a proof view} *)
type telescope =
| TNil of Evd.evar_map
| TCons of Environ.env * Evd.evar_map * EConstr.types * (Evd.evar_map -> EConstr.constr -> telescope)
let typeclass_resolvable = Evd.Store.field ()
let dependent_init =
(* Goals are created with a store which marks them as unresolvable
for type classes. *)
let store = Evd.Store.set Evd.Store.empty typeclass_resolvable () in
(* Goals don't have a source location. *)
let src = Loc.tag @@ Evar_kinds.GoalEvar in
(* Main routine *)
let rec aux = function
| TNil sigma -> [], { solution = sigma; comb = []; shelf = [] }
| TCons (env, sigma, typ, t) ->
let (sigma, econstr) = Evarutil.new_evar env sigma ~src ~store typ in
let (gl, _) = EConstr.destEvar sigma econstr in
let ret, { solution = sol; comb = comb } = aux (t sigma econstr) in
let entry = (econstr, typ) :: ret in
entry, { solution = sol; comb = with_empty_state gl :: comb; shelf = [] }
in
fun t ->
let entry, v = aux t in
(* The created goal are not to be shelved. *)
let solution = Evd.reset_future_goals v.solution in
entry, { v with solution }
let init =
let rec aux sigma = function
| [] -> TNil sigma
| (env,g)::l -> TCons (env,sigma,g,(fun sigma _ -> aux sigma l))
in
fun sigma l -> dependent_init (aux sigma l)
let initial_goals initial = initial
let finished = function
| {comb = []} -> true
| _ -> false
let return { solution=defs } = defs
let return_constr { solution = defs } c = Evarutil.nf_evar defs c
let partial_proof entry pv = CList.map (return_constr pv) (CList.map fst entry)
(** {6 Focusing commands} *)
(** A [focus_context] represents the part of the proof view which has
been removed by a focusing action, it can be used to unfocus later
on. *)
(* First component is a reverse list of the goals which come before
and second component is the list of the goals which go after (in
the expected order). *)
type focus_context = goal_with_state list * goal_with_state list
(** Returns a stylised view of a focus_context for use by, for
instance, ide-s. *)
(* spiwack: the type of [focus_context] will change as we push more
refined functions to ide-s. This would be better than spawning a
new nearly identical function everytime. Hence the generic name. *)
(* In this version: the goals in the context, as a "zipper" (the first
list is in reversed order). *)
let focus_context (left,right) =
(List.map drop_state left, List.map drop_state right)
(** This (internal) function extracts a sublist between two indices,
and returns this sublist together with its context: if it returns
[(a,(b,c))] then [a] is the sublist and [(rev b) @ a @ c] is the
original list. The focused list has lenght [j-i-1] and contains
the goals from number [i] to number [j] (both included) the first
goal of the list being numbered [1]. [focus_sublist i j l] raises
[IndexOutOfRange] if [i > length l], or [j > length l] or [j <
i]. *)
let focus_sublist i j l =
let (left,sub_right) = CList.goto (i-1) l in
let (sub, right) =
try CList.chop (j-i+1) sub_right
with Failure _ -> raise CList.IndexOutOfRange
in
(sub, (left,right))
(** Inverse operation to the previous one. *)
let unfocus_sublist (left,right) s =
CList.rev_append left (s@right)
(** [focus i j] focuses a proofview on the goals from index [i] to
index [j] (inclusive, goals are indexed from [1]). I.e. goals
number [i] to [j] become the only focused goals of the returned
proofview. It returns the focused proofview, and a context for
the focus stack. *)
let focus i j sp =
let (new_comb, (left, right)) = focus_sublist i j sp.comb in
( { sp with comb = new_comb } , (left, right) )
let cleared_alias evd g =
let evk = drop_state g in
let state = get_state g in
Option.map (fun g -> goal_with_state g state) (Evarutil.advance evd evk)
(** [undefined defs l] is the list of goals in [l] which are still
unsolved (after advancing cleared goals). Note that order matters. *)
let undefined_evars defs l =
List.fold_right (fun evk l ->
match Evarutil.advance defs evk with
| Some evk -> List.add_set Evar.equal evk l
| None -> l) l []
let goal_with_state_equal x y = Evar.equal (drop_state x) (drop_state y)
let undefined defs l =
List.fold_right (fun evk l ->
match cleared_alias defs evk with
| Some evk -> List.add_set goal_with_state_equal evk l
| None -> l) l []
(** Unfocuses a proofview with respect to a context. *)
let unfocus (left, right) sp =
{ sp with comb = undefined sp.solution (unfocus_sublist (left, right) sp.comb) }
let with_empty_state = Proofview_monad.with_empty_state
let drop_state = Proofview_monad.drop_state
let goal_with_state = Proofview_monad.goal_with_state
(** {6 The tactic monad} *)
(** - Tactics are objects which apply a transformation to all the
subgoals of the current view at the same time. By opposition to
the old vision of applying it to a single goal. It allows tactics
such as [shelve_unifiable], tactics to reorder the focused goals,
or global automation tactic for dependent subgoals (instantiating
an evar has influences on the other goals of the proof in
progress, not being able to take that into account causes the
current eauto tactic to fail on some instances where it could
succeed). Another benefit is that it is possible to write tactics
that can be executed even if there are no focused goals.
- Tactics form a monad ['a tactic], in a sense a tactic can be
seen as a function (without argument) which returns a value of
type 'a and modifies the environment (in our case: the view).
Tactics of course have arguments, but these are given at the
meta-level as OCaml functions. Most tactics in the sense we are
used to return [()], that is no really interesting values. But
some might pass information around. The tactics seen in Coq's
Ltac are (for now at least) only [unit tactic], the return values
are kept for the OCaml toolkit. The operation or the monad are
[Proofview.tclUNIT] (which is the "return" of the tactic monad)
[Proofview.tclBIND] (which is the "bind") and [Proofview.tclTHEN]
(which is a specialized bind on unit-returning tactics).
- Tactics have support for full-backtracking. Tactics can be seen
having multiple success: if after returning the first success a
failure is encountered, the tactic can backtrack and use a second
success if available. The state is backtracked to its previous
value, except the non-logical state defined in the {!NonLogical}
module below.
*)
(* spiwack: as far as I'm aware this doesn't really relate to
F. Kirchner and C. Muñoz. *)
module Proof = Logical
(** type of tactics:
tactics can
- access the environment,
- report unsafe status, shelved goals and given up goals
- access and change the current [proofview]
- backtrack on previous changes of the proofview *)
type +'a tactic = 'a Proof.t
(** Applies a tactic to the current proofview. *)
let apply env t sp =
let open Logic_monad in
let ans = Proof.repr (Proof.run t false (sp,env)) in
let ans = Logic_monad.NonLogical.run ans in
match ans with
| Nil (e, info) -> iraise (TacticFailure e, info)
| Cons ((r, (state, _), status, info), _) ->
let (status, gaveup) = status in
let status = (status, state.shelf, gaveup) in
let state = { state with shelf = [] } in
r, state, status, Trace.to_tree info
(** {7 Monadic primitives} *)
(** Unit of the tactic monad. *)
let tclUNIT = Proof.return
(** Bind operation of the tactic monad. *)
let tclBIND = Proof.(>>=)
(** Interpretes the ";" (semicolon) of Ltac. As a monadic operation,
it's a specialized "bind". *)
let tclTHEN = Proof.(>>)
(** [tclIGNORE t] has the same operational content as [t], but drops
the returned value. *)
let tclIGNORE = Proof.ignore
module Monad = Proof
(** {7 Failure and backtracking} *)
(** [tclZERO e] fails with exception [e]. It has no success. *)
let tclZERO ?info e =
let info = match info with
| None -> Exninfo.null
| Some info -> info
in
Proof.zero (e, info)
(** [tclOR t1 t2] behaves like [t1] as long as [t1] succeeds. Whenever
the successes of [t1] have been depleted and it failed with [e],
then it behaves as [t2 e]. In other words, [tclOR] inserts a
backtracking point. *)
let tclOR = Proof.plus
(** [tclORELSE t1 t2] is equal to [t1] if [t1] has at least one
success or [t2 e] if [t1] fails with [e]. It is analogous to
[try/with] handler of exception in that it is not a backtracking
point. *)
let tclORELSE t1 t2 =
let open Logic_monad in
let open Proof in
split t1 >>= function
| Nil e -> t2 e
| Cons (a,t1') -> plus (return a) t1'
(** [tclIFCATCH a s f] is a generalisation of {!tclORELSE}: if [a]
succeeds at least once then it behaves as [tclBIND a s] otherwise,
if [a] fails with [e], then it behaves as [f e]. *)
let tclIFCATCH a s f =
let open Logic_monad in
let open Proof in
split a >>= function
| Nil e -> f e
| Cons (x,a') -> plus (s x) (fun e -> (a' e) >>= fun x' -> (s x'))
(** [tclONCE t] behave like [t] except it has at most one success:
[tclONCE t] stops after the first success of [t]. If [t] fails
with [e], [tclONCE t] also fails with [e]. *)
let tclONCE = Proof.once
exception MoreThanOneSuccess
let _ = CErrors.register_handler begin function
| MoreThanOneSuccess -> CErrors.user_err Pp.(str "This tactic has more than one success.")
| _ -> raise CErrors.Unhandled
end
(** [tclEXACTLY_ONCE e t] succeeds as [t] if [t] has exactly one
success. Otherwise it fails. The tactic [t] is run until its first
success, then a failure with exception [e] is simulated. It [t]
yields another success, then [tclEXACTLY_ONCE e t] fails with
[MoreThanOneSuccess] (it is a user error). Otherwise,
[tclEXACTLY_ONCE e t] succeeds with the first success of
[t]. Notice that the choice of [e] is relevant, as the presence of
further successes may depend on [e] (see {!tclOR}). *)
let tclEXACTLY_ONCE e t =
let open Logic_monad in
let open Proof in
split t >>= function
| Nil (e, info) -> tclZERO ~info e
| Cons (x,k) ->
Proof.split (k (e, Exninfo.null)) >>= function
| Nil _ -> tclUNIT x
| _ -> tclZERO MoreThanOneSuccess
(** [tclCASE t] wraps the {!Proofview_monad.Logical.split} primitive. *)
type 'a case =
| Fail of iexn
| Next of 'a * (iexn -> 'a tactic)
let tclCASE t =
let open Logic_monad in
let map = function
| Nil e -> Fail e
| Cons (x, t) -> Next (x, t)
in
Proof.map map (Proof.split t)
let tclBREAK = Proof.break
(** {7 Focusing tactics} *)
exception NoSuchGoals of int
(* This hook returns a string to be appended to the usual message.
Primarily used to add a suggestion about the right bullet to use to
focus the next goal, if applicable. *)
let nosuchgoals_hook:(int -> Pp.t) ref = ref (fun n -> mt ())
let set_nosuchgoals_hook f = nosuchgoals_hook := f
(* This uses the hook above *)
let _ = CErrors.register_handler begin function
| NoSuchGoals n ->
let suffix = !nosuchgoals_hook n in
CErrors.user_err
(str "No such " ++ str (String.plural n "goal") ++ str "." ++
pr_non_empty_arg (fun x -> x) suffix)
| _ -> raise CErrors.Unhandled
end
(** [tclFOCUS_gen nosuchgoal i j t] applies [t] in a context where
only the goals numbered [i] to [j] are focused (the rest of the goals
is restored at the end of the tactic). If the range [i]-[j] is not
valid, then it [tclFOCUS_gen nosuchgoal i j t] is [nosuchgoal]. *)
let tclFOCUS_gen nosuchgoal i j t =
let open Proof in
Pv.get >>= fun initial ->
try
let (focused,context) = focus i j initial in
Pv.set focused >>
t >>= fun result ->
Pv.modify (fun next -> unfocus context next) >>
return result
with CList.IndexOutOfRange -> nosuchgoal
let tclFOCUS i j t = tclFOCUS_gen (tclZERO (NoSuchGoals (j+1-i))) i j t
let tclTRYFOCUS i j t = tclFOCUS_gen (tclUNIT ()) i j t
let tclFOCUSLIST l t =
let open Proof in
Comb.get >>= fun comb ->
let n = CList.length comb in
(* First, remove empty intervals, and bound the intervals to the number
of goals. *)
let sanitize (i, j) =
if i > j then None
else if i > n then None
else if j < 1 then None
else Some ((max i 1), (min j n))
in
let l = CList.map_filter sanitize l in
match l with
| [] -> tclZERO (NoSuchGoals 0)
| (mi, _) :: _ ->
(* Get the left-most goal to focus. This goal won't move, and we
will then place all the other goals to focus to the right. *)
let mi = CList.fold_left (fun m (i, _) -> min m i) mi l in
(* [CList.goto] returns a zipper, so that
[(rev left) @ sub_right = comb]. *)
let left, sub_right = CList.goto (mi-1) comb in
let p x _ = CList.exists (fun (i, j) -> i <= x + mi && x + mi <= j) l in
let sub, right = CList.partitioni p sub_right in
let mj = mi - 1 + CList.length sub in
Comb.set (CList.rev_append left (sub @ right)) >>
tclFOCUS mi mj t
(** Like {!tclFOCUS} but selects a single goal by name. *)
let tclFOCUSID id t =
let open Proof in
Pv.get >>= fun initial ->
try
let ev = Evd.evar_key id initial.solution in
try
let comb = CList.map drop_state initial.comb in
let n = CList.index Evar.equal ev comb in
(* goal is already under focus *)
let (focused,context) = focus n n initial in
Pv.set focused >>
t >>= fun result ->
Pv.modify (fun next -> unfocus context next) >>
return result
with Not_found ->
(* otherwise, save current focus and work purely on the shelve *)
Comb.set [with_empty_state ev] >>
t >>= fun result ->
Comb.set initial.comb >>
return result
with Not_found -> tclZERO (NoSuchGoals 1)
(** {7 Dispatching on goals} *)
exception SizeMismatch of int*int
let _ = CErrors.register_handler begin function
| SizeMismatch (i,j) ->
let open Pp in
let errmsg =
str"Incorrect number of goals" ++ spc() ++
str"(expected "++int i++str(String.plural i " tactic") ++ str", was given "++ int j++str")."
in
CErrors.user_err errmsg
| _ -> raise CErrors.Unhandled
end
(** A variant of [Monad.List.iter] where we iter over the focused list
of goals. The argument tactic is executed in a focus comprising
only of the current goal, a goal which has been solved by side
effect is skipped. The generated subgoals are concatenated in
order. *)
let iter_goal i =
let open Proof in
Comb.get >>= fun initial ->
Proof.List.fold_left begin fun (subgoals as cur) goal ->
Solution.get >>= fun step ->
match cleared_alias step goal with
| None -> return cur
| Some goal ->
Comb.set [goal] >>
i goal >>
Proof.map (fun comb -> comb :: subgoals) Comb.get
end [] initial >>= fun subgoals ->
Solution.get >>= fun evd ->
Comb.set CList.(undefined evd (flatten (rev subgoals)))
(** List iter but allocates a list of results *)
let map_goal i =
let rev = List.rev in (* hem... Proof masks List... *)
let open Proof in
Comb.get >>= fun initial ->
Proof.List.fold_left begin fun (acc, subgoals as cur) goal ->
Solution.get >>= fun step ->
match cleared_alias step goal with
| None -> return cur
| Some goal ->
Comb.set [goal] >>
i goal >>= fun res ->
Proof.map (fun comb -> comb :: subgoals) Comb.get >>= fun x ->
return (res :: acc, x)
end ([],[]) initial >>= fun (results_rev, subgoals) ->
Solution.get >>= fun evd ->
Comb.set CList.(undefined evd (flatten (rev subgoals))) >>
return (rev results_rev)
(** A variant of [Monad.List.fold_left2] where the first list is the
list of focused goals. The argument tactic is executed in a focus
comprising only of the current goal, a goal which has been solved
by side effect is skipped. The generated subgoals are concatenated
in order. *)
let fold_left2_goal i s l =
let open Proof in
Pv.get >>= fun initial ->
let err =
return () >>= fun () -> (* Delay the computation of list lengths. *)
tclZERO (SizeMismatch (CList.length initial.comb,CList.length l))
in
Proof.List.fold_left2 err begin fun ((r,subgoals) as cur) goal a ->
Solution.get >>= fun step ->
match cleared_alias step goal with
| None -> return cur
| Some goal ->
Comb.set [goal] >>
i goal a r >>= fun r ->
Proof.map (fun comb -> (r, comb :: subgoals)) Comb.get
end (s,[]) initial.comb l >>= fun (r,subgoals) ->
Solution.get >>= fun evd ->
Comb.set CList.(undefined evd (flatten (rev subgoals))) >>
return r
(** Dispatch tacticals are used to apply a different tactic to each
goal under focus. They come in two flavours: [tclDISPATCH] takes a
list of [unit tactic]-s and build a [unit tactic]. [tclDISPATCHL]
takes a list of ['a tactic] and returns an ['a list tactic].
They both work by applying each of the tactic in a focus
restricted to the corresponding goal (starting with the first
goal). In the case of [tclDISPATCHL], the tactic returns a list of
the same size as the argument list (of tactics), each element
being the result of the tactic executed in the corresponding goal.
When the length of the tactic list is not the number of goal,
raises [SizeMismatch (g,t)] where [g] is the number of available
goals, and [t] the number of tactics passed.
[tclDISPATCHGEN join tacs] generalises both functions as the
successive results of [tacs] are stored in reverse order in a
list, and [join] is used to convert the result into the expected
form. *)
let tclDISPATCHGEN0 join tacs =
match tacs with
| [] ->
begin
let open Proof in
Comb.get >>= function
| [] -> tclUNIT (join [])
| comb -> tclZERO (SizeMismatch (CList.length comb,0))
end
| [tac] ->
begin
let open Proof in
Pv.get >>= function
| { comb=[goal] ; solution } ->
begin match cleared_alias solution goal with
| None -> tclUNIT (join [])
| Some _ -> Proof.map (fun res -> join [res]) tac
end
| {comb} -> tclZERO (SizeMismatch(CList.length comb,1))
end
| _ ->
let iter _ t cur = Proof.map (fun y -> y :: cur) t in
let ans = fold_left2_goal iter [] tacs in
Proof.map join ans
let tclDISPATCHGEN join tacs =
let branch t = InfoL.tag (Info.DBranch) t in
let tacs = CList.map branch tacs in
InfoL.tag (Info.Dispatch) (tclDISPATCHGEN0 join tacs)
let tclDISPATCH tacs = tclDISPATCHGEN Pervasives.ignore tacs
let tclDISPATCHL tacs = tclDISPATCHGEN CList.rev tacs
(** [extend_to_list startxs rx endxs l] builds a list
[startxs @ [rx,...,rx] @ endxs] of the same length as [l]. Raises
[SizeMismatch] if [startxs @ endxs] is already longer than [l]. *)
let extend_to_list startxs rx endxs l =
(* spiwack: I use [l] essentially as a natural number *)
let rec duplicate acc = function
| [] -> acc
| _::rest -> duplicate (rx::acc) rest
in
let rec tail to_match rest =
match rest, to_match with
| [] , _::_ -> raise (SizeMismatch(0,0)) (* placeholder *)
| _::rest , _::to_match -> tail to_match rest
| _ , [] -> duplicate endxs rest
in
let rec copy pref rest =
match rest,pref with
| [] , _::_ -> raise (SizeMismatch(0,0)) (* placeholder *)
| _::rest, a::pref -> a::(copy pref rest)
| _ , [] -> tail endxs rest
in
copy startxs l
(** [tclEXTEND b r e] is a variant of {!tclDISPATCH}, where the [r]
tactic is "repeated" enough time such that every goal has a tactic
assigned to it ([b] is the list of tactics applied to the first
goals, [e] to the last goals, and [r] is applied to every goal in
between). *)
let tclEXTEND tacs1 rtac tacs2 =
let open Proof in
Comb.get >>= fun comb ->
try
let tacs = extend_to_list tacs1 rtac tacs2 comb in
tclDISPATCH tacs
with SizeMismatch _ ->
tclZERO (SizeMismatch(
CList.length comb,
(CList.length tacs1)+(CList.length tacs2)))
(* spiwack: failure occurs only when the number of goals is too
small. Hence we can assume that [rtac] is replicated 0 times for
any error message. *)
(** [tclEXTEND [] tac []]. *)
let tclINDEPENDENT tac =
let open Proof in
Pv.get >>= fun initial ->
match initial.comb with
| [] -> tclUNIT ()
| [_] -> tac
| _ ->
let tac = InfoL.tag (Info.DBranch) tac in
InfoL.tag (Info.Dispatch) (iter_goal (fun _ -> tac))
let tclINDEPENDENTL tac =
let open Proof in
Pv.get >>= fun initial ->
match initial.comb with
| [] -> tclUNIT []
| [_] -> tac >>= fun x -> return [x]
| _ ->
let tac = InfoL.tag (Info.DBranch) tac in
InfoL.tag (Info.Dispatch) (map_goal (fun _ -> tac))
(** {7 Goal manipulation} *)
(** Shelves all the goals under focus. *)
let shelve =
let open Proof in
Comb.get >>= fun initial ->
Comb.set [] >>
InfoL.leaf (Info.Tactic (fun () -> Pp.str"shelve")) >>
Shelf.modify (fun gls -> gls @ CList.map drop_state initial)
let shelve_goals l =
let open Proof in
Comb.get >>= fun initial ->
let comb = CList.filter (fun g -> not (CList.mem (drop_state g) l)) initial in
Comb.set comb >>
InfoL.leaf (Info.Tactic (fun () -> Pp.str"shelve_goals")) >>
Shelf.modify (fun gls -> gls @ l)
(** [depends_on sigma src tgt] checks whether the goal [src] appears
as an existential variable in the definition of the goal [tgt] in
[sigma]. *)
let depends_on sigma src tgt =
let evi = Evd.find sigma tgt in
Evar.Set.mem src (Evd.evars_of_filtered_evar_info (Evarutil.nf_evar_info sigma evi))
let unifiable_delayed g l =
CList.exists (fun (tgt, lazy evs) -> not (Evar.equal g tgt) && Evar.Set.mem g evs) l
let free_evars sigma l =
let cache = Evarutil.create_undefined_evars_cache () in
let map ev =
(** Computes the set of evars appearing in the hypotheses, the conclusion or
the body of the evar_info [evi]. Note: since we want to use it on goals,
the body is actually supposed to be empty. *)
let evi = Evd.find sigma ev in
let fevs = lazy (Evarutil.filtered_undefined_evars_of_evar_info ~cache sigma evi) in
(ev, fevs)
in
List.map map l
let free_evars_with_state sigma l =
let cache = Evarutil.create_undefined_evars_cache () in
let map ev =
(** Computes the set of evars appearing in the hypotheses, the conclusion or
the body of the evar_info [evi]. Note: since we want to use it on goals,
the body is actually supposed to be empty. *)
let ev = drop_state ev in
let evi = Evd.find sigma ev in
let fevs = lazy (Evarutil.filtered_undefined_evars_of_evar_info ~cache sigma evi) in
(ev, fevs)
in
List.map map l
(** [unifiable sigma g l] checks whether [g] appears in another
subgoal of [l]. The list [l] may contain [g], but it does not
affect the result. *)
let unifiable_delayed_with_state sigma g l =
let g = drop_state g in
unifiable_delayed g l
let unifiable sigma g l =
let l = free_evars sigma l in
unifiable_delayed g l
(** [partition_unifiable sigma l] partitions [l] into a pair [(u,n)]
where [u] is composed of the unifiable goals, i.e. the goals on
whose definition other goals of [l] depend, and [n] are the
non-unifiable goals. *)
let partition_unifiable sigma l =
let fevs = free_evars_with_state sigma l in
CList.partition (fun g -> unifiable_delayed_with_state sigma g fevs) l
(** Shelves the unifiable goals under focus, i.e. the goals which
appear in other goals under focus (the unfocused goals are not
considered). *)
let shelve_unifiable_informative =
let open Proof in
Pv.get >>= fun initial ->
let (u,n) = partition_unifiable initial.solution initial.comb in
Comb.set n >>
InfoL.leaf (Info.Tactic (fun () -> Pp.str"shelve_unifiable")) >>
let u = CList.map drop_state u in
Shelf.modify (fun gls -> gls @ u) >>
tclUNIT u
let shelve_unifiable =
let open Proof in
shelve_unifiable_informative >>= fun _ -> tclUNIT ()
(** [guard_no_unifiable] returns the list of unifiable goals if some
goals are unifiable (see {!shelve_unifiable}) in the current focus. *)
let guard_no_unifiable =
let open Proof in
Pv.get >>= fun initial ->
let (u,n) = partition_unifiable initial.solution initial.comb in
match u with
| [] -> tclUNIT None
| gls ->
let l = CList.map (fun g -> Evd.dependent_evar_ident (drop_state g) initial.solution) gls in
let l = CList.map (fun id -> Names.Name id) l in
tclUNIT (Some l)
(** [unshelve l p] adds all the goals in [l] at the end of the focused
goals of p *)
let unshelve l p =
let l = List.map with_empty_state l in
(* advance the goals in case of clear *)
let l = undefined p.solution l in
{ p with comb = p.comb@l }
let mark_in_evm ~goal evd content =
let info = Evd.find evd content in
let info =
if goal then
{ info with Evd.evar_source = match info.Evd.evar_source with
(* Two kinds for goal evars:
- GoalEvar (morally not dependent)
- VarInstance (morally dependent of some name).
This is a heuristic for naming these evars. *)
| loc, (Evar_kinds.QuestionMark (_,Names.Name id) |
Evar_kinds.ImplicitArg (_,(_,Some id),_)) -> loc, Evar_kinds.VarInstance id
| _, (Evar_kinds.VarInstance _ | Evar_kinds.GoalEvar) as x -> x
| loc,_ -> loc,Evar_kinds.GoalEvar }
else info
in
let info = match Evd.Store.get info.Evd.evar_extra typeclass_resolvable with
| None -> { info with Evd.evar_extra = Evd.Store.set info.Evd.evar_extra typeclass_resolvable () }
| Some () -> info
in
Evd.add evd content info
let with_shelf tac =
let open Proof in
Pv.get >>= fun pv ->
let { shelf; solution } = pv in
Pv.set { pv with shelf = []; solution = Evd.reset_future_goals solution } >>
tac >>= fun ans ->
Pv.get >>= fun npv ->
let { shelf = gls; solution = sigma } = npv in
(* The pending future goals are necessarily coming from V82.tactic *)
(* and thus considered as to shelve, as in Proof.run_tactic *)
let gls' = Evd.future_goals sigma in
let fgoals = Evd.save_future_goals solution in
let sigma = Evd.restore_future_goals sigma fgoals in
(* Ensure we mark and return only unsolved goals *)
let gls' = undefined_evars sigma (CList.rev_append gls' gls) in
let sigma = CList.fold_left (mark_in_evm ~goal:false) sigma gls' in
let npv = { npv with shelf; solution = sigma } in
Pv.set npv >> tclUNIT (gls', ans)
(** [goodmod p m] computes the representative of [p] modulo [m] in the
interval [[0,m-1]].*)
let goodmod p m =
if m = 0 then 0 else
let p' = p mod m in
(* if [n] is negative [n mod l] is negative of absolute value less
than [l], so [(n mod l)+l] is the representative of [n] in the
interval [[0,l-1]].*)
if p' < 0 then p'+m else p'
let cycle n =
let open Proof in
InfoL.leaf (Info.Tactic (fun () -> Pp.(str"cycle "++int n))) >>
Comb.modify begin fun initial ->
let l = CList.length initial in
let n' = goodmod n l in
let (front,rear) = CList.chop n' initial in
rear@front
end
let swap i j =
let open Proof in
InfoL.leaf (Info.Tactic (fun () -> Pp.(hov 2 (str"swap"++spc()++int i++spc()++int j)))) >>
Comb.modify begin fun initial ->
let l = CList.length initial in
let i = if i>0 then i-1 else i and j = if j>0 then j-1 else j in
let i = goodmod i l and j = goodmod j l in
CList.map_i begin fun k x ->
match k with
| k when Int.equal k i -> CList.nth initial j
| k when Int.equal k j -> CList.nth initial i
| _ -> x
end 0 initial
end
let revgoals =
let open Proof in
InfoL.leaf (Info.Tactic (fun () -> Pp.str"revgoals")) >>
Comb.modify CList.rev
let numgoals =
let open Proof in
Comb.get >>= fun comb ->
return (CList.length comb)
(** {7 Access primitives} *)
let tclEVARMAP = Solution.get
let tclENV = Env.get
(** {7 Put-like primitives} *)
let emit_side_effects eff x =
{ x with solution = Evd.emit_side_effects eff x.solution }
let tclEFFECTS eff =
let open Proof in
return () >>= fun () -> (* The Global.env should be taken at exec time *)
Env.set (Global.env ()) >>
Pv.modify (fun initial -> emit_side_effects eff initial)
let mark_as_unsafe = Status.put false
(** Gives up on the goal under focus. Reports an unsafe status. Proofs
with given up goals cannot be closed. *)
let give_up =
let open Proof in
Comb.get >>= fun initial ->
Comb.set [] >>
mark_as_unsafe >>
InfoL.leaf (Info.Tactic (fun () -> Pp.str"give_up")) >>
Giveup.put (CList.map drop_state initial)
(** {7 Control primitives} *)
module Progress = struct
let eq_constr = Evarutil.eq_constr_univs_test
(** equality function on hypothesis contexts *)
let eq_named_context_val sigma1 sigma2 ctx1 ctx2 =
let c1 = EConstr.named_context_of_val ctx1 and c2 = EConstr.named_context_of_val ctx2 in
let eq_named_declaration d1 d2 =
match d1, d2 with
| LocalAssum (i1,t1), LocalAssum (i2,t2) ->
Names.Id.equal i1 i2 && eq_constr sigma1 sigma2 t1 t2
| LocalDef (i1,c1,t1), LocalDef (i2,c2,t2) ->
Names.Id.equal i1 i2 && eq_constr sigma1 sigma2 c1 c2
&& eq_constr sigma1 sigma2 t1 t2
| _ ->
false
in List.equal eq_named_declaration c1 c2
let eq_evar_body sigma1 sigma2 b1 b2 =
let open Evd in
match b1, b2 with
| Evar_empty, Evar_empty -> true
| Evar_defined t1, Evar_defined t2 -> eq_constr sigma1 sigma2 t1 t2
| _ -> false
let eq_evar_info sigma1 sigma2 ei1 ei2 =
let open Evd in
eq_constr sigma1 sigma2 ei1.evar_concl ei2.evar_concl &&
eq_named_context_val sigma1 sigma2 (ei1.evar_hyps) (ei2.evar_hyps) &&
eq_evar_body sigma1 sigma2 ei1.evar_body ei2.evar_body
(** Equality function on goals *)
let goal_equal evars1 gl1 evars2 gl2 =
let evi1 = Evd.find evars1 (drop_state gl1) in
let evi2 = Evd.find evars2 (drop_state gl2) in
eq_evar_info evars1 evars2 evi1 evi2
end
let tclPROGRESS t =
let open Proof in
Pv.get >>= fun initial ->
t >>= fun res ->
Pv.get >>= fun final ->
(* [*_test] test absence of progress. [quick_test] is approximate
whereas [exhaustive_test] is complete. *)
let quick_test =
initial.solution == final.solution && initial.comb == final.comb
in
let test =
quick_test ||
Util.List.for_all2eq begin fun i f ->
Progress.goal_equal initial.solution i final.solution f
end initial.comb final.comb
in
if not test then
tclUNIT res
else
tclZERO (CErrors.UserError (Some "Proofview.tclPROGRESS" , Pp.str"Failed to progress."))
exception Timeout
let _ = CErrors.register_handler begin function
| Timeout -> CErrors.user_err ~hdr:"Proofview.tclTIMEOUT" (Pp.str"Tactic timeout!")
| _ -> Pervasives.raise CErrors.Unhandled
end
let tclTIMEOUT n t =
let open Proof in
(* spiwack: as one of the monad is a continuation passing monad, it
doesn't force the computation to be threaded inside the underlying
(IO) monad. Hence I force it myself by asking for the evaluation of
a dummy value first, lest [timeout] be called when everything has
already been computed. *)
let t = Proof.lift (Logic_monad.NonLogical.return ()) >> t in
Proof.get >>= fun initial ->
Proof.current >>= fun envvar ->
Proof.lift begin
Logic_monad.NonLogical.catch
begin
let open Logic_monad.NonLogical in
timeout n (Proof.repr (Proof.run t envvar initial)) >>= fun r ->
match r with
| Logic_monad.Nil e -> return (Util.Inr e)
| Logic_monad.Cons (r, _) -> return (Util.Inl r)
end
begin let open Logic_monad.NonLogical in function (e, info) ->
match e with
| Logic_monad.Timeout -> return (Util.Inr (Timeout, info))
| Logic_monad.TacticFailure e ->
return (Util.Inr (e, info))
| e -> Logic_monad.NonLogical.raise ~info e
end
end >>= function
| Util.Inl (res,s,m,i) ->
Proof.set s >>
Proof.put m >>
Proof.update (fun _ -> i) >>
return res
| Util.Inr (e, info) -> tclZERO ~info e
let tclTIME s t =
let pr_time t1 t2 n msg =
let msg =
if n = 0 then
str msg
else
str (msg ^ " after ") ++ int n ++ str (String.plural n " backtracking")
in
Feedback.msg_info(str "Tactic call" ++ pr_opt str s ++ str " ran for " ++
System.fmt_time_difference t1 t2 ++ str " " ++ surround msg) in
let rec aux n t =
let open Proof in
tclUNIT () >>= fun () ->
let tstart = System.get_time() in
Proof.split t >>= let open Logic_monad in function
| Nil (e, info) ->
begin
let tend = System.get_time() in
pr_time tstart tend n "failure";
tclZERO ~info e
end
| Cons (x,k) ->
let tend = System.get_time() in
pr_time tstart tend n "success";
tclOR (tclUNIT x) (fun e -> aux (n+1) (k e))
in aux 0 t
(** {7 Unsafe primitives} *)
module Unsafe = struct
let tclEVARS evd =
Pv.modify (fun ps -> { ps with solution = evd })
let tclNEWGOALS gls =
Pv.modify begin fun step ->
let gls = undefined step.solution gls in
{ step with comb = step.comb @ gls }
end
let tclSETENV = Env.set
let tclGETGOALS = Comb.get
let tclSETGOALS = Comb.set
let tclGETSHELF = Shelf.get
let tclSETSHELF = Shelf.set
let tclPUTSHELF to_shelve =
tclBIND tclGETSHELF (fun shelf -> tclSETSHELF (to_shelve@shelf))
let tclPUTGIVENUP = Giveup.put
let tclEVARSADVANCE evd =
Pv.modify (fun ps -> { ps with solution = evd; comb = undefined evd ps.comb })
let tclEVARUNIVCONTEXT ctx =
Pv.modify (fun ps -> { ps with solution = Evd.set_universe_context ps.solution ctx })
let reset_future_goals p =
{ p with solution = Evd.reset_future_goals p.solution }
let mark_as_goal evd content =
mark_in_evm ~goal:true evd content
let advance = Evarutil.advance
let undefined = undefined
let mark_as_unresolvable p gl =
{ p with solution = mark_in_evm ~goal:false p.solution gl }
let typeclass_resolvable = typeclass_resolvable
end
module UnsafeRepr = Proof.Unsafe
let (>>=) = tclBIND
(** {6 Goal-dependent tactics} *)
let goal_env evars gl =
let evi = Evd.find evars gl in
Evd.evar_filtered_env evi
let goal_nf_evar sigma gl =
let evi = Evd.find sigma gl in
let evi = Evarutil.nf_evar_info sigma evi in
let sigma = Evd.add sigma gl evi in
(gl, sigma)
let goal_extra evars gl =
let evi = Evd.find evars gl in
evi.Evd.evar_extra
let catchable_exception = function
| Logic_monad.Exception _ -> false
| e -> CErrors.noncritical e
module Goal = struct
type t = {
env : Environ.env;
sigma : Evd.evar_map;
concl : EConstr.constr ;
state : StateStore.t;
self : Evar.t ; (* for compatibility with old-style definitions *)
}
let print { sigma; self } = { Evd.it = self; sigma }
let state { state=state } = state
let env {env} = env
let sigma {sigma} = sigma
let hyps {env} = EConstr.named_context env
let concl {concl} = concl
let extra {sigma; self} = goal_extra sigma self
let gmake_with info env sigma goal state =
{ env = Environ.reset_with_named_context (Evd.evar_filtered_hyps info) env ;
sigma = sigma ;
concl = Evd.evar_concl info;
state = state ;
self = goal }
let nf_gmake env sigma goal =
let state = get_state goal in
let goal = drop_state goal in
let info = Evarutil.nf_evar_info sigma (Evd.find sigma goal) in
let sigma = Evd.add sigma goal info in
gmake_with info env sigma goal state , sigma
let nf_enter f =
InfoL.tag (Info.Dispatch) begin
iter_goal begin fun goal ->
tclENV >>= fun env ->
tclEVARMAP >>= fun sigma ->
try
let (gl, sigma) = nf_gmake env sigma goal in
tclTHEN (Unsafe.tclEVARS sigma) (InfoL.tag (Info.DBranch) (f gl))
with e when catchable_exception e ->
let (e, info) = CErrors.push e in
tclZERO ~info e
end
end
let normalize { self; state } =
Env.get >>= fun env ->
tclEVARMAP >>= fun sigma ->
let (gl,sigma) = nf_gmake env sigma (goal_with_state self state) in
tclTHEN (Unsafe.tclEVARS sigma) (tclUNIT gl)
let gmake env sigma goal =
let state = get_state goal in
let goal = drop_state goal in
let info = Evd.find sigma goal in
gmake_with info env sigma goal state
let enter f =
let f gl = InfoL.tag (Info.DBranch) (f gl) in
InfoL.tag (Info.Dispatch) begin
iter_goal begin fun goal ->
Env.get >>= fun env ->
tclEVARMAP >>= fun sigma ->
try f (gmake env sigma goal)
with e when catchable_exception e ->
let (e, info) = CErrors.push e in
tclZERO ~info e
end
end
let enter_one ?(__LOC__=__LOC__) f =
let open Proof in
Comb.get >>= function
| [goal] -> begin
Env.get >>= fun env ->
tclEVARMAP >>= fun sigma ->
try f (gmake env sigma goal)
with e when catchable_exception e ->
let (e, info) = CErrors.push e in
tclZERO ~info e
end
| _ ->
CErrors.anomaly Pp.(str __LOC__ ++ str " enter_one")
let goals =
Pv.get >>= fun step ->
let sigma = step.solution in
let map goal =
match cleared_alias sigma goal with
| None -> None (** ppedrot: Is this check really necessary? *)
| Some goal ->
let gl =
Env.get >>= fun env ->
tclEVARMAP >>= fun sigma ->
tclUNIT (gmake env sigma goal)
in
Some gl
in
tclUNIT (CList.map_filter map step.comb)
let unsolved { self=self } =
tclEVARMAP >>= fun sigma ->
tclUNIT (not (Option.is_empty (Evarutil.advance sigma self)))
(* compatibility *)
let goal { self=self } = self
end
(** {6 Trace} *)
module Trace = struct
let record_info_trace = InfoL.record_trace
let log m = InfoL.leaf (Info.Msg m)
let name_tactic m t = InfoL.tag (Info.Tactic m) t
let pr_info ?(lvl=0) info =
assert (lvl >= 0);
Info.(print (collapse lvl info))
end
(** {6 Non-logical state} *)
module NonLogical = Logic_monad.NonLogical
let tclLIFT = Proof.lift
let tclCHECKINTERRUPT =
tclLIFT (NonLogical.make Control.check_for_interrupt)
(*** Compatibility layer with <= 8.2 tactics ***)
module V82 = struct
type tac = Evar.t Evd.sigma -> Evar.t list Evd.sigma
let tactic ?(nf_evars=true) tac =
(* spiwack: we ignore the dependencies between goals here,
expectingly preserving the semantics of <= 8.2 tactics *)
(* spiwack: convenience notations, waiting for ocaml 3.12 *)
let open Proof in
Pv.get >>= fun ps ->
try
let tac g_w_s evd =
let g, w = drop_state g_w_s, get_state g_w_s in
let glsigma =
tac { Evd.it = g ; sigma = evd; } in
let sigma = glsigma.Evd.sigma in
let g = CList.map (fun g -> goal_with_state g w) glsigma.Evd.it in
( g, sigma )
in
(* Old style tactics expect the goals normalized with respect to evars. *)
let (initgoals_w_state, initevd) =
Evd.Monad.List.map (fun g_w_s s ->
let g, w = drop_state g_w_s, get_state g_w_s in
let g, s = if nf_evars then goal_nf_evar s g else g, s in
goal_with_state g w, s) ps.comb ps.solution
in
let (goalss,evd) = Evd.Monad.List.map tac initgoals_w_state initevd in
let sgs = CList.flatten goalss in
let sgs = undefined evd sgs in
InfoL.leaf (Info.Tactic (fun () -> Pp.str"<unknown>")) >>
Pv.set { ps with solution = evd; comb = sgs; }
with e when catchable_exception e ->
let (e, info) = CErrors.push e in
tclZERO ~info e
(* normalises the evars in the goals, and stores the result in
solution. *)
let nf_evar_goals =
Pv.modify begin fun ps ->
let map g s = goal_nf_evar s g in
let comb = CList.map drop_state ps.comb in
let (_goals,evd) = Evd.Monad.List.map map comb ps.solution in
{ ps with solution = evd; }
end
let has_unresolved_evar pv =
Evd.has_undefined pv.solution
(* Main function in the implementation of Grab Existential Variables.*)
let grab pv =
let undef = Evd.undefined_map pv.solution in
let goals = CList.rev_map fst (Evar.Map.bindings undef) in
{ pv with comb = List.map with_empty_state goals }
let top_goals initial { solution=solution; } =
let goals = CList.map (fun (t,_) -> fst (Constr.destEvar (EConstr.Unsafe.to_constr t))) initial in
{ Evd.it = goals ; sigma=solution; }
let top_evars initial =
let evars_of_initial (c,_) =
Evar.Set.elements (Evd.evars_of_term (EConstr.Unsafe.to_constr c))
in
CList.flatten (CList.map evars_of_initial initial)
let of_tactic t gls =
try
let init = { shelf = []; solution = gls.Evd.sigma ; comb = [with_empty_state gls.Evd.it] } in
let (_,final,_,_) = apply (goal_env gls.Evd.sigma gls.Evd.it) t init in
{ Evd.sigma = final.solution ; it = CList.map drop_state final.comb }
with Logic_monad.TacticFailure e as src ->
let (_, info) = CErrors.push src in
iraise (e, info)
let put_status = Status.put
let catchable_exception = catchable_exception
let wrap_exceptions f =
try f ()
with e when catchable_exception e ->
let (e, info) = CErrors.push e in tclZERO ~info e
end
(** {7 Notations} *)
module Notations = struct
let (>>=) = tclBIND
let (<*>) = tclTHEN
let (<+>) t1 t2 = tclOR t1 (fun _ -> t2)
end
|