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
1312
1313
1314
1315
1316
1317
1318
1319
1320
1321
1322
1323
1324
1325
1326
1327
1328
1329
1330
1331
1332
1333
1334
1335
1336
1337
1338
1339
1340
1341
1342
1343
1344
1345
1346
1347
1348
1349
1350
1351
1352
1353
1354
1355
1356
1357
1358
1359
1360
1361
1362
1363
1364
1365
1366
1367
1368
1369
1370
1371
1372
1373
1374
1375
1376
1377
1378
1379
1380
1381
1382
1383
1384
1385
1386
1387
1388
1389
1390
1391
1392
1393
1394
1395
1396
1397
1398
1399
1400
1401
1402
1403
1404
1405
1406
1407
1408
1409
1410
1411
1412
1413
1414
1415
1416
1417
1418
1419
1420
1421
1422
1423
1424
1425
1426
1427
1428
1429
1430
1431
1432
1433
1434
1435
1436
1437
1438
1439
1440
1441
1442
1443
1444
1445
1446
1447
1448
1449
1450
1451
1452
1453
1454
1455
1456
1457
1458
1459
1460
1461
1462
1463
1464
1465
1466
1467
1468
1469
1470
1471
1472
1473
1474
1475
1476
1477
1478
1479
1480
1481
1482
1483
1484
1485
1486
1487
1488
1489
1490
1491
1492
1493
1494
1495
1496
1497
1498
1499
1500
1501
1502
1503
1504
1505
1506
1507
1508
1509
1510
1511
1512
1513
1514
1515
1516
1517
1518
1519
1520
1521
1522
1523
1524
1525
1526
1527
1528
1529
1530
1531
1532
1533
1534
1535
1536
1537
1538
1539
1540
1541
1542
1543
1544
1545
1546
1547
1548
1549
1550
1551
1552
1553
1554
1555
1556
1557
1558
1559
1560
1561
1562
1563
1564
1565
1566
1567
1568
1569
1570
1571
1572
1573
1574
1575
1576
1577
1578
1579
1580
1581
1582
1583
1584
1585
1586
1587
1588
1589
1590
1591
1592
1593
1594
1595
1596
1597
1598
1599
1600
1601
1602
1603
1604
1605
1606
1607
1608
1609
1610
1611
1612
1613
1614
1615
1616
1617
1618
1619
1620
1621
1622
1623
1624
1625
1626
1627
1628
1629
1630
1631
1632
1633
1634
1635
1636
1637
1638
1639
1640
1641
1642
1643
1644
1645
1646
1647
1648
1649
1650
1651
1652
1653
1654
1655
1656
1657
1658
1659
1660
1661
1662
1663
1664
|
// Copyright (c) 2019 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#ifndef BITCOIN_SCRIPT_MINISCRIPT_H
#define BITCOIN_SCRIPT_MINISCRIPT_H
#include <algorithm>
#include <numeric>
#include <memory>
#include <optional>
#include <string>
#include <vector>
#include <stdlib.h>
#include <assert.h>
#include <policy/policy.h>
#include <primitives/transaction.h>
#include <script/script.h>
#include <span.h>
#include <util/spanparsing.h>
#include <util/strencodings.h>
#include <util/string.h>
#include <util/vector.h>
namespace miniscript {
/** This type encapsulates the miniscript type system properties.
*
* Every miniscript expression is one of 4 basic types, and additionally has
* a number of boolean type properties.
*
* The basic types are:
* - "B" Base:
* - Takes its inputs from the top of the stack.
* - When satisfied, pushes a nonzero value of up to 4 bytes onto the stack.
* - When dissatisfied, pushes a 0 onto the stack.
* - This is used for most expressions, and required for the top level one.
* - For example: older(n) = <n> OP_CHECKSEQUENCEVERIFY.
* - "V" Verify:
* - Takes its inputs from the top of the stack.
* - When satisfactied, pushes nothing.
* - Cannot be dissatisfied.
* - This can be obtained by adding an OP_VERIFY to a B, modifying the last opcode
* of a B to its -VERIFY version (only for OP_CHECKSIG, OP_CHECKSIGVERIFY
* and OP_EQUAL), or by combining a V fragment under some conditions.
* - For example vc:pk_k(key) = <key> OP_CHECKSIGVERIFY
* - "K" Key:
* - Takes its inputs from the top of the stack.
* - Becomes a B when followed by OP_CHECKSIG.
* - Always pushes a public key onto the stack, for which a signature is to be
* provided to satisfy the expression.
* - For example pk_h(key) = OP_DUP OP_HASH160 <Hash160(key)> OP_EQUALVERIFY
* - "W" Wrapped:
* - Takes its input from one below the top of the stack.
* - When satisfied, pushes a nonzero value (like B) on top of the stack, or one below.
* - When dissatisfied, pushes 0 op top of the stack or one below.
* - Is always "OP_SWAP [B]" or "OP_TOALTSTACK [B] OP_FROMALTSTACK".
* - For example sc:pk_k(key) = OP_SWAP <key> OP_CHECKSIG
*
* There a type properties that help reasoning about correctness:
* - "z" Zero-arg:
* - Is known to always consume exactly 0 stack elements.
* - For example after(n) = <n> OP_CHECKLOCKTIMEVERIFY
* - "o" One-arg:
* - Is known to always consume exactly 1 stack element.
* - Conflicts with property 'z'
* - For example sha256(hash) = OP_SIZE 32 OP_EQUALVERIFY OP_SHA256 <hash> OP_EQUAL
* - "n" Nonzero:
* - For every way this expression can be satisfied, a satisfaction exists that never needs
* a zero top stack element.
* - Conflicts with property 'z' and with type 'W'.
* - "d" Dissatisfiable:
* - There is an easy way to construct a dissatisfaction for this expression.
* - Conflicts with type 'V'.
* - "u" Unit:
* - In case of satisfaction, an exact 1 is put on the stack (rather than just nonzero).
* - Conflicts with type 'V'.
*
* Additional type properties help reasoning about nonmalleability:
* - "e" Expression:
* - This implies property 'd', but the dissatisfaction is nonmalleable.
* - This generally requires 'e' for all subexpressions which are invoked for that
* dissatifsaction, and property 'f' for the unexecuted subexpressions in that case.
* - Conflicts with type 'V'.
* - "f" Forced:
* - Dissatisfactions (if any) for this expression always involve at least one signature.
* - Is always true for type 'V'.
* - "s" Safe:
* - Satisfactions for this expression always involve at least one signature.
* - "m" Nonmalleable:
* - For every way this expression can be satisfied (which may be none),
* a nonmalleable satisfaction exists.
* - This generally requires 'm' for all subexpressions, and 'e' for all subexpressions
* which are dissatisfied when satisfying the parent.
*
* One type property is an implementation detail:
* - "x" Expensive verify:
* - Expressions with this property have a script whose last opcode is not EQUAL, CHECKSIG, or CHECKMULTISIG.
* - Not having this property means that it can be converted to a V at no cost (by switching to the
* -VERIFY version of the last opcode).
*
* Five more type properties for representing timelock information. Spend paths
* in miniscripts containing conflicting timelocks and heightlocks cannot be spent together.
* This helps users detect if miniscript does not match the semantic behaviour the
* user expects.
* - "g" Whether the branch contains a relative time timelock
* - "h" Whether the branch contains a relative height timelock
* - "i" Whether the branch contains an absolute time timelock
* - "j" Whether the branch contains an absolute height timelock
* - "k"
* - Whether all satisfactions of this expression don't contain a mix of heightlock and timelock
* of the same type.
* - If the miniscript does not have the "k" property, the miniscript template will not match
* the user expectation of the corresponding spending policy.
* For each of these properties the subset rule holds: an expression with properties X, Y, and Z, is also
* valid in places where an X, a Y, a Z, an XY, ... is expected.
*/
class Type {
//! Internal bitmap of properties (see ""_mst operator for details).
uint32_t m_flags;
//! Internal constructor used by the ""_mst operator.
explicit constexpr Type(uint32_t flags) : m_flags(flags) {}
public:
//! The only way to publicly construct a Type is using this literal operator.
friend constexpr Type operator"" _mst(const char* c, size_t l);
//! Compute the type with the union of properties.
constexpr Type operator|(Type x) const { return Type(m_flags | x.m_flags); }
//! Compute the type with the intersection of properties.
constexpr Type operator&(Type x) const { return Type(m_flags & x.m_flags); }
//! Check whether the left hand's properties are superset of the right's (= left is a subtype of right).
constexpr bool operator<<(Type x) const { return (x.m_flags & ~m_flags) == 0; }
//! Comparison operator to enable use in sets/maps (total ordering incompatible with <<).
constexpr bool operator<(Type x) const { return m_flags < x.m_flags; }
//! Equality operator.
constexpr bool operator==(Type x) const { return m_flags == x.m_flags; }
//! The empty type if x is false, itself otherwise.
constexpr Type If(bool x) const { return Type(x ? m_flags : 0); }
};
//! Literal operator to construct Type objects.
inline constexpr Type operator"" _mst(const char* c, size_t l) {
Type typ{0};
for (const char *p = c; p < c + l; p++) {
typ = typ | Type(
*p == 'B' ? 1 << 0 : // Base type
*p == 'V' ? 1 << 1 : // Verify type
*p == 'K' ? 1 << 2 : // Key type
*p == 'W' ? 1 << 3 : // Wrapped type
*p == 'z' ? 1 << 4 : // Zero-arg property
*p == 'o' ? 1 << 5 : // One-arg property
*p == 'n' ? 1 << 6 : // Nonzero arg property
*p == 'd' ? 1 << 7 : // Dissatisfiable property
*p == 'u' ? 1 << 8 : // Unit property
*p == 'e' ? 1 << 9 : // Expression property
*p == 'f' ? 1 << 10 : // Forced property
*p == 's' ? 1 << 11 : // Safe property
*p == 'm' ? 1 << 12 : // Nonmalleable property
*p == 'x' ? 1 << 13 : // Expensive verify
*p == 'g' ? 1 << 14 : // older: contains relative time timelock (csv_time)
*p == 'h' ? 1 << 15 : // older: contains relative height timelock (csv_height)
*p == 'i' ? 1 << 16 : // after: contains time timelock (cltv_time)
*p == 'j' ? 1 << 17 : // after: contains height timelock (cltv_height)
*p == 'k' ? 1 << 18 : // does not contain a combination of height and time locks
(throw std::logic_error("Unknown character in _mst literal"), 0)
);
}
return typ;
}
template<typename Key> struct Node;
template<typename Key> using NodeRef = std::shared_ptr<const Node<Key>>;
//! Construct a miniscript node as a shared_ptr.
template<typename Key, typename... Args>
NodeRef<Key> MakeNodeRef(Args&&... args) { return std::make_shared<const Node<Key>>(std::forward<Args>(args)...); }
//! The different node types in miniscript.
enum class Fragment {
JUST_0, //!< OP_0
JUST_1, //!< OP_1
PK_K, //!< [key]
PK_H, //!< OP_DUP OP_HASH160 [keyhash] OP_EQUALVERIFY
OLDER, //!< [n] OP_CHECKSEQUENCEVERIFY
AFTER, //!< [n] OP_CHECKLOCKTIMEVERIFY
SHA256, //!< OP_SIZE 32 OP_EQUALVERIFY OP_SHA256 [hash] OP_EQUAL
HASH256, //!< OP_SIZE 32 OP_EQUALVERIFY OP_HASH256 [hash] OP_EQUAL
RIPEMD160, //!< OP_SIZE 32 OP_EQUALVERIFY OP_RIPEMD160 [hash] OP_EQUAL
HASH160, //!< OP_SIZE 32 OP_EQUALVERIFY OP_HASH160 [hash] OP_EQUAL
WRAP_A, //!< OP_TOALTSTACK [X] OP_FROMALTSTACK
WRAP_S, //!< OP_SWAP [X]
WRAP_C, //!< [X] OP_CHECKSIG
WRAP_D, //!< OP_DUP OP_IF [X] OP_ENDIF
WRAP_V, //!< [X] OP_VERIFY (or -VERIFY version of last opcode in X)
WRAP_J, //!< OP_SIZE OP_0NOTEQUAL OP_IF [X] OP_ENDIF
WRAP_N, //!< [X] OP_0NOTEQUAL
AND_V, //!< [X] [Y]
AND_B, //!< [X] [Y] OP_BOOLAND
OR_B, //!< [X] [Y] OP_BOOLOR
OR_C, //!< [X] OP_NOTIF [Y] OP_ENDIF
OR_D, //!< [X] OP_IFDUP OP_NOTIF [Y] OP_ENDIF
OR_I, //!< OP_IF [X] OP_ELSE [Y] OP_ENDIF
ANDOR, //!< [X] OP_NOTIF [Z] OP_ELSE [Y] OP_ENDIF
THRESH, //!< [X1] ([Xn] OP_ADD)* [k] OP_EQUAL
MULTI, //!< [k] [key_n]* [n] OP_CHECKMULTISIG
// AND_N(X,Y) is represented as ANDOR(X,Y,0)
// WRAP_T(X) is represented as AND_V(X,1)
// WRAP_L(X) is represented as OR_I(0,X)
// WRAP_U(X) is represented as OR_I(X,0)
};
namespace internal {
//! Helper function for Node::CalcType.
Type ComputeType(Fragment fragment, Type x, Type y, Type z, const std::vector<Type>& sub_types, uint32_t k, size_t data_size, size_t n_subs, size_t n_keys);
//! Helper function for Node::CalcScriptLen.
size_t ComputeScriptLen(Fragment fragment, Type sub0typ, size_t subsize, uint32_t k, size_t n_subs, size_t n_keys);
//! A helper sanitizer/checker for the output of CalcType.
Type SanitizeType(Type x);
//! Class whose objects represent the maximum of a list of integers.
template<typename I>
struct MaxInt {
const bool valid;
const I value;
MaxInt() : valid(false), value(0) {}
MaxInt(I val) : valid(true), value(val) {}
friend MaxInt<I> operator+(const MaxInt<I>& a, const MaxInt<I>& b) {
if (!a.valid || !b.valid) return {};
return a.value + b.value;
}
friend MaxInt<I> operator|(const MaxInt<I>& a, const MaxInt<I>& b) {
if (!a.valid) return b;
if (!b.valid) return a;
return std::max(a.value, b.value);
}
};
struct Ops {
//! Non-push opcodes.
uint32_t count;
//! Number of keys in possibly executed OP_CHECKMULTISIG(VERIFY)s to satisfy.
MaxInt<uint32_t> sat;
//! Number of keys in possibly executed OP_CHECKMULTISIG(VERIFY)s to dissatisfy.
MaxInt<uint32_t> dsat;
Ops(uint32_t in_count, MaxInt<uint32_t> in_sat, MaxInt<uint32_t> in_dsat) : count(in_count), sat(in_sat), dsat(in_dsat) {};
};
struct StackSize {
//! Maximum stack size to satisfy;
MaxInt<uint32_t> sat;
//! Maximum stack size to dissatisfy;
MaxInt<uint32_t> dsat;
StackSize(MaxInt<uint32_t> in_sat, MaxInt<uint32_t> in_dsat) : sat(in_sat), dsat(in_dsat) {};
};
} // namespace internal
//! A node in a miniscript expression.
template<typename Key>
struct Node {
//! What node type this node is.
const Fragment fragment;
//! The k parameter (time for OLDER/AFTER, threshold for THRESH(_M))
const uint32_t k = 0;
//! The keys used by this expression (only for PK_K/PK_H/MULTI)
const std::vector<Key> keys;
//! The data bytes in this expression (only for HASH160/HASH256/SHA256/RIPEMD10).
const std::vector<unsigned char> data;
//! Subexpressions (for WRAP_*/AND_*/OR_*/ANDOR/THRESH)
const std::vector<NodeRef<Key>> subs;
private:
//! Cached ops counts.
const internal::Ops ops;
//! Cached stack size bounds.
const internal::StackSize ss;
//! Cached expression type (computed by CalcType and fed through SanitizeType).
const Type typ;
//! Cached script length (computed by CalcScriptLen).
const size_t scriptlen;
//! Compute the length of the script for this miniscript (including children).
size_t CalcScriptLen() const {
size_t subsize = 0;
for (const auto& sub : subs) {
subsize += sub->ScriptSize();
}
Type sub0type = subs.size() > 0 ? subs[0]->GetType() : ""_mst;
return internal::ComputeScriptLen(fragment, sub0type, subsize, k, subs.size(), keys.size());
}
/* Apply a recursive algorithm to a Miniscript tree, without actual recursive calls.
*
* The algorithm is defined by two functions: downfn and upfn. Conceptually, the
* result can be thought of as first using downfn to compute a "state" for each node,
* from the root down to the leaves. Then upfn is used to compute a "result" for each
* node, from the leaves back up to the root, which is then returned. In the actual
* implementation, both functions are invoked in an interleaved fashion, performing a
* depth-first traversal of the tree.
*
* In more detail, it is invoked as node.TreeEvalMaybe<Result>(root, downfn, upfn):
* - root is the state of the root node, of type State.
* - downfn is a callable (State&, const Node&, size_t) -> State, which given a
* node, its state, and an index of one of its children, computes the state of that
* child. It can modify the state. Children of a given node will have downfn()
* called in order.
* - upfn is a callable (State&&, const Node&, Span<Result>) -> std::optional<Result>,
* which given a node, its state, and a Span of the results of its children,
* computes the result of the node. If std::nullopt is returned by upfn,
* TreeEvalMaybe() immediately returns std::nullopt.
* The return value of TreeEvalMaybe is the result of the root node.
*/
template<typename Result, typename State, typename DownFn, typename UpFn>
std::optional<Result> TreeEvalMaybe(State root_state, DownFn downfn, UpFn upfn) const
{
/** Entries of the explicit stack tracked in this algorithm. */
struct StackElem
{
const Node& node; //!< The node being evaluated.
size_t expanded; //!< How many children of this node have been expanded.
State state; //!< The state for that node.
StackElem(const Node& node_, size_t exp_, State&& state_) :
node(node_), expanded(exp_), state(std::move(state_)) {}
};
/* Stack of tree nodes being explored. */
std::vector<StackElem> stack;
/* Results of subtrees so far. Their order and mapping to tree nodes
* is implicitly defined by stack. */
std::vector<Result> results;
stack.emplace_back(*this, 0, std::move(root_state));
/* Here is a demonstration of the algorithm, for an example tree A(B,C(D,E),F).
* State variables are omitted for simplicity.
*
* First: stack=[(A,0)] results=[]
* stack=[(A,1),(B,0)] results=[]
* stack=[(A,1)] results=[B]
* stack=[(A,2),(C,0)] results=[B]
* stack=[(A,2),(C,1),(D,0)] results=[B]
* stack=[(A,2),(C,1)] results=[B,D]
* stack=[(A,2),(C,2),(E,0)] results=[B,D]
* stack=[(A,2),(C,2)] results=[B,D,E]
* stack=[(A,2)] results=[B,C]
* stack=[(A,3),(F,0)] results=[B,C]
* stack=[(A,3)] results=[B,C,F]
* Final: stack=[] results=[A]
*/
while (stack.size()) {
const Node& node = stack.back().node;
if (stack.back().expanded < node.subs.size()) {
/* We encounter a tree node with at least one unexpanded child.
* Expand it. By the time we hit this node again, the result of
* that child (and all earlier children) will be at the end of `results`. */
size_t child_index = stack.back().expanded++;
State child_state = downfn(stack.back().state, node, child_index);
stack.emplace_back(*node.subs[child_index], 0, std::move(child_state));
continue;
}
// Invoke upfn with the last node.subs.size() elements of results as input.
assert(results.size() >= node.subs.size());
std::optional<Result> result{upfn(std::move(stack.back().state), node,
Span<Result>{results}.last(node.subs.size()))};
// If evaluation returns std::nullopt, abort immediately.
if (!result) return {};
// Replace the last node.subs.size() elements of results with the new result.
results.erase(results.end() - node.subs.size(), results.end());
results.push_back(std::move(*result));
stack.pop_back();
}
// The final remaining results element is the root result, return it.
assert(results.size() == 1);
return std::move(results[0]);
}
/** Like TreeEvalMaybe, but always produces a result. upfn must return Result. */
template<typename Result, typename State, typename DownFn, typename UpFn>
Result TreeEval(State root_state, DownFn&& downfn, UpFn upfn) const
{
// Invoke TreeEvalMaybe with upfn wrapped to return std::optional<Result>, and then
// unconditionally dereference the result (it cannot be std::nullopt).
return std::move(*TreeEvalMaybe<Result>(std::move(root_state),
std::forward<DownFn>(downfn),
[&upfn](State&& state, const Node& node, Span<Result> subs) {
Result res{upfn(std::move(state), node, subs)};
return std::optional<Result>(std::move(res));
}
));
}
/** Compare two miniscript subtrees, using a non-recursive algorithm. */
friend int Compare(const Node<Key>& node1, const Node<Key>& node2)
{
std::vector<std::pair<const Node<Key>&, const Node<Key>&>> queue;
queue.emplace_back(node1, node2);
while (!queue.empty()) {
const auto& [a, b] = queue.back();
queue.pop_back();
if (std::tie(a.fragment, a.k, a.keys, a.data) < std::tie(b.fragment, b.k, b.keys, b.data)) return -1;
if (std::tie(b.fragment, b.k, b.keys, b.data) < std::tie(a.fragment, a.k, a.keys, a.data)) return 1;
if (a.subs.size() < b.subs.size()) return -1;
if (b.subs.size() < a.subs.size()) return 1;
size_t n = a.subs.size();
for (size_t i = 0; i < n; ++i) {
queue.emplace_back(*a.subs[n - 1 - i], *b.subs[n - 1 - i]);
}
}
return 0;
}
//! Compute the type for this miniscript.
Type CalcType() const {
using namespace internal;
// THRESH has a variable number of subexpressions
std::vector<Type> sub_types;
if (fragment == Fragment::THRESH) {
for (const auto& sub : subs) sub_types.push_back(sub->GetType());
}
// All other nodes than THRESH can be computed just from the types of the 0-3 subexpressions.
Type x = subs.size() > 0 ? subs[0]->GetType() : ""_mst;
Type y = subs.size() > 1 ? subs[1]->GetType() : ""_mst;
Type z = subs.size() > 2 ? subs[2]->GetType() : ""_mst;
return SanitizeType(ComputeType(fragment, x, y, z, sub_types, k, data.size(), subs.size(), keys.size()));
}
public:
template<typename Ctx>
CScript ToScript(const Ctx& ctx) const
{
// To construct the CScript for a Miniscript object, we use the TreeEval algorithm.
// The State is a boolean: whether or not the node's script expansion is followed
// by an OP_VERIFY (which may need to be combined with the last script opcode).
auto downfn = [](bool verify, const Node& node, size_t index) {
// For WRAP_V, the subexpression is certainly followed by OP_VERIFY.
if (node.fragment == Fragment::WRAP_V) return true;
// The subexpression of WRAP_S, and the last subexpression of AND_V
// inherit the followed-by-OP_VERIFY property from the parent.
if (node.fragment == Fragment::WRAP_S ||
(node.fragment == Fragment::AND_V && index == 1)) return verify;
return false;
};
// The upward function computes for a node, given its followed-by-OP_VERIFY status
// and the CScripts of its child nodes, the CScript of the node.
auto upfn = [&ctx](bool verify, const Node& node, Span<CScript> subs) -> CScript {
switch (node.fragment) {
case Fragment::PK_K: return BuildScript(ctx.ToPKBytes(node.keys[0]));
case Fragment::PK_H: return BuildScript(OP_DUP, OP_HASH160, ctx.ToPKHBytes(node.keys[0]), OP_EQUALVERIFY);
case Fragment::OLDER: return BuildScript(node.k, OP_CHECKSEQUENCEVERIFY);
case Fragment::AFTER: return BuildScript(node.k, OP_CHECKLOCKTIMEVERIFY);
case Fragment::SHA256: return BuildScript(OP_SIZE, 32, OP_EQUALVERIFY, OP_SHA256, node.data, verify ? OP_EQUALVERIFY : OP_EQUAL);
case Fragment::RIPEMD160: return BuildScript(OP_SIZE, 32, OP_EQUALVERIFY, OP_RIPEMD160, node.data, verify ? OP_EQUALVERIFY : OP_EQUAL);
case Fragment::HASH256: return BuildScript(OP_SIZE, 32, OP_EQUALVERIFY, OP_HASH256, node.data, verify ? OP_EQUALVERIFY : OP_EQUAL);
case Fragment::HASH160: return BuildScript(OP_SIZE, 32, OP_EQUALVERIFY, OP_HASH160, node.data, verify ? OP_EQUALVERIFY : OP_EQUAL);
case Fragment::WRAP_A: return BuildScript(OP_TOALTSTACK, subs[0], OP_FROMALTSTACK);
case Fragment::WRAP_S: return BuildScript(OP_SWAP, subs[0]);
case Fragment::WRAP_C: return BuildScript(std::move(subs[0]), verify ? OP_CHECKSIGVERIFY : OP_CHECKSIG);
case Fragment::WRAP_D: return BuildScript(OP_DUP, OP_IF, subs[0], OP_ENDIF);
case Fragment::WRAP_V: {
if (node.subs[0]->GetType() << "x"_mst) {
return BuildScript(std::move(subs[0]), OP_VERIFY);
} else {
return std::move(subs[0]);
}
}
case Fragment::WRAP_J: return BuildScript(OP_SIZE, OP_0NOTEQUAL, OP_IF, subs[0], OP_ENDIF);
case Fragment::WRAP_N: return BuildScript(std::move(subs[0]), OP_0NOTEQUAL);
case Fragment::JUST_1: return BuildScript(OP_1);
case Fragment::JUST_0: return BuildScript(OP_0);
case Fragment::AND_V: return BuildScript(std::move(subs[0]), subs[1]);
case Fragment::AND_B: return BuildScript(std::move(subs[0]), subs[1], OP_BOOLAND);
case Fragment::OR_B: return BuildScript(std::move(subs[0]), subs[1], OP_BOOLOR);
case Fragment::OR_D: return BuildScript(std::move(subs[0]), OP_IFDUP, OP_NOTIF, subs[1], OP_ENDIF);
case Fragment::OR_C: return BuildScript(std::move(subs[0]), OP_NOTIF, subs[1], OP_ENDIF);
case Fragment::OR_I: return BuildScript(OP_IF, subs[0], OP_ELSE, subs[1], OP_ENDIF);
case Fragment::ANDOR: return BuildScript(std::move(subs[0]), OP_NOTIF, subs[2], OP_ELSE, subs[1], OP_ENDIF);
case Fragment::MULTI: {
CScript script = BuildScript(node.k);
for (const auto& key : node.keys) {
script = BuildScript(std::move(script), ctx.ToPKBytes(key));
}
return BuildScript(std::move(script), node.keys.size(), verify ? OP_CHECKMULTISIGVERIFY : OP_CHECKMULTISIG);
}
case Fragment::THRESH: {
CScript script = std::move(subs[0]);
for (size_t i = 1; i < subs.size(); ++i) {
script = BuildScript(std::move(script), subs[i], OP_ADD);
}
return BuildScript(std::move(script), node.k, verify ? OP_EQUALVERIFY : OP_EQUAL);
}
}
assert(false);
return {};
};
return TreeEval<CScript>(false, downfn, upfn);
}
template<typename CTx>
std::optional<std::string> ToString(const CTx& ctx) const {
// To construct the std::string representation for a Miniscript object, we use
// the TreeEvalMaybe algorithm. The State is a boolean: whether the parent node is a
// wrapper. If so, non-wrapper expressions must be prefixed with a ":".
auto downfn = [](bool, const Node& node, size_t) {
return (node.fragment == Fragment::WRAP_A || node.fragment == Fragment::WRAP_S ||
node.fragment == Fragment::WRAP_D || node.fragment == Fragment::WRAP_V ||
node.fragment == Fragment::WRAP_J || node.fragment == Fragment::WRAP_N ||
node.fragment == Fragment::WRAP_C ||
(node.fragment == Fragment::AND_V && node.subs[1]->fragment == Fragment::JUST_1) ||
(node.fragment == Fragment::OR_I && node.subs[0]->fragment == Fragment::JUST_0) ||
(node.fragment == Fragment::OR_I && node.subs[1]->fragment == Fragment::JUST_0));
};
// The upward function computes for a node, given whether its parent is a wrapper,
// and the string representations of its child nodes, the string representation of the node.
auto upfn = [&ctx](bool wrapped, const Node& node, Span<std::string> subs) -> std::optional<std::string> {
std::string ret = wrapped ? ":" : "";
switch (node.fragment) {
case Fragment::WRAP_A: return "a" + std::move(subs[0]);
case Fragment::WRAP_S: return "s" + std::move(subs[0]);
case Fragment::WRAP_C:
if (node.subs[0]->fragment == Fragment::PK_K) {
// pk(K) is syntactic sugar for c:pk_k(K)
auto key_str = ctx.ToString(node.subs[0]->keys[0]);
if (!key_str) return {};
return std::move(ret) + "pk(" + std::move(*key_str) + ")";
}
if (node.subs[0]->fragment == Fragment::PK_H) {
// pkh(K) is syntactic sugar for c:pk_h(K)
auto key_str = ctx.ToString(node.subs[0]->keys[0]);
if (!key_str) return {};
return std::move(ret) + "pkh(" + std::move(*key_str) + ")";
}
return "c" + std::move(subs[0]);
case Fragment::WRAP_D: return "d" + std::move(subs[0]);
case Fragment::WRAP_V: return "v" + std::move(subs[0]);
case Fragment::WRAP_J: return "j" + std::move(subs[0]);
case Fragment::WRAP_N: return "n" + std::move(subs[0]);
case Fragment::AND_V:
// t:X is syntactic sugar for and_v(X,1).
if (node.subs[1]->fragment == Fragment::JUST_1) return "t" + std::move(subs[0]);
break;
case Fragment::OR_I:
if (node.subs[0]->fragment == Fragment::JUST_0) return "l" + std::move(subs[1]);
if (node.subs[1]->fragment == Fragment::JUST_0) return "u" + std::move(subs[0]);
break;
default: break;
}
switch (node.fragment) {
case Fragment::PK_K: {
auto key_str = ctx.ToString(node.keys[0]);
if (!key_str) return {};
return std::move(ret) + "pk_k(" + std::move(*key_str) + ")";
}
case Fragment::PK_H: {
auto key_str = ctx.ToString(node.keys[0]);
if (!key_str) return {};
return std::move(ret) + "pk_h(" + std::move(*key_str) + ")";
}
case Fragment::AFTER: return std::move(ret) + "after(" + ::ToString(node.k) + ")";
case Fragment::OLDER: return std::move(ret) + "older(" + ::ToString(node.k) + ")";
case Fragment::HASH256: return std::move(ret) + "hash256(" + HexStr(node.data) + ")";
case Fragment::HASH160: return std::move(ret) + "hash160(" + HexStr(node.data) + ")";
case Fragment::SHA256: return std::move(ret) + "sha256(" + HexStr(node.data) + ")";
case Fragment::RIPEMD160: return std::move(ret) + "ripemd160(" + HexStr(node.data) + ")";
case Fragment::JUST_1: return std::move(ret) + "1";
case Fragment::JUST_0: return std::move(ret) + "0";
case Fragment::AND_V: return std::move(ret) + "and_v(" + std::move(subs[0]) + "," + std::move(subs[1]) + ")";
case Fragment::AND_B: return std::move(ret) + "and_b(" + std::move(subs[0]) + "," + std::move(subs[1]) + ")";
case Fragment::OR_B: return std::move(ret) + "or_b(" + std::move(subs[0]) + "," + std::move(subs[1]) + ")";
case Fragment::OR_D: return std::move(ret) + "or_d(" + std::move(subs[0]) + "," + std::move(subs[1]) + ")";
case Fragment::OR_C: return std::move(ret) + "or_c(" + std::move(subs[0]) + "," + std::move(subs[1]) + ")";
case Fragment::OR_I: return std::move(ret) + "or_i(" + std::move(subs[0]) + "," + std::move(subs[1]) + ")";
case Fragment::ANDOR:
// and_n(X,Y) is syntactic sugar for andor(X,Y,0).
if (node.subs[2]->fragment == Fragment::JUST_0) return std::move(ret) + "and_n(" + std::move(subs[0]) + "," + std::move(subs[1]) + ")";
return std::move(ret) + "andor(" + std::move(subs[0]) + "," + std::move(subs[1]) + "," + std::move(subs[2]) + ")";
case Fragment::MULTI: {
auto str = std::move(ret) + "multi(" + ::ToString(node.k);
for (const auto& key : node.keys) {
auto key_str = ctx.ToString(key);
if (!key_str) return {};
str += "," + std::move(*key_str);
}
return std::move(str) + ")";
}
case Fragment::THRESH: {
auto str = std::move(ret) + "thresh(" + ::ToString(node.k);
for (auto& sub : subs) {
str += "," + std::move(sub);
}
return std::move(str) + ")";
}
default: assert(false);
}
return ""; // Should never be reached.
};
return TreeEvalMaybe<std::string>(false, downfn, upfn);
}
internal::Ops CalcOps() const {
switch (fragment) {
case Fragment::JUST_1: return {0, 0, {}};
case Fragment::JUST_0: return {0, {}, 0};
case Fragment::PK_K: return {0, 0, 0};
case Fragment::PK_H: return {3, 0, 0};
case Fragment::OLDER:
case Fragment::AFTER: return {1, 0, {}};
case Fragment::SHA256:
case Fragment::RIPEMD160:
case Fragment::HASH256:
case Fragment::HASH160: return {4, 0, {}};
case Fragment::AND_V: return {subs[0]->ops.count + subs[1]->ops.count, subs[0]->ops.sat + subs[1]->ops.sat, {}};
case Fragment::AND_B: {
const auto count{1 + subs[0]->ops.count + subs[1]->ops.count};
const auto sat{subs[0]->ops.sat + subs[1]->ops.sat};
const auto dsat{subs[0]->ops.dsat + subs[1]->ops.dsat};
return {count, sat, dsat};
}
case Fragment::OR_B: {
const auto count{1 + subs[0]->ops.count + subs[1]->ops.count};
const auto sat{(subs[0]->ops.sat + subs[1]->ops.dsat) | (subs[1]->ops.sat + subs[0]->ops.dsat)};
const auto dsat{subs[0]->ops.dsat + subs[1]->ops.dsat};
return {count, sat, dsat};
}
case Fragment::OR_D: {
const auto count{3 + subs[0]->ops.count + subs[1]->ops.count};
const auto sat{subs[0]->ops.sat | (subs[1]->ops.sat + subs[0]->ops.dsat)};
const auto dsat{subs[0]->ops.dsat + subs[1]->ops.dsat};
return {count, sat, dsat};
}
case Fragment::OR_C: {
const auto count{2 + subs[0]->ops.count + subs[1]->ops.count};
const auto sat{subs[0]->ops.sat | (subs[1]->ops.sat + subs[0]->ops.dsat)};
return {count, sat, {}};
}
case Fragment::OR_I: {
const auto count{3 + subs[0]->ops.count + subs[1]->ops.count};
const auto sat{subs[0]->ops.sat | subs[1]->ops.sat};
const auto dsat{subs[0]->ops.dsat | subs[1]->ops.dsat};
return {count, sat, dsat};
}
case Fragment::ANDOR: {
const auto count{3 + subs[0]->ops.count + subs[1]->ops.count + subs[2]->ops.count};
const auto sat{(subs[1]->ops.sat + subs[0]->ops.sat) | (subs[0]->ops.dsat + subs[2]->ops.sat)};
const auto dsat{subs[0]->ops.dsat + subs[2]->ops.dsat};
return {count, sat, dsat};
}
case Fragment::MULTI: return {1, (uint32_t)keys.size(), (uint32_t)keys.size()};
case Fragment::WRAP_S:
case Fragment::WRAP_C:
case Fragment::WRAP_N: return {1 + subs[0]->ops.count, subs[0]->ops.sat, subs[0]->ops.dsat};
case Fragment::WRAP_A: return {2 + subs[0]->ops.count, subs[0]->ops.sat, subs[0]->ops.dsat};
case Fragment::WRAP_D: return {3 + subs[0]->ops.count, subs[0]->ops.sat, 0};
case Fragment::WRAP_J: return {4 + subs[0]->ops.count, subs[0]->ops.sat, 0};
case Fragment::WRAP_V: return {subs[0]->ops.count + (subs[0]->GetType() << "x"_mst), subs[0]->ops.sat, {}};
case Fragment::THRESH: {
uint32_t count = 0;
auto sats = Vector(internal::MaxInt<uint32_t>(0));
for (const auto& sub : subs) {
count += sub->ops.count + 1;
auto next_sats = Vector(sats[0] + sub->ops.dsat);
for (size_t j = 1; j < sats.size(); ++j) next_sats.push_back((sats[j] + sub->ops.dsat) | (sats[j - 1] + sub->ops.sat));
next_sats.push_back(sats[sats.size() - 1] + sub->ops.sat);
sats = std::move(next_sats);
}
assert(k <= sats.size());
return {count, sats[k], sats[0]};
}
}
assert(false);
return {0, {}, {}};
}
internal::StackSize CalcStackSize() const {
switch (fragment) {
case Fragment::JUST_0: return {{}, 0};
case Fragment::JUST_1:
case Fragment::OLDER:
case Fragment::AFTER: return {0, {}};
case Fragment::PK_K: return {1, 1};
case Fragment::PK_H: return {2, 2};
case Fragment::SHA256:
case Fragment::RIPEMD160:
case Fragment::HASH256:
case Fragment::HASH160: return {1, {}};
case Fragment::ANDOR: {
const auto sat{(subs[0]->ss.sat + subs[1]->ss.sat) | (subs[0]->ss.dsat + subs[2]->ss.sat)};
const auto dsat{subs[0]->ss.dsat + subs[2]->ss.dsat};
return {sat, dsat};
}
case Fragment::AND_V: return {subs[0]->ss.sat + subs[1]->ss.sat, {}};
case Fragment::AND_B: return {subs[0]->ss.sat + subs[1]->ss.sat, subs[0]->ss.dsat + subs[1]->ss.dsat};
case Fragment::OR_B: {
const auto sat{(subs[0]->ss.dsat + subs[1]->ss.sat) | (subs[0]->ss.sat + subs[1]->ss.dsat)};
const auto dsat{subs[0]->ss.dsat + subs[1]->ss.dsat};
return {sat, dsat};
}
case Fragment::OR_C: return {subs[0]->ss.sat | (subs[0]->ss.dsat + subs[1]->ss.sat), {}};
case Fragment::OR_D: return {subs[0]->ss.sat | (subs[0]->ss.dsat + subs[1]->ss.sat), subs[0]->ss.dsat + subs[1]->ss.dsat};
case Fragment::OR_I: return {(subs[0]->ss.sat + 1) | (subs[1]->ss.sat + 1), (subs[0]->ss.dsat + 1) | (subs[1]->ss.dsat + 1)};
case Fragment::MULTI: return {k + 1, k + 1};
case Fragment::WRAP_A:
case Fragment::WRAP_N:
case Fragment::WRAP_S:
case Fragment::WRAP_C: return subs[0]->ss;
case Fragment::WRAP_D: return {1 + subs[0]->ss.sat, 1};
case Fragment::WRAP_V: return {subs[0]->ss.sat, {}};
case Fragment::WRAP_J: return {subs[0]->ss.sat, 1};
case Fragment::THRESH: {
auto sats = Vector(internal::MaxInt<uint32_t>(0));
for (const auto& sub : subs) {
auto next_sats = Vector(sats[0] + sub->ss.dsat);
for (size_t j = 1; j < sats.size(); ++j) next_sats.push_back((sats[j] + sub->ss.dsat) | (sats[j - 1] + sub->ss.sat));
next_sats.push_back(sats[sats.size() - 1] + sub->ss.sat);
sats = std::move(next_sats);
}
assert(k <= sats.size());
return {sats[k], sats[0]};
}
}
assert(false);
return {{}, {}};
}
public:
//! Return the size of the script for this expression (faster than ToScript().size()).
size_t ScriptSize() const { return scriptlen; }
//! Return the maximum number of ops needed to satisfy this script non-malleably.
uint32_t GetOps() const { return ops.count + ops.sat.value; }
//! Check the ops limit of this script against the consensus limit.
bool CheckOpsLimit() const { return GetOps() <= MAX_OPS_PER_SCRIPT; }
/** Return the maximum number of stack elements needed to satisfy this script non-malleably, including
* the script push. */
uint32_t GetStackSize() const { return ss.sat.value + 1; }
//! Check the maximum stack size for this script against the policy limit.
bool CheckStackSize() const { return GetStackSize() - 1 <= MAX_STANDARD_P2WSH_STACK_ITEMS; }
//! Return the expression type.
Type GetType() const { return typ; }
//! Check whether this node is valid at all.
bool IsValid() const { return !(GetType() == ""_mst) && ScriptSize() <= MAX_STANDARD_P2WSH_SCRIPT_SIZE; }
//! Check whether this node is valid as a script on its own.
bool IsValidTopLevel() const { return IsValid() && GetType() << "B"_mst; }
//! Check whether this script can always be satisfied in a non-malleable way.
bool IsNonMalleable() const { return GetType() << "m"_mst; }
//! Check whether this script always needs a signature.
bool NeedsSignature() const { return GetType() << "s"_mst; }
//! Check whether there is no satisfaction path that contains both timelocks and heightlocks
bool CheckTimeLocksMix() const { return GetType() << "k"_mst; }
//! Whether successful non-malleable satisfactions are guaranteed to be valid.
bool ValidSatisfactions() const { return IsValid() && CheckOpsLimit() && CheckStackSize(); }
//! Whether the apparent policy of this node matches its script semantics.
bool IsSane() const { return ValidSatisfactions() && IsNonMalleable() && CheckTimeLocksMix(); }
//! Check whether this node is safe as a script on its own.
bool IsSaneTopLevel() const { return IsValidTopLevel() && IsSane() && NeedsSignature(); }
//! Equality testing.
bool operator==(const Node<Key>& arg) const { return Compare(*this, arg) == 0; }
// Constructors with various argument combinations.
Node(Fragment nt, std::vector<NodeRef<Key>> sub, std::vector<unsigned char> arg, uint32_t val = 0) : fragment(nt), k(val), data(std::move(arg)), subs(std::move(sub)), ops(CalcOps()), ss(CalcStackSize()), typ(CalcType()), scriptlen(CalcScriptLen()) {}
Node(Fragment nt, std::vector<unsigned char> arg, uint32_t val = 0) : fragment(nt), k(val), data(std::move(arg)), ops(CalcOps()), ss(CalcStackSize()), typ(CalcType()), scriptlen(CalcScriptLen()) {}
Node(Fragment nt, std::vector<NodeRef<Key>> sub, std::vector<Key> key, uint32_t val = 0) : fragment(nt), k(val), keys(std::move(key)), subs(std::move(sub)), ops(CalcOps()), ss(CalcStackSize()), typ(CalcType()), scriptlen(CalcScriptLen()) {}
Node(Fragment nt, std::vector<Key> key, uint32_t val = 0) : fragment(nt), k(val), keys(std::move(key)), ops(CalcOps()), ss(CalcStackSize()), typ(CalcType()), scriptlen(CalcScriptLen()) {}
Node(Fragment nt, std::vector<NodeRef<Key>> sub, uint32_t val = 0) : fragment(nt), k(val), subs(std::move(sub)), ops(CalcOps()), ss(CalcStackSize()), typ(CalcType()), scriptlen(CalcScriptLen()) {}
Node(Fragment nt, uint32_t val = 0) : fragment(nt), k(val), ops(CalcOps()), ss(CalcStackSize()), typ(CalcType()), scriptlen(CalcScriptLen()) {}
};
namespace internal {
enum class ParseContext {
/** An expression which may be begin with wrappers followed by a colon. */
WRAPPED_EXPR,
/** A miniscript expression which does not begin with wrappers. */
EXPR,
/** SWAP wraps the top constructed node with s: */
SWAP,
/** ALT wraps the top constructed node with a: */
ALT,
/** CHECK wraps the top constructed node with c: */
CHECK,
/** DUP_IF wraps the top constructed node with d: */
DUP_IF,
/** VERIFY wraps the top constructed node with v: */
VERIFY,
/** NON_ZERO wraps the top constructed node with j: */
NON_ZERO,
/** ZERO_NOTEQUAL wraps the top constructed node with n: */
ZERO_NOTEQUAL,
/** WRAP_U will construct an or_i(X,0) node from the top constructed node. */
WRAP_U,
/** WRAP_T will construct an and_v(X,1) node from the top constructed node. */
WRAP_T,
/** AND_N will construct an andor(X,Y,0) node from the last two constructed nodes. */
AND_N,
/** AND_V will construct an and_v node from the last two constructed nodes. */
AND_V,
/** AND_B will construct an and_b node from the last two constructed nodes. */
AND_B,
/** ANDOR will construct an andor node from the last three constructed nodes. */
ANDOR,
/** OR_B will construct an or_b node from the last two constructed nodes. */
OR_B,
/** OR_C will construct an or_c node from the last two constructed nodes. */
OR_C,
/** OR_D will construct an or_d node from the last two constructed nodes. */
OR_D,
/** OR_I will construct an or_i node from the last two constructed nodes. */
OR_I,
/** THRESH will read a wrapped expression, and then look for a COMMA. If
* no comma follows, it will construct a thresh node from the appropriate
* number of constructed children. Otherwise, it will recurse with another
* THRESH. */
THRESH,
/** COMMA expects the next element to be ',' and fails if not. */
COMMA,
/** CLOSE_BRACKET expects the next element to be ')' and fails if not. */
CLOSE_BRACKET,
};
int FindNextChar(Span<const char> in, const char m);
/** Parse a key string ending with a ')' or ','. */
template<typename Key, typename Ctx>
std::optional<std::pair<Key, int>> ParseKeyEnd(Span<const char> in, const Ctx& ctx)
{
int key_size = FindNextChar(in, ')');
if (key_size < 1) return {};
auto key = ctx.FromString(in.begin(), in.begin() + key_size);
if (!key) return {};
return {{std::move(*key), key_size}};
}
/** Parse a hex string ending at the end of the fragment's text representation. */
template<typename Ctx>
std::optional<std::pair<std::vector<unsigned char>, int>> ParseHexStrEnd(Span<const char> in, const size_t expected_size,
const Ctx& ctx)
{
int hash_size = FindNextChar(in, ')');
if (hash_size < 1) return {};
std::string val = std::string(in.begin(), in.begin() + hash_size);
if (!IsHex(val)) return {};
auto hash = ParseHex(val);
if (hash.size() != expected_size) return {};
return {{std::move(hash), hash_size}};
}
/** BuildBack pops the last two elements off `constructed` and wraps them in the specified Fragment */
template<typename Key>
void BuildBack(Fragment nt, std::vector<NodeRef<Key>>& constructed, const bool reverse = false)
{
NodeRef<Key> child = std::move(constructed.back());
constructed.pop_back();
if (reverse) {
constructed.back() = MakeNodeRef<Key>(nt, Vector(std::move(child), std::move(constructed.back())));
} else {
constructed.back() = MakeNodeRef<Key>(nt, Vector(std::move(constructed.back()), std::move(child)));
}
}
//! Parse a miniscript from its textual descriptor form.
template<typename Key, typename Ctx>
inline NodeRef<Key> Parse(Span<const char> in, const Ctx& ctx)
{
using namespace spanparsing;
// The two integers are used to hold state for thresh()
std::vector<std::tuple<ParseContext, int64_t, int64_t>> to_parse;
std::vector<NodeRef<Key>> constructed;
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
while (!to_parse.empty()) {
// Get the current context we are decoding within
auto [cur_context, n, k] = to_parse.back();
to_parse.pop_back();
switch (cur_context) {
case ParseContext::WRAPPED_EXPR: {
int colon_index = -1;
for (int i = 1; i < (int)in.size(); ++i) {
if (in[i] == ':') {
colon_index = i;
break;
}
if (in[i] < 'a' || in[i] > 'z') break;
}
// If there is no colon, this loop won't execute
for (int j = 0; j < colon_index; ++j) {
if (in[j] == 'a') {
to_parse.emplace_back(ParseContext::ALT, -1, -1);
} else if (in[j] == 's') {
to_parse.emplace_back(ParseContext::SWAP, -1, -1);
} else if (in[j] == 'c') {
to_parse.emplace_back(ParseContext::CHECK, -1, -1);
} else if (in[j] == 'd') {
to_parse.emplace_back(ParseContext::DUP_IF, -1, -1);
} else if (in[j] == 'j') {
to_parse.emplace_back(ParseContext::NON_ZERO, -1, -1);
} else if (in[j] == 'n') {
to_parse.emplace_back(ParseContext::ZERO_NOTEQUAL, -1, -1);
} else if (in[j] == 'v') {
to_parse.emplace_back(ParseContext::VERIFY, -1, -1);
} else if (in[j] == 'u') {
to_parse.emplace_back(ParseContext::WRAP_U, -1, -1);
} else if (in[j] == 't') {
to_parse.emplace_back(ParseContext::WRAP_T, -1, -1);
} else if (in[j] == 'l') {
// The l: wrapper is equivalent to or_i(0,X)
constructed.push_back(MakeNodeRef<Key>(Fragment::JUST_0));
to_parse.emplace_back(ParseContext::OR_I, -1, -1);
} else {
return {};
}
}
to_parse.emplace_back(ParseContext::EXPR, -1, -1);
in = in.subspan(colon_index + 1);
break;
}
case ParseContext::EXPR: {
if (Const("0", in)) {
constructed.push_back(MakeNodeRef<Key>(Fragment::JUST_0));
} else if (Const("1", in)) {
constructed.push_back(MakeNodeRef<Key>(Fragment::JUST_1));
} else if (Const("pk(", in)) {
auto res = ParseKeyEnd<Key, Ctx>(in, ctx);
if (!res) return {};
auto& [key, key_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::WRAP_C, Vector(MakeNodeRef<Key>(Fragment::PK_K, Vector(std::move(key))))));
in = in.subspan(key_size + 1);
} else if (Const("pkh(", in)) {
auto res = ParseKeyEnd<Key>(in, ctx);
if (!res) return {};
auto& [key, key_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::WRAP_C, Vector(MakeNodeRef<Key>(Fragment::PK_H, Vector(std::move(key))))));
in = in.subspan(key_size + 1);
} else if (Const("pk_k(", in)) {
auto res = ParseKeyEnd<Key>(in, ctx);
if (!res) return {};
auto& [key, key_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::PK_K, Vector(std::move(key))));
in = in.subspan(key_size + 1);
} else if (Const("pk_h(", in)) {
auto res = ParseKeyEnd<Key>(in, ctx);
if (!res) return {};
auto& [key, key_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::PK_H, Vector(std::move(key))));
in = in.subspan(key_size + 1);
} else if (Const("sha256(", in)) {
auto res = ParseHexStrEnd(in, 32, ctx);
if (!res) return {};
auto& [hash, hash_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::SHA256, std::move(hash)));
in = in.subspan(hash_size + 1);
} else if (Const("ripemd160(", in)) {
auto res = ParseHexStrEnd(in, 20, ctx);
if (!res) return {};
auto& [hash, hash_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::RIPEMD160, std::move(hash)));
in = in.subspan(hash_size + 1);
} else if (Const("hash256(", in)) {
auto res = ParseHexStrEnd(in, 32, ctx);
if (!res) return {};
auto& [hash, hash_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::HASH256, std::move(hash)));
in = in.subspan(hash_size + 1);
} else if (Const("hash160(", in)) {
auto res = ParseHexStrEnd(in, 20, ctx);
if (!res) return {};
auto& [hash, hash_size] = *res;
constructed.push_back(MakeNodeRef<Key>(Fragment::HASH160, std::move(hash)));
in = in.subspan(hash_size + 1);
} else if (Const("after(", in)) {
int arg_size = FindNextChar(in, ')');
if (arg_size < 1) return {};
int64_t num;
if (!ParseInt64(std::string(in.begin(), in.begin() + arg_size), &num)) return {};
if (num < 1 || num >= 0x80000000L) return {};
constructed.push_back(MakeNodeRef<Key>(Fragment::AFTER, num));
in = in.subspan(arg_size + 1);
} else if (Const("older(", in)) {
int arg_size = FindNextChar(in, ')');
if (arg_size < 1) return {};
int64_t num;
if (!ParseInt64(std::string(in.begin(), in.begin() + arg_size), &num)) return {};
if (num < 1 || num >= 0x80000000L) return {};
constructed.push_back(MakeNodeRef<Key>(Fragment::OLDER, num));
in = in.subspan(arg_size + 1);
} else if (Const("multi(", in)) {
// Get threshold
int next_comma = FindNextChar(in, ',');
if (next_comma < 1) return {};
if (!ParseInt64(std::string(in.begin(), in.begin() + next_comma), &k)) return {};
in = in.subspan(next_comma + 1);
// Get keys
std::vector<Key> keys;
while (next_comma != -1) {
next_comma = FindNextChar(in, ',');
int key_length = (next_comma == -1) ? FindNextChar(in, ')') : next_comma;
if (key_length < 1) return {};
auto key = ctx.FromString(in.begin(), in.begin() + key_length);
if (!key) return {};
keys.push_back(std::move(*key));
in = in.subspan(key_length + 1);
}
if (keys.size() < 1 || keys.size() > 20) return {};
if (k < 1 || k > (int64_t)keys.size()) return {};
constructed.push_back(MakeNodeRef<Key>(Fragment::MULTI, std::move(keys), k));
} else if (Const("thresh(", in)) {
int next_comma = FindNextChar(in, ',');
if (next_comma < 1) return {};
if (!ParseInt64(std::string(in.begin(), in.begin() + next_comma), &k)) return {};
if (k < 1) return {};
in = in.subspan(next_comma + 1);
// n = 1 here because we read the first WRAPPED_EXPR before reaching THRESH
to_parse.emplace_back(ParseContext::THRESH, 1, k);
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
} else if (Const("andor(", in)) {
to_parse.emplace_back(ParseContext::ANDOR, -1, -1);
to_parse.emplace_back(ParseContext::CLOSE_BRACKET, -1, -1);
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
to_parse.emplace_back(ParseContext::COMMA, -1, -1);
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
to_parse.emplace_back(ParseContext::COMMA, -1, -1);
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
} else {
if (Const("and_n(", in)) {
to_parse.emplace_back(ParseContext::AND_N, -1, -1);
} else if (Const("and_b(", in)) {
to_parse.emplace_back(ParseContext::AND_B, -1, -1);
} else if (Const("and_v(", in)) {
to_parse.emplace_back(ParseContext::AND_V, -1, -1);
} else if (Const("or_b(", in)) {
to_parse.emplace_back(ParseContext::OR_B, -1, -1);
} else if (Const("or_c(", in)) {
to_parse.emplace_back(ParseContext::OR_C, -1, -1);
} else if (Const("or_d(", in)) {
to_parse.emplace_back(ParseContext::OR_D, -1, -1);
} else if (Const("or_i(", in)) {
to_parse.emplace_back(ParseContext::OR_I, -1, -1);
} else {
return {};
}
to_parse.emplace_back(ParseContext::CLOSE_BRACKET, -1, -1);
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
to_parse.emplace_back(ParseContext::COMMA, -1, -1);
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
}
break;
}
case ParseContext::ALT: {
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_A, Vector(std::move(constructed.back())));
break;
}
case ParseContext::SWAP: {
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_S, Vector(std::move(constructed.back())));
break;
}
case ParseContext::CHECK: {
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_C, Vector(std::move(constructed.back())));
break;
}
case ParseContext::DUP_IF: {
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_D, Vector(std::move(constructed.back())));
break;
}
case ParseContext::NON_ZERO: {
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_J, Vector(std::move(constructed.back())));
break;
}
case ParseContext::ZERO_NOTEQUAL: {
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_N, Vector(std::move(constructed.back())));
break;
}
case ParseContext::VERIFY: {
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_V, Vector(std::move(constructed.back())));
break;
}
case ParseContext::WRAP_U: {
constructed.back() = MakeNodeRef<Key>(Fragment::OR_I, Vector(std::move(constructed.back()), MakeNodeRef<Key>(Fragment::JUST_0)));
break;
}
case ParseContext::WRAP_T: {
constructed.back() = MakeNodeRef<Key>(Fragment::AND_V, Vector(std::move(constructed.back()), MakeNodeRef<Key>(Fragment::JUST_1)));
break;
}
case ParseContext::AND_B: {
BuildBack(Fragment::AND_B, constructed);
break;
}
case ParseContext::AND_N: {
auto mid = std::move(constructed.back());
constructed.pop_back();
constructed.back() = MakeNodeRef<Key>(Fragment::ANDOR, Vector(std::move(constructed.back()), std::move(mid), MakeNodeRef<Key>(Fragment::JUST_0)));
break;
}
case ParseContext::AND_V: {
BuildBack(Fragment::AND_V, constructed);
break;
}
case ParseContext::OR_B: {
BuildBack(Fragment::OR_B, constructed);
break;
}
case ParseContext::OR_C: {
BuildBack(Fragment::OR_C, constructed);
break;
}
case ParseContext::OR_D: {
BuildBack(Fragment::OR_D, constructed);
break;
}
case ParseContext::OR_I: {
BuildBack(Fragment::OR_I, constructed);
break;
}
case ParseContext::ANDOR: {
auto right = std::move(constructed.back());
constructed.pop_back();
auto mid = std::move(constructed.back());
constructed.pop_back();
constructed.back() = MakeNodeRef<Key>(Fragment::ANDOR, Vector(std::move(constructed.back()), std::move(mid), std::move(right)));
break;
}
case ParseContext::THRESH: {
if (in.size() < 1) return {};
if (in[0] == ',') {
in = in.subspan(1);
to_parse.emplace_back(ParseContext::THRESH, n+1, k);
to_parse.emplace_back(ParseContext::WRAPPED_EXPR, -1, -1);
} else if (in[0] == ')') {
if (k > n) return {};
in = in.subspan(1);
// Children are constructed in reverse order, so iterate from end to beginning
std::vector<NodeRef<Key>> subs;
for (int i = 0; i < n; ++i) {
subs.push_back(std::move(constructed.back()));
constructed.pop_back();
}
std::reverse(subs.begin(), subs.end());
constructed.push_back(MakeNodeRef<Key>(Fragment::THRESH, std::move(subs), k));
} else {
return {};
}
break;
}
case ParseContext::COMMA: {
if (in.size() < 1 || in[0] != ',') return {};
in = in.subspan(1);
break;
}
case ParseContext::CLOSE_BRACKET: {
if (in.size() < 1 || in[0] != ')') return {};
in = in.subspan(1);
break;
}
}
}
// Sanity checks on the produced miniscript
assert(constructed.size() == 1);
if (in.size() > 0) return {};
const NodeRef<Key> tl_node = std::move(constructed.front());
if (!tl_node->IsValidTopLevel()) return {};
return tl_node;
}
/** Decode a script into opcode/push pairs.
*
* Construct a vector with one element per opcode in the script, in reverse order.
* Each element is a pair consisting of the opcode, as well as the data pushed by
* the opcode (including OP_n), if any. OP_CHECKSIGVERIFY, OP_CHECKMULTISIGVERIFY,
* and OP_EQUALVERIFY are decomposed into OP_CHECKSIG, OP_CHECKMULTISIG, OP_EQUAL
* respectively, plus OP_VERIFY.
*/
std::optional<std::vector<std::pair<opcodetype, std::vector<unsigned char>>>> DecomposeScript(const CScript& script);
/** Determine whether the passed pair (created by DecomposeScript) is pushing a number. */
std::optional<int64_t> ParseScriptNumber(const std::pair<opcodetype, std::vector<unsigned char>>& in);
enum class DecodeContext {
/** A single expression of type B, K, or V. Specifically, this can't be an
* and_v or an expression of type W (a: and s: wrappers). */
SINGLE_BKV_EXPR,
/** Potentially multiple SINGLE_BKV_EXPRs as children of (potentially multiple)
* and_v expressions. Syntactic sugar for MAYBE_AND_V + SINGLE_BKV_EXPR. */
BKV_EXPR,
/** An expression of type W (a: or s: wrappers). */
W_EXPR,
/** SWAP expects the next element to be OP_SWAP (inside a W-type expression that
* didn't end with FROMALTSTACK), and wraps the top of the constructed stack
* with s: */
SWAP,
/** ALT expects the next element to be TOALTSTACK (we must have already read a
* FROMALTSTACK earlier), and wraps the top of the constructed stack with a: */
ALT,
/** CHECK wraps the top constructed node with c: */
CHECK,
/** DUP_IF wraps the top constructed node with d: */
DUP_IF,
/** VERIFY wraps the top constructed node with v: */
VERIFY,
/** NON_ZERO wraps the top constructed node with j: */
NON_ZERO,
/** ZERO_NOTEQUAL wraps the top constructed node with n: */
ZERO_NOTEQUAL,
/** MAYBE_AND_V will check if the next part of the script could be a valid
* miniscript sub-expression, and if so it will push AND_V and SINGLE_BKV_EXPR
* to decode it and construct the and_v node. This is recursive, to deal with
* multiple and_v nodes inside each other. */
MAYBE_AND_V,
/** AND_V will construct an and_v node from the last two constructed nodes. */
AND_V,
/** AND_B will construct an and_b node from the last two constructed nodes. */
AND_B,
/** ANDOR will construct an andor node from the last three constructed nodes. */
ANDOR,
/** OR_B will construct an or_b node from the last two constructed nodes. */
OR_B,
/** OR_C will construct an or_c node from the last two constructed nodes. */
OR_C,
/** OR_D will construct an or_d node from the last two constructed nodes. */
OR_D,
/** In a thresh expression, all sub-expressions other than the first are W-type,
* and end in OP_ADD. THRESH_W will check for this OP_ADD and either push a W_EXPR
* or a SINGLE_BKV_EXPR and jump to THRESH_E accordingly. */
THRESH_W,
/** THRESH_E constructs a thresh node from the appropriate number of constructed
* children. */
THRESH_E,
/** ENDIF signals that we are inside some sort of OP_IF structure, which could be
* or_d, or_c, or_i, andor, d:, or j: wrapper, depending on what follows. We read
* a BKV_EXPR and then deal with the next opcode case-by-case. */
ENDIF,
/** If, inside an ENDIF context, we find an OP_NOTIF before finding an OP_ELSE,
* we could either be in an or_d or an or_c node. We then check for IFDUP to
* distinguish these cases. */
ENDIF_NOTIF,
/** If, inside an ENDIF context, we find an OP_ELSE, then we could be in either an
* or_i or an andor node. Read the next BKV_EXPR and find either an OP_IF or an
* OP_NOTIF. */
ENDIF_ELSE,
};
//! Parse a miniscript from a bitcoin script
template<typename Key, typename Ctx, typename I>
inline NodeRef<Key> DecodeScript(I& in, I last, const Ctx& ctx)
{
// The two integers are used to hold state for thresh()
std::vector<std::tuple<DecodeContext, int64_t, int64_t>> to_parse;
std::vector<NodeRef<Key>> constructed;
// This is the top level, so we assume the type is B
// (in particular, disallowing top level W expressions)
to_parse.emplace_back(DecodeContext::BKV_EXPR, -1, -1);
while (!to_parse.empty()) {
// Exit early if the Miniscript is not going to be valid.
if (!constructed.empty() && !constructed.back()->IsValid()) return {};
// Get the current context we are decoding within
auto [cur_context, n, k] = to_parse.back();
to_parse.pop_back();
switch(cur_context) {
case DecodeContext::SINGLE_BKV_EXPR: {
if (in >= last) return {};
// Constants
if (in[0].first == OP_1) {
++in;
constructed.push_back(MakeNodeRef<Key>(Fragment::JUST_1));
break;
}
if (in[0].first == OP_0) {
++in;
constructed.push_back(MakeNodeRef<Key>(Fragment::JUST_0));
break;
}
// Public keys
if (in[0].second.size() == 33) {
auto key = ctx.FromPKBytes(in[0].second.begin(), in[0].second.end());
if (!key) return {};
++in;
constructed.push_back(MakeNodeRef<Key>(Fragment::PK_K, Vector(std::move(*key))));
break;
}
if (last - in >= 5 && in[0].first == OP_VERIFY && in[1].first == OP_EQUAL && in[3].first == OP_HASH160 && in[4].first == OP_DUP && in[2].second.size() == 20) {
auto key = ctx.FromPKHBytes(in[2].second.begin(), in[2].second.end());
if (!key) return {};
in += 5;
constructed.push_back(MakeNodeRef<Key>(Fragment::PK_H, Vector(std::move(*key))));
break;
}
// Time locks
std::optional<int64_t> num;
if (last - in >= 2 && in[0].first == OP_CHECKSEQUENCEVERIFY && (num = ParseScriptNumber(in[1]))) {
in += 2;
if (*num < 1 || *num > 0x7FFFFFFFL) return {};
constructed.push_back(MakeNodeRef<Key>(Fragment::OLDER, *num));
break;
}
if (last - in >= 2 && in[0].first == OP_CHECKLOCKTIMEVERIFY && (num = ParseScriptNumber(in[1]))) {
in += 2;
if (num < 1 || num > 0x7FFFFFFFL) return {};
constructed.push_back(MakeNodeRef<Key>(Fragment::AFTER, *num));
break;
}
// Hashes
if (last - in >= 7 && in[0].first == OP_EQUAL && in[3].first == OP_VERIFY && in[4].first == OP_EQUAL && (num = ParseScriptNumber(in[5])) && num == 32 && in[6].first == OP_SIZE) {
if (in[2].first == OP_SHA256 && in[1].second.size() == 32) {
constructed.push_back(MakeNodeRef<Key>(Fragment::SHA256, in[1].second));
in += 7;
break;
} else if (in[2].first == OP_RIPEMD160 && in[1].second.size() == 20) {
constructed.push_back(MakeNodeRef<Key>(Fragment::RIPEMD160, in[1].second));
in += 7;
break;
} else if (in[2].first == OP_HASH256 && in[1].second.size() == 32) {
constructed.push_back(MakeNodeRef<Key>(Fragment::HASH256, in[1].second));
in += 7;
break;
} else if (in[2].first == OP_HASH160 && in[1].second.size() == 20) {
constructed.push_back(MakeNodeRef<Key>(Fragment::HASH160, in[1].second));
in += 7;
break;
}
}
// Multi
if (last - in >= 3 && in[0].first == OP_CHECKMULTISIG) {
std::vector<Key> keys;
const auto n = ParseScriptNumber(in[1]);
if (!n || last - in < 3 + *n) return {};
if (*n < 1 || *n > 20) return {};
for (int i = 0; i < *n; ++i) {
if (in[2 + i].second.size() != 33) return {};
auto key = ctx.FromPKBytes(in[2 + i].second.begin(), in[2 + i].second.end());
if (!key) return {};
keys.push_back(std::move(*key));
}
const auto k = ParseScriptNumber(in[2 + *n]);
if (!k || *k < 1 || *k > *n) return {};
in += 3 + *n;
std::reverse(keys.begin(), keys.end());
constructed.push_back(MakeNodeRef<Key>(Fragment::MULTI, std::move(keys), *k));
break;
}
/** In the following wrappers, we only need to push SINGLE_BKV_EXPR rather
* than BKV_EXPR, because and_v commutes with these wrappers. For example,
* c:and_v(X,Y) produces the same script as and_v(X,c:Y). */
// c: wrapper
if (in[0].first == OP_CHECKSIG) {
++in;
to_parse.emplace_back(DecodeContext::CHECK, -1, -1);
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
break;
}
// v: wrapper
if (in[0].first == OP_VERIFY) {
++in;
to_parse.emplace_back(DecodeContext::VERIFY, -1, -1);
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
break;
}
// n: wrapper
if (in[0].first == OP_0NOTEQUAL) {
++in;
to_parse.emplace_back(DecodeContext::ZERO_NOTEQUAL, -1, -1);
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
break;
}
// Thresh
if (last - in >= 3 && in[0].first == OP_EQUAL && (num = ParseScriptNumber(in[1]))) {
if (*num < 1) return {};
in += 2;
to_parse.emplace_back(DecodeContext::THRESH_W, 0, *num);
break;
}
// OP_ENDIF can be WRAP_J, WRAP_D, ANDOR, OR_C, OR_D, or OR_I
if (in[0].first == OP_ENDIF) {
++in;
to_parse.emplace_back(DecodeContext::ENDIF, -1, -1);
to_parse.emplace_back(DecodeContext::BKV_EXPR, -1, -1);
break;
}
/** In and_b and or_b nodes, we only look for SINGLE_BKV_EXPR, because
* or_b(and_v(X,Y),Z) has script [X] [Y] [Z] OP_BOOLOR, the same as
* and_v(X,or_b(Y,Z)). In this example, the former of these is invalid as
* miniscript, while the latter is valid. So we leave the and_v "outside"
* while decoding. */
// and_b
if (in[0].first == OP_BOOLAND) {
++in;
to_parse.emplace_back(DecodeContext::AND_B, -1, -1);
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
to_parse.emplace_back(DecodeContext::W_EXPR, -1, -1);
break;
}
// or_b
if (in[0].first == OP_BOOLOR) {
++in;
to_parse.emplace_back(DecodeContext::OR_B, -1, -1);
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
to_parse.emplace_back(DecodeContext::W_EXPR, -1, -1);
break;
}
// Unrecognised expression
return {};
}
case DecodeContext::BKV_EXPR: {
to_parse.emplace_back(DecodeContext::MAYBE_AND_V, -1, -1);
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
break;
}
case DecodeContext::W_EXPR: {
// a: wrapper
if (in >= last) return {};
if (in[0].first == OP_FROMALTSTACK) {
++in;
to_parse.emplace_back(DecodeContext::ALT, -1, -1);
} else {
to_parse.emplace_back(DecodeContext::SWAP, -1, -1);
}
to_parse.emplace_back(DecodeContext::BKV_EXPR, -1, -1);
break;
}
case DecodeContext::MAYBE_AND_V: {
// If we reach a potential AND_V top-level, check if the next part of the script could be another AND_V child
// These op-codes cannot end any well-formed miniscript so cannot be used in an and_v node.
if (in < last && in[0].first != OP_IF && in[0].first != OP_ELSE && in[0].first != OP_NOTIF && in[0].first != OP_TOALTSTACK && in[0].first != OP_SWAP) {
to_parse.emplace_back(DecodeContext::AND_V, -1, -1);
// BKV_EXPR can contain more AND_V nodes
to_parse.emplace_back(DecodeContext::BKV_EXPR, -1, -1);
}
break;
}
case DecodeContext::SWAP: {
if (in >= last || in[0].first != OP_SWAP || constructed.empty()) return {};
++in;
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_S, Vector(std::move(constructed.back())));
break;
}
case DecodeContext::ALT: {
if (in >= last || in[0].first != OP_TOALTSTACK || constructed.empty()) return {};
++in;
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_A, Vector(std::move(constructed.back())));
break;
}
case DecodeContext::CHECK: {
if (constructed.empty()) return {};
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_C, Vector(std::move(constructed.back())));
break;
}
case DecodeContext::DUP_IF: {
if (constructed.empty()) return {};
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_D, Vector(std::move(constructed.back())));
break;
}
case DecodeContext::VERIFY: {
if (constructed.empty()) return {};
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_V, Vector(std::move(constructed.back())));
break;
}
case DecodeContext::NON_ZERO: {
if (constructed.empty()) return {};
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_J, Vector(std::move(constructed.back())));
break;
}
case DecodeContext::ZERO_NOTEQUAL: {
if (constructed.empty()) return {};
constructed.back() = MakeNodeRef<Key>(Fragment::WRAP_N, Vector(std::move(constructed.back())));
break;
}
case DecodeContext::AND_V: {
if (constructed.size() < 2) return {};
BuildBack(Fragment::AND_V, constructed, /*reverse=*/true);
break;
}
case DecodeContext::AND_B: {
if (constructed.size() < 2) return {};
BuildBack(Fragment::AND_B, constructed, /*reverse=*/true);
break;
}
case DecodeContext::OR_B: {
if (constructed.size() < 2) return {};
BuildBack(Fragment::OR_B, constructed, /*reverse=*/true);
break;
}
case DecodeContext::OR_C: {
if (constructed.size() < 2) return {};
BuildBack(Fragment::OR_C, constructed, /*reverse=*/true);
break;
}
case DecodeContext::OR_D: {
if (constructed.size() < 2) return {};
BuildBack(Fragment::OR_D, constructed, /*reverse=*/true);
break;
}
case DecodeContext::ANDOR: {
if (constructed.size() < 3) return {};
NodeRef<Key> left = std::move(constructed.back());
constructed.pop_back();
NodeRef<Key> right = std::move(constructed.back());
constructed.pop_back();
NodeRef<Key> mid = std::move(constructed.back());
constructed.back() = MakeNodeRef<Key>(Fragment::ANDOR, Vector(std::move(left), std::move(mid), std::move(right)));
break;
}
case DecodeContext::THRESH_W: {
if (in >= last) return {};
if (in[0].first == OP_ADD) {
++in;
to_parse.emplace_back(DecodeContext::THRESH_W, n+1, k);
to_parse.emplace_back(DecodeContext::W_EXPR, -1, -1);
} else {
to_parse.emplace_back(DecodeContext::THRESH_E, n+1, k);
// All children of thresh have type modifier d, so cannot be and_v
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
}
break;
}
case DecodeContext::THRESH_E: {
if (k < 1 || k > n || constructed.size() < static_cast<size_t>(n)) return {};
std::vector<NodeRef<Key>> subs;
for (int i = 0; i < n; ++i) {
NodeRef<Key> sub = std::move(constructed.back());
constructed.pop_back();
subs.push_back(std::move(sub));
}
constructed.push_back(MakeNodeRef<Key>(Fragment::THRESH, std::move(subs), k));
break;
}
case DecodeContext::ENDIF: {
if (in >= last) return {};
// could be andor or or_i
if (in[0].first == OP_ELSE) {
++in;
to_parse.emplace_back(DecodeContext::ENDIF_ELSE, -1, -1);
to_parse.emplace_back(DecodeContext::BKV_EXPR, -1, -1);
}
// could be j: or d: wrapper
else if (in[0].first == OP_IF) {
if (last - in >= 2 && in[1].first == OP_DUP) {
in += 2;
to_parse.emplace_back(DecodeContext::DUP_IF, -1, -1);
} else if (last - in >= 3 && in[1].first == OP_0NOTEQUAL && in[2].first == OP_SIZE) {
in += 3;
to_parse.emplace_back(DecodeContext::NON_ZERO, -1, -1);
}
else {
return {};
}
// could be or_c or or_d
} else if (in[0].first == OP_NOTIF) {
++in;
to_parse.emplace_back(DecodeContext::ENDIF_NOTIF, -1, -1);
}
else {
return {};
}
break;
}
case DecodeContext::ENDIF_NOTIF: {
if (in >= last) return {};
if (in[0].first == OP_IFDUP) {
++in;
to_parse.emplace_back(DecodeContext::OR_D, -1, -1);
} else {
to_parse.emplace_back(DecodeContext::OR_C, -1, -1);
}
// or_c and or_d both require X to have type modifier d so, can't contain and_v
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
break;
}
case DecodeContext::ENDIF_ELSE: {
if (in >= last) return {};
if (in[0].first == OP_IF) {
++in;
BuildBack(Fragment::OR_I, constructed, /*reverse=*/true);
} else if (in[0].first == OP_NOTIF) {
++in;
to_parse.emplace_back(DecodeContext::ANDOR, -1, -1);
// andor requires X to have type modifier d, so it can't be and_v
to_parse.emplace_back(DecodeContext::SINGLE_BKV_EXPR, -1, -1);
} else {
return {};
}
break;
}
}
}
if (constructed.size() != 1) return {};
const NodeRef<Key> tl_node = std::move(constructed.front());
// Note that due to how ComputeType works (only assign the type to the node if the
// subs' types are valid) this would fail if any node of tree is badly typed.
if (!tl_node->IsValidTopLevel()) return {};
return tl_node;
}
} // namespace internal
template<typename Ctx>
inline NodeRef<typename Ctx::Key> FromString(const std::string& str, const Ctx& ctx) {
return internal::Parse<typename Ctx::Key>(str, ctx);
}
template<typename Ctx>
inline NodeRef<typename Ctx::Key> FromScript(const CScript& script, const Ctx& ctx) {
using namespace internal;
auto decomposed = DecomposeScript(script);
if (!decomposed) return {};
auto it = decomposed->begin();
auto ret = DecodeScript<typename Ctx::Key>(it, decomposed->end(), ctx);
if (!ret) return {};
if (it != decomposed->end()) return {};
return ret;
}
} // namespace miniscript
#endif // BITCOIN_SCRIPT_MINISCRIPT_H
|