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
1665
1666
1667
1668
1669
1670
1671
1672
1673
1674
1675
1676
1677
1678
1679
1680
1681
1682
1683
1684
1685
1686
1687
1688
1689
1690
1691
1692
1693
1694
1695
1696
1697
1698
1699
1700
1701
1702
1703
1704
1705
1706
1707
1708
1709
1710
1711
1712
1713
1714
1715
1716
1717
1718
1719
1720
1721
1722
1723
1724
1725
1726
1727
1728
1729
1730
1731
1732
1733
1734
1735
1736
1737
1738
1739
1740
1741
1742
1743
1744
1745
1746
1747
1748
1749
1750
1751
1752
1753
1754
1755
1756
1757
1758
1759
1760
1761
1762
1763
1764
1765
1766
1767
1768
1769
1770
1771
1772
1773
1774
1775
1776
1777
1778
1779
1780
1781
1782
1783
1784
1785
1786
1787
1788
1789
1790
1791
1792
1793
1794
1795
1796
1797
1798
1799
1800
1801
1802
1803
1804
1805
1806
1807
1808
1809
1810
1811
1812
1813
1814
1815
1816
1817
1818
1819
1820
1821
1822
1823
1824
1825
1826
1827
1828
1829
1830
1831
1832
1833
1834
1835
1836
1837
1838
1839
1840
1841
1842
1843
1844
1845
1846
1847
1848
1849
1850
1851
1852
1853
1854
1855
1856
1857
1858
1859
1860
1861
1862
1863
1864
1865
1866
1867
1868
1869
1870
1871
1872
1873
1874
1875
1876
1877
1878
1879
1880
1881
1882
1883
1884
1885
1886
1887
1888
1889
1890
1891
1892
1893
1894
1895
1896
1897
1898
1899
1900
1901
1902
1903
1904
1905
1906
1907
1908
1909
1910
1911
1912
1913
1914
1915
1916
1917
1918
1919
1920
1921
1922
1923
1924
1925
1926
1927
1928
1929
1930
1931
1932
1933
1934
1935
1936
1937
1938
1939
1940
1941
1942
1943
1944
1945
1946
1947
1948
1949
1950
1951
1952
1953
1954
1955
1956
1957
1958
1959
1960
1961
1962
1963
1964
1965
1966
1967
1968
1969
1970
1971
1972
1973
1974
1975
1976
1977
1978
1979
1980
1981
1982
1983
1984
1985
1986
1987
1988
1989
1990
1991
1992
1993
1994
1995
1996
1997
1998
1999
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
2014
2015
2016
2017
2018
2019
2020
2021
2022
2023
2024
2025
2026
2027
2028
2029
2030
2031
2032
2033
2034
2035
2036
2037
2038
2039
2040
2041
2042
2043
2044
2045
2046
2047
2048
2049
2050
2051
2052
2053
2054
2055
2056
2057
2058
2059
2060
2061
2062
2063
2064
2065
2066
2067
2068
2069
2070
2071
2072
2073
2074
2075
2076
2077
2078
2079
2080
2081
2082
2083
2084
2085
2086
2087
2088
2089
2090
2091
2092
2093
2094
2095
2096
2097
2098
2099
2100
2101
2102
2103
2104
2105
2106
2107
2108
2109
2110
2111
2112
2113
2114
2115
2116
2117
2118
2119
2120
2121
2122
2123
2124
2125
2126
2127
2128
2129
2130
2131
2132
2133
2134
2135
2136
2137
2138
2139
2140
2141
2142
2143
2144
2145
2146
2147
2148
2149
2150
2151
2152
2153
2154
2155
2156
2157
2158
2159
2160
2161
2162
2163
2164
2165
2166
2167
2168
2169
2170
2171
2172
2173
2174
2175
2176
2177
2178
2179
2180
2181
2182
2183
2184
2185
2186
2187
2188
2189
2190
2191
2192
2193
2194
2195
2196
2197
2198
2199
2200
2201
2202
2203
2204
2205
2206
2207
2208
2209
2210
2211
2212
2213
2214
2215
2216
2217
2218
2219
2220
2221
2222
2223
2224
2225
2226
2227
2228
2229
2230
2231
2232
2233
2234
2235
2236
2237
2238
2239
2240
2241
2242
2243
2244
2245
2246
2247
2248
2249
2250
2251
2252
2253
2254
2255
2256
2257
2258
2259
2260
2261
2262
2263
2264
2265
2266
2267
2268
2269
2270
2271
2272
2273
2274
2275
2276
2277
2278
2279
2280
2281
2282
2283
2284
2285
2286
2287
2288
2289
2290
2291
2292
2293
2294
2295
2296
2297
2298
2299
2300
2301
2302
2303
2304
2305
2306
2307
2308
2309
2310
2311
2312
2313
2314
2315
2316
2317
2318
2319
2320
2321
2322
2323
2324
2325
2326
2327
2328
2329
2330
2331
2332
#[cfg(feature = "std")]
use core::fmt;
#[cfg(feature = "std")]
use core::iter;
use core::mem;
use core::slice;

#[cfg(feature = "std")]
use byteorder::{BigEndian, LittleEndian};
use byteorder::{ByteOrder, NativeEndian};
#[cfg(feature = "std")]
use regex_syntax::ParserBuilder;

use classes::ByteClasses;
#[cfg(feature = "std")]
use determinize::Determinizer;
use dfa::DFA;
#[cfg(feature = "std")]
use error::{Error, Result};
#[cfg(feature = "std")]
use minimize::Minimizer;
#[cfg(feature = "std")]
use nfa::{self, NFA};
#[cfg(feature = "std")]
use sparse::SparseDFA;
use state_id::{dead_id, StateID};
#[cfg(feature = "std")]
use state_id::{
    next_state_id, premultiply_overflow_error, write_state_id_bytes,
};

/// The size of the alphabet in a standard DFA.
///
/// Specifically, this length controls the number of transitions present in
/// each DFA state. However, when the byte class optimization is enabled,
/// then each DFA maps the space of all possible 256 byte values to at most
/// 256 distinct equivalence classes. In this case, the number of distinct
/// equivalence classes corresponds to the internal alphabet of the DFA, in the
/// sense that each DFA state has a number of transitions equal to the number
/// of equivalence classes despite supporting matching on all possible byte
/// values.
const ALPHABET_LEN: usize = 256;

/// Masks used in serialization of DFAs.
pub(crate) const MASK_PREMULTIPLIED: u16 = 0b0000_0000_0000_0001;
pub(crate) const MASK_ANCHORED: u16 = 0b0000_0000_0000_0010;

/// A dense table-based deterministic finite automaton (DFA).
///
/// A dense DFA represents the core matching primitive in this crate. That is,
/// logically, all DFAs have a single start state, one or more match states
/// and a transition table that maps the current state and the current byte of
/// input to the next state. A DFA can use this information to implement fast
/// searching. In particular, the use of a dense DFA generally makes the trade
/// off that match speed is the most valuable characteristic, even if building
/// the regex may take significant time *and* space. As such, the processing
/// of every byte of input is done with a small constant number of operations
/// that does not vary with the pattern, its size or the size of the alphabet.
/// If your needs don't line up with this trade off, then a dense DFA may not
/// be an adequate solution to your problem.
///
/// In contrast, a [sparse DFA](enum.SparseDFA.html) makes the opposite
/// trade off: it uses less space but will execute a variable number of
/// instructions per byte at match time, which makes it slower for matching.
///
/// A DFA can be built using the default configuration via the
/// [`DenseDFA::new`](enum.DenseDFA.html#method.new) constructor. Otherwise,
/// one can configure various aspects via the
/// [`dense::Builder`](dense/struct.Builder.html).
///
/// A single DFA fundamentally supports the following operations:
///
/// 1. Detection of a match.
/// 2. Location of the end of the first possible match.
/// 3. Location of the end of the leftmost-first match.
///
/// A notable absence from the above list of capabilities is the location of
/// the *start* of a match. In order to provide both the start and end of a
/// match, *two* DFAs are required. This functionality is provided by a
/// [`Regex`](struct.Regex.html), which can be built with its basic
/// constructor, [`Regex::new`](struct.Regex.html#method.new), or with
/// a [`RegexBuilder`](struct.RegexBuilder.html).
///
/// # State size
///
/// A `DenseDFA` has two type parameters, `T` and `S`. `T` corresponds to
/// the type of the DFA's transition table while `S` corresponds to the
/// representation used for the DFA's state identifiers as described by the
/// [`StateID`](trait.StateID.html) trait. This type parameter is typically
/// `usize`, but other valid choices provided by this crate include `u8`,
/// `u16`, `u32` and `u64`. The primary reason for choosing a different state
/// identifier representation than the default is to reduce the amount of
/// memory used by a DFA. Note though, that if the chosen representation cannot
/// accommodate the size of your DFA, then building the DFA will fail and
/// return an error.
///
/// While the reduction in heap memory used by a DFA is one reason for choosing
/// a smaller state identifier representation, another possible reason is for
/// decreasing the serialization size of a DFA, as returned by
/// [`to_bytes_little_endian`](enum.DenseDFA.html#method.to_bytes_little_endian),
/// [`to_bytes_big_endian`](enum.DenseDFA.html#method.to_bytes_big_endian)
/// or
/// [`to_bytes_native_endian`](enum.DenseDFA.html#method.to_bytes_native_endian).
///
/// The type of the transition table is typically either `Vec<S>` or `&[S]`,
/// depending on where the transition table is stored.
///
/// # Variants
///
/// This DFA is defined as a non-exhaustive enumeration of different types of
/// dense DFAs. All of these dense DFAs use the same internal representation
/// for the transition table, but they vary in how the transition table is
/// read. A DFA's specific variant depends on the configuration options set via
/// [`dense::Builder`](dense/struct.Builder.html). The default variant is
/// `PremultipliedByteClass`.
///
/// # The `DFA` trait
///
/// This type implements the [`DFA`](trait.DFA.html) trait, which means it
/// can be used for searching. For example:
///
/// ```
/// use regex_automata::{DFA, DenseDFA};
///
/// # fn example() -> Result<(), regex_automata::Error> {
/// let dfa = DenseDFA::new("foo[0-9]+")?;
/// assert_eq!(Some(8), dfa.find(b"foo12345"));
/// # Ok(()) }; example().unwrap()
/// ```
///
/// The `DFA` trait also provides an assortment of other lower level methods
/// for DFAs, such as `start_state` and `next_state`. While these are correctly
/// implemented, it is an anti-pattern to use them in performance sensitive
/// code on the `DenseDFA` type directly. Namely, each implementation requires
/// a branch to determine which type of dense DFA is being used. Instead,
/// this branch should be pushed up a layer in the code since walking the
/// transitions of a DFA is usually a hot path. If you do need to use these
/// lower level methods in performance critical code, then you should match on
/// the variants of this DFA and use each variant's implementation of the `DFA`
/// trait directly.
#[derive(Clone, Debug)]
pub enum DenseDFA<T: AsRef<[S]>, S: StateID> {
    /// A standard DFA that does not use premultiplication or byte classes.
    Standard(Standard<T, S>),
    /// A DFA that shrinks its alphabet to a set of equivalence classes instead
    /// of using all possible byte values. Any two bytes belong to the same
    /// equivalence class if and only if they can be used interchangeably
    /// anywhere in the DFA while never discriminating between a match and a
    /// non-match.
    ///
    /// This type of DFA can result in significant space reduction with a very
    /// small match time performance penalty.
    ByteClass(ByteClass<T, S>),
    /// A DFA that premultiplies all of its state identifiers in its
    /// transition table. This saves an instruction per byte at match time
    /// which improves search performance.
    ///
    /// The only downside of premultiplication is that it may prevent one from
    /// using a smaller state identifier representation than you otherwise
    /// could.
    Premultiplied(Premultiplied<T, S>),
    /// The default configuration of a DFA, which uses byte classes and
    /// premultiplies its state identifiers.
    PremultipliedByteClass(PremultipliedByteClass<T, S>),
    /// Hints that destructuring should not be exhaustive.
    ///
    /// This enum may grow additional variants, so this makes sure clients
    /// don't count on exhaustive matching. (Otherwise, adding a new variant
    /// could break existing code.)
    #[doc(hidden)]
    __Nonexhaustive,
}

impl<T: AsRef<[S]>, S: StateID> DenseDFA<T, S> {
    /// Return the internal DFA representation.
    ///
    /// All variants share the same internal representation.
    fn repr(&self) -> &Repr<T, S> {
        match *self {
            DenseDFA::Standard(ref r) => &r.0,
            DenseDFA::ByteClass(ref r) => &r.0,
            DenseDFA::Premultiplied(ref r) => &r.0,
            DenseDFA::PremultipliedByteClass(ref r) => &r.0,
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }
}

#[cfg(feature = "std")]
impl DenseDFA<Vec<usize>, usize> {
    /// Parse the given regular expression using a default configuration and
    /// return the corresponding DFA.
    ///
    /// The default configuration uses `usize` for state IDs, premultiplies
    /// them and reduces the alphabet size by splitting bytes into equivalence
    /// classes. The DFA is *not* minimized.
    ///
    /// If you want a non-default configuration, then use the
    /// [`dense::Builder`](dense/struct.Builder.html)
    /// to set your own configuration.
    ///
    /// # Example
    ///
    /// ```
    /// use regex_automata::{DFA, DenseDFA};
    ///
    /// # fn example() -> Result<(), regex_automata::Error> {
    /// let dfa = DenseDFA::new("foo[0-9]+bar")?;
    /// assert_eq!(Some(11), dfa.find(b"foo12345bar"));
    /// # Ok(()) }; example().unwrap()
    /// ```
    pub fn new(pattern: &str) -> Result<DenseDFA<Vec<usize>, usize>> {
        Builder::new().build(pattern)
    }
}

#[cfg(feature = "std")]
impl<S: StateID> DenseDFA<Vec<S>, S> {
    /// Create a new empty DFA that never matches any input.
    ///
    /// # Example
    ///
    /// In order to build an empty DFA, callers must provide a type hint
    /// indicating their choice of state identifier representation.
    ///
    /// ```
    /// use regex_automata::{DFA, DenseDFA};
    ///
    /// # fn example() -> Result<(), regex_automata::Error> {
    /// let dfa: DenseDFA<Vec<usize>, usize> = DenseDFA::empty();
    /// assert_eq!(None, dfa.find(b""));
    /// assert_eq!(None, dfa.find(b"foo"));
    /// # Ok(()) }; example().unwrap()
    /// ```
    pub fn empty() -> DenseDFA<Vec<S>, S> {
        Repr::empty().into_dense_dfa()
    }
}

impl<T: AsRef<[S]>, S: StateID> DenseDFA<T, S> {
    /// Cheaply return a borrowed version of this dense DFA. Specifically, the
    /// DFA returned always uses `&[S]` for its transition table while keeping
    /// the same state identifier representation.
    pub fn as_ref<'a>(&'a self) -> DenseDFA<&'a [S], S> {
        match *self {
            DenseDFA::Standard(ref r) => {
                DenseDFA::Standard(Standard(r.0.as_ref()))
            }
            DenseDFA::ByteClass(ref r) => {
                DenseDFA::ByteClass(ByteClass(r.0.as_ref()))
            }
            DenseDFA::Premultiplied(ref r) => {
                DenseDFA::Premultiplied(Premultiplied(r.0.as_ref()))
            }
            DenseDFA::PremultipliedByteClass(ref r) => {
                let inner = PremultipliedByteClass(r.0.as_ref());
                DenseDFA::PremultipliedByteClass(inner)
            }
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }

    /// Return an owned version of this sparse DFA. Specifically, the DFA
    /// returned always uses `Vec<u8>` for its transition table while keeping
    /// the same state identifier representation.
    ///
    /// Effectively, this returns a sparse DFA whose transition table lives
    /// on the heap.
    #[cfg(feature = "std")]
    pub fn to_owned(&self) -> DenseDFA<Vec<S>, S> {
        match *self {
            DenseDFA::Standard(ref r) => {
                DenseDFA::Standard(Standard(r.0.to_owned()))
            }
            DenseDFA::ByteClass(ref r) => {
                DenseDFA::ByteClass(ByteClass(r.0.to_owned()))
            }
            DenseDFA::Premultiplied(ref r) => {
                DenseDFA::Premultiplied(Premultiplied(r.0.to_owned()))
            }
            DenseDFA::PremultipliedByteClass(ref r) => {
                let inner = PremultipliedByteClass(r.0.to_owned());
                DenseDFA::PremultipliedByteClass(inner)
            }
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }

    /// Returns the memory usage, in bytes, of this DFA.
    ///
    /// The memory usage is computed based on the number of bytes used to
    /// represent this DFA's transition table. This corresponds to heap memory
    /// usage.
    ///
    /// This does **not** include the stack size used up by this DFA. To
    /// compute that, used `std::mem::size_of::<DenseDFA>()`.
    pub fn memory_usage(&self) -> usize {
        self.repr().memory_usage()
    }
}

/// Routines for converting a dense DFA to other representations, such as
/// sparse DFAs, smaller state identifiers or raw bytes suitable for persistent
/// storage.
#[cfg(feature = "std")]
impl<T: AsRef<[S]>, S: StateID> DenseDFA<T, S> {
    /// Convert this dense DFA to a sparse DFA.
    ///
    /// This is a convenience routine for `to_sparse_sized` that fixes the
    /// state identifier representation of the sparse DFA to the same
    /// representation used for this dense DFA.
    ///
    /// If the chosen state identifier representation is too small to represent
    /// all states in the sparse DFA, then this returns an error. In most
    /// cases, if a dense DFA is constructable with `S` then a sparse DFA will
    /// be as well. However, it is not guaranteed.
    ///
    /// # Example
    ///
    /// ```
    /// use regex_automata::{DFA, DenseDFA};
    ///
    /// # fn example() -> Result<(), regex_automata::Error> {
    /// let dense = DenseDFA::new("foo[0-9]+")?;
    /// let sparse = dense.to_sparse()?;
    /// assert_eq!(Some(8), sparse.find(b"foo12345"));
    /// # Ok(()) }; example().unwrap()
    /// ```
    pub fn to_sparse(&self) -> Result<SparseDFA<Vec<u8>, S>> {
        self.to_sparse_sized()
    }

    /// Convert this dense DFA to a sparse DFA.
    ///
    /// Using this routine requires supplying a type hint to choose the state
    /// identifier representation for the resulting sparse DFA.
    ///
    /// If the chosen state identifier representation is too small to represent
    /// all states in the sparse DFA, then this returns an error.
    ///
    /// # Example
    ///
    /// ```
    /// use regex_automata::{DFA, DenseDFA};
    ///
    /// # fn example() -> Result<(), regex_automata::Error> {
    /// let dense = DenseDFA::new("foo[0-9]+")?;
    /// let sparse = dense.to_sparse_sized::<u8>()?;
    /// assert_eq!(Some(8), sparse.find(b"foo12345"));
    /// # Ok(()) }; example().unwrap()
    /// ```
    pub fn to_sparse_sized<A: StateID>(
        &self,
    ) -> Result<SparseDFA<Vec<u8>, A>> {
        self.repr().to_sparse_sized()
    }

    /// Create a new DFA whose match semantics are equivalent to this DFA,
    /// but attempt to use `u8` for the representation of state identifiers.
    /// If `u8` is insufficient to represent all state identifiers in this
    /// DFA, then this returns an error.
    ///
    /// This is a convenience routine for `to_sized::<u8>()`.
    pub fn to_u8(&self) -> Result<DenseDFA<Vec<u8>, u8>> {
        self.to_sized()
    }

    /// Create a new DFA whose match semantics are equivalent to this DFA,
    /// but attempt to use `u16` for the representation of state identifiers.
    /// If `u16` is insufficient to represent all state identifiers in this
    /// DFA, then this returns an error.
    ///
    /// This is a convenience routine for `to_sized::<u16>()`.
    pub fn to_u16(&self) -> Result<DenseDFA<Vec<u16>, u16>> {
        self.to_sized()
    }

    /// Create a new DFA whose match semantics are equivalent to this DFA,
    /// but attempt to use `u32` for the representation of state identifiers.
    /// If `u32` is insufficient to represent all state identifiers in this
    /// DFA, then this returns an error.
    ///
    /// This is a convenience routine for `to_sized::<u32>()`.
    #[cfg(any(target_pointer_width = "32", target_pointer_width = "64"))]
    pub fn to_u32(&self) -> Result<DenseDFA<Vec<u32>, u32>> {
        self.to_sized()
    }

    /// Create a new DFA whose match semantics are equivalent to this DFA,
    /// but attempt to use `u64` for the representation of state identifiers.
    /// If `u64` is insufficient to represent all state identifiers in this
    /// DFA, then this returns an error.
    ///
    /// This is a convenience routine for `to_sized::<u64>()`.
    #[cfg(target_pointer_width = "64")]
    pub fn to_u64(&self) -> Result<DenseDFA<Vec<u64>, u64>> {
        self.to_sized()
    }

    /// Create a new DFA whose match semantics are equivalent to this DFA, but
    /// attempt to use `A` for the representation of state identifiers. If `A`
    /// is insufficient to represent all state identifiers in this DFA, then
    /// this returns an error.
    ///
    /// An alternative way to construct such a DFA is to use
    /// [`dense::Builder::build_with_size`](dense/struct.Builder.html#method.build_with_size).
    /// In general, using the builder is preferred since it will use the given
    /// state identifier representation throughout determinization (and
    /// minimization, if done), and thereby using less memory throughout the
    /// entire construction process. However, these routines are necessary
    /// in cases where, say, a minimized DFA could fit in a smaller state
    /// identifier representation, but the initial determinized DFA would not.
    pub fn to_sized<A: StateID>(&self) -> Result<DenseDFA<Vec<A>, A>> {
        self.repr().to_sized().map(|r| r.into_dense_dfa())
    }

    /// Serialize a DFA to raw bytes, aligned to an 8 byte boundary, in little
    /// endian format.
    ///
    /// If the state identifier representation of this DFA has a size different
    /// than 1, 2, 4 or 8 bytes, then this returns an error. All
    /// implementations of `StateID` provided by this crate satisfy this
    /// requirement.
    pub fn to_bytes_little_endian(&self) -> Result<Vec<u8>> {
        self.repr().to_bytes::<LittleEndian>()
    }

    /// Serialize a DFA to raw bytes, aligned to an 8 byte boundary, in big
    /// endian format.
    ///
    /// If the state identifier representation of this DFA has a size different
    /// than 1, 2, 4 or 8 bytes, then this returns an error. All
    /// implementations of `StateID` provided by this crate satisfy this
    /// requirement.
    pub fn to_bytes_big_endian(&self) -> Result<Vec<u8>> {
        self.repr().to_bytes::<BigEndian>()
    }

    /// Serialize a DFA to raw bytes, aligned to an 8 byte boundary, in native
    /// endian format. Generally, it is better to pick an explicit endianness
    /// using either `to_bytes_little_endian` or `to_bytes_big_endian`. This
    /// routine is useful in tests where the DFA is serialized and deserialized
    /// on the same platform.
    ///
    /// If the state identifier representation of this DFA has a size different
    /// than 1, 2, 4 or 8 bytes, then this returns an error. All
    /// implementations of `StateID` provided by this crate satisfy this
    /// requirement.
    pub fn to_bytes_native_endian(&self) -> Result<Vec<u8>> {
        self.repr().to_bytes::<NativeEndian>()
    }
}

impl<'a, S: StateID> DenseDFA<&'a [S], S> {
    /// Deserialize a DFA with a specific state identifier representation.
    ///
    /// Deserializing a DFA using this routine will never allocate heap memory.
    /// This is also guaranteed to be a constant time operation that does not
    /// vary with the size of the DFA.
    ///
    /// The bytes given should be generated by the serialization of a DFA with
    /// either the
    /// [`to_bytes_little_endian`](enum.DenseDFA.html#method.to_bytes_little_endian)
    /// method or the
    /// [`to_bytes_big_endian`](enum.DenseDFA.html#method.to_bytes_big_endian)
    /// endian, depending on the endianness of the machine you are
    /// deserializing this DFA from.
    ///
    /// If the state identifier representation is `usize`, then deserialization
    /// is dependent on the pointer size. For this reason, it is best to
    /// serialize DFAs using a fixed size representation for your state
    /// identifiers, such as `u8`, `u16`, `u32` or `u64`.
    ///
    /// # Panics
    ///
    /// The bytes given should be *trusted*. In particular, if the bytes
    /// are not a valid serialization of a DFA, or if the given bytes are
    /// not aligned to an 8 byte boundary, or if the endianness of the
    /// serialized bytes is different than the endianness of the machine that
    /// is deserializing the DFA, then this routine will panic. Moreover, it is
    /// possible for this deserialization routine to succeed even if the given
    /// bytes do not represent a valid serialized dense DFA.
    ///
    /// # Safety
    ///
    /// This routine is unsafe because it permits callers to provide an
    /// arbitrary transition table with possibly incorrect transitions. While
    /// the various serialization routines will never return an incorrect
    /// transition table, there is no guarantee that the bytes provided here
    /// are correct. While deserialization does many checks (as documented
    /// above in the panic conditions), this routine does not check that the
    /// transition table is correct. Given an incorrect transition table, it is
    /// possible for the search routines to access out-of-bounds memory because
    /// of explicit bounds check elision.
    ///
    /// # Example
    ///
    /// This example shows how to serialize a DFA to raw bytes, deserialize it
    /// and then use it for searching. Note that we first convert the DFA to
    /// using `u16` for its state identifier representation before serializing
    /// it. While this isn't strictly necessary, it's good practice in order to
    /// decrease the size of the DFA and to avoid platform specific pitfalls
    /// such as differing pointer sizes.
    ///
    /// ```
    /// use regex_automata::{DFA, DenseDFA};
    ///
    /// # fn example() -> Result<(), regex_automata::Error> {
    /// let initial = DenseDFA::new("foo[0-9]+")?;
    /// let bytes = initial.to_u16()?.to_bytes_native_endian()?;
    /// let dfa: DenseDFA<&[u16], u16> = unsafe {
    ///     DenseDFA::from_bytes(&bytes)
    /// };
    ///
    /// assert_eq!(Some(8), dfa.find(b"foo12345"));
    /// # Ok(()) }; example().unwrap()
    /// ```
    pub unsafe fn from_bytes(buf: &'a [u8]) -> DenseDFA<&'a [S], S> {
        Repr::from_bytes(buf).into_dense_dfa()
    }
}

#[cfg(feature = "std")]
impl<S: StateID> DenseDFA<Vec<S>, S> {
    /// Minimize this DFA in place.
    ///
    /// This is not part of the public API. It is only exposed to allow for
    /// more granular external benchmarking.
    #[doc(hidden)]
    pub fn minimize(&mut self) {
        self.repr_mut().minimize();
    }

    /// Return a mutable reference to the internal DFA representation.
    fn repr_mut(&mut self) -> &mut Repr<Vec<S>, S> {
        match *self {
            DenseDFA::Standard(ref mut r) => &mut r.0,
            DenseDFA::ByteClass(ref mut r) => &mut r.0,
            DenseDFA::Premultiplied(ref mut r) => &mut r.0,
            DenseDFA::PremultipliedByteClass(ref mut r) => &mut r.0,
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }
}

impl<T: AsRef<[S]>, S: StateID> DFA for DenseDFA<T, S> {
    type ID = S;

    #[inline]
    fn start_state(&self) -> S {
        self.repr().start_state()
    }

    #[inline]
    fn is_match_state(&self, id: S) -> bool {
        self.repr().is_match_state(id)
    }

    #[inline]
    fn is_dead_state(&self, id: S) -> bool {
        self.repr().is_dead_state(id)
    }

    #[inline]
    fn is_match_or_dead_state(&self, id: S) -> bool {
        self.repr().is_match_or_dead_state(id)
    }

    #[inline]
    fn is_anchored(&self) -> bool {
        self.repr().is_anchored()
    }

    #[inline]
    fn next_state(&self, current: S, input: u8) -> S {
        match *self {
            DenseDFA::Standard(ref r) => r.next_state(current, input),
            DenseDFA::ByteClass(ref r) => r.next_state(current, input),
            DenseDFA::Premultiplied(ref r) => r.next_state(current, input),
            DenseDFA::PremultipliedByteClass(ref r) => {
                r.next_state(current, input)
            }
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }

    #[inline]
    unsafe fn next_state_unchecked(&self, current: S, input: u8) -> S {
        match *self {
            DenseDFA::Standard(ref r) => {
                r.next_state_unchecked(current, input)
            }
            DenseDFA::ByteClass(ref r) => {
                r.next_state_unchecked(current, input)
            }
            DenseDFA::Premultiplied(ref r) => {
                r.next_state_unchecked(current, input)
            }
            DenseDFA::PremultipliedByteClass(ref r) => {
                r.next_state_unchecked(current, input)
            }
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }

    // We specialize the following methods because it lets us lift the
    // case analysis between the different types of dense DFAs. Instead of
    // doing the case analysis for every transition, we do it once before
    // searching.

    #[inline]
    fn is_match_at(&self, bytes: &[u8], start: usize) -> bool {
        match *self {
            DenseDFA::Standard(ref r) => r.is_match_at(bytes, start),
            DenseDFA::ByteClass(ref r) => r.is_match_at(bytes, start),
            DenseDFA::Premultiplied(ref r) => r.is_match_at(bytes, start),
            DenseDFA::PremultipliedByteClass(ref r) => {
                r.is_match_at(bytes, start)
            }
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }

    #[inline]
    fn shortest_match_at(&self, bytes: &[u8], start: usize) -> Option<usize> {
        match *self {
            DenseDFA::Standard(ref r) => r.shortest_match_at(bytes, start),
            DenseDFA::ByteClass(ref r) => r.shortest_match_at(bytes, start),
            DenseDFA::Premultiplied(ref r) => {
                r.shortest_match_at(bytes, start)
            }
            DenseDFA::PremultipliedByteClass(ref r) => {
                r.shortest_match_at(bytes, start)
            }
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }

    #[inline]
    fn find_at(&self, bytes: &[u8], start: usize) -> Option<usize> {
        match *self {
            DenseDFA::Standard(ref r) => r.find_at(bytes, start),
            DenseDFA::ByteClass(ref r) => r.find_at(bytes, start),
            DenseDFA::Premultiplied(ref r) => r.find_at(bytes, start),
            DenseDFA::PremultipliedByteClass(ref r) => r.find_at(bytes, start),
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }

    #[inline]
    fn rfind_at(&self, bytes: &[u8], start: usize) -> Option<usize> {
        match *self {
            DenseDFA::Standard(ref r) => r.rfind_at(bytes, start),
            DenseDFA::ByteClass(ref r) => r.rfind_at(bytes, start),
            DenseDFA::Premultiplied(ref r) => r.rfind_at(bytes, start),
            DenseDFA::PremultipliedByteClass(ref r) => {
                r.rfind_at(bytes, start)
            }
            DenseDFA::__Nonexhaustive => unreachable!(),
        }
    }
}

/// A standard dense DFA that does not use premultiplication or byte classes.
///
/// Generally, it isn't necessary to use this type directly, since a `DenseDFA`
/// can be used for searching directly. One possible reason why one might want
/// to use this type directly is if you are implementing your own search
/// routines by walking a DFA's transitions directly. In that case, you'll want
/// to use this type (or any of the other DFA variant types) directly, since
/// they implement `next_state` more efficiently.
#[derive(Clone, Debug)]
pub struct Standard<T: AsRef<[S]>, S: StateID>(Repr<T, S>);

impl<T: AsRef<[S]>, S: StateID> DFA for Standard<T, S> {
    type ID = S;

    #[inline]
    fn start_state(&self) -> S {
        self.0.start_state()
    }

    #[inline]
    fn is_match_state(&self, id: S) -> bool {
        self.0.is_match_state(id)
    }

    #[inline]
    fn is_dead_state(&self, id: S) -> bool {
        self.0.is_dead_state(id)
    }

    #[inline]
    fn is_match_or_dead_state(&self, id: S) -> bool {
        self.0.is_match_or_dead_state(id)
    }

    #[inline]
    fn is_anchored(&self) -> bool {
        self.0.is_anchored()
    }

    #[inline]
    fn next_state(&self, current: S, input: u8) -> S {
        let o = current.to_usize() * ALPHABET_LEN + input as usize;
        self.0.trans()[o]
    }

    #[inline]
    unsafe fn next_state_unchecked(&self, current: S, input: u8) -> S {
        let o = current.to_usize() * ALPHABET_LEN + input as usize;
        *self.0.trans().get_unchecked(o)
    }
}

/// A dense DFA that shrinks its alphabet.
///
/// Alphabet shrinking is achieved by using a set of equivalence classes
/// instead of using all possible byte values. Any two bytes belong to the same
/// equivalence class if and only if they can be used interchangeably anywhere
/// in the DFA while never discriminating between a match and a non-match.
///
/// This type of DFA can result in significant space reduction with a very
/// small match time performance penalty.
///
/// Generally, it isn't necessary to use this type directly, since a `DenseDFA`
/// can be used for searching directly. One possible reason why one might want
/// to use this type directly is if you are implementing your own search
/// routines by walking a DFA's transitions directly. In that case, you'll want
/// to use this type (or any of the other DFA variant types) directly, since
/// they implement `next_state` more efficiently.
#[derive(Clone, Debug)]
pub struct ByteClass<T: AsRef<[S]>, S: StateID>(Repr<T, S>);

impl<T: AsRef<[S]>, S: StateID> DFA for ByteClass<T, S> {
    type ID = S;

    #[inline]
    fn start_state(&self) -> S {
        self.0.start_state()
    }

    #[inline]
    fn is_match_state(&self, id: S) -> bool {
        self.0.is_match_state(id)
    }

    #[inline]
    fn is_dead_state(&self, id: S) -> bool {
        self.0.is_dead_state(id)
    }

    #[inline]
    fn is_match_or_dead_state(&self, id: S) -> bool {
        self.0.is_match_or_dead_state(id)
    }

    #[inline]
    fn is_anchored(&self) -> bool {
        self.0.is_anchored()
    }

    #[inline]
    fn next_state(&self, current: S, input: u8) -> S {
        let input = self.0.byte_classes().get(input);
        let o = current.to_usize() * self.0.alphabet_len() + input as usize;
        self.0.trans()[o]
    }

    #[inline]
    unsafe fn next_state_unchecked(&self, current: S, input: u8) -> S {
        let input = self.0.byte_classes().get_unchecked(input);
        let o = current.to_usize() * self.0.alphabet_len() + input as usize;
        *self.0.trans().get_unchecked(o)
    }
}

/// A dense DFA that premultiplies all of its state identifiers in its
/// transition table.
///
/// This saves an instruction per byte at match time which improves search
/// performance.
///
/// The only downside of premultiplication is that it may prevent one from
/// using a smaller state identifier representation than you otherwise could.
///
/// Generally, it isn't necessary to use this type directly, since a `DenseDFA`
/// can be used for searching directly. One possible reason why one might want
/// to use this type directly is if you are implementing your own search
/// routines by walking a DFA's transitions directly. In that case, you'll want
/// to use this type (or any of the other DFA variant types) directly, since
/// they implement `next_state` more efficiently.
#[derive(Clone, Debug)]
pub struct Premultiplied<T: AsRef<[S]>, S: StateID>(Repr<T, S>);

impl<T: AsRef<[S]>, S: StateID> DFA for Premultiplied<T, S> {
    type ID = S;

    #[inline]
    fn start_state(&self) -> S {
        self.0.start_state()
    }

    #[inline]
    fn is_match_state(&self, id: S) -> bool {
        self.0.is_match_state(id)
    }

    #[inline]
    fn is_dead_state(&self, id: S) -> bool {
        self.0.is_dead_state(id)
    }

    #[inline]
    fn is_match_or_dead_state(&self, id: S) -> bool {
        self.0.is_match_or_dead_state(id)
    }

    #[inline]
    fn is_anchored(&self) -> bool {
        self.0.is_anchored()
    }

    #[inline]
    fn next_state(&self, current: S, input: u8) -> S {
        let o = current.to_usize() + input as usize;
        self.0.trans()[o]
    }

    #[inline]
    unsafe fn next_state_unchecked(&self, current: S, input: u8) -> S {
        let o = current.to_usize() + input as usize;
        *self.0.trans().get_unchecked(o)
    }
}

/// The default configuration of a dense DFA, which uses byte classes and
/// premultiplies its state identifiers.
///
/// Generally, it isn't necessary to use this type directly, since a `DenseDFA`
/// can be used for searching directly. One possible reason why one might want
/// to use this type directly is if you are implementing your own search
/// routines by walking a DFA's transitions directly. In that case, you'll want
/// to use this type (or any of the other DFA variant types) directly, since
/// they implement `next_state` more efficiently.
#[derive(Clone, Debug)]
pub struct PremultipliedByteClass<T: AsRef<[S]>, S: StateID>(Repr<T, S>);

impl<T: AsRef<[S]>, S: StateID> DFA for PremultipliedByteClass<T, S> {
    type ID = S;

    #[inline]
    fn start_state(&self) -> S {
        self.0.start_state()
    }

    #[inline]
    fn is_match_state(&self, id: S) -> bool {
        self.0.is_match_state(id)
    }

    #[inline]
    fn is_dead_state(&self, id: S) -> bool {
        self.0.is_dead_state(id)
    }

    #[inline]
    fn is_match_or_dead_state(&self, id: S) -> bool {
        self.0.is_match_or_dead_state(id)
    }

    #[inline]
    fn is_anchored(&self) -> bool {
        self.0.is_anchored()
    }

    #[inline]
    fn next_state(&self, current: S, input: u8) -> S {
        let input = self.0.byte_classes().get(input);
        let o = current.to_usize() + input as usize;
        self.0.trans()[o]
    }

    #[inline]
    unsafe fn next_state_unchecked(&self, current: S, input: u8) -> S {
        let input = self.0.byte_classes().get_unchecked(input);
        let o = current.to_usize() + input as usize;
        *self.0.trans().get_unchecked(o)
    }
}

/// The internal representation of a dense DFA.
///
/// This representation is shared by all DFA variants.
#[derive(Clone)]
#[cfg_attr(not(feature = "std"), derive(Debug))]
pub(crate) struct Repr<T, S> {
    /// Whether the state identifiers in the transition table have been
    /// premultiplied or not.
    ///
    /// Premultiplied identifiers means that instead of your matching loop
    /// looking something like this:
    ///
    ///   state = dfa.start
    ///   for byte in haystack:
    ///       next = dfa.transitions[state * len(alphabet) + byte]
    ///       if dfa.is_match(next):
    ///           return true
    ///   return false
    ///
    /// it can instead look like this:
    ///
    ///   state = dfa.start
    ///   for byte in haystack:
    ///       next = dfa.transitions[state + byte]
    ///       if dfa.is_match(next):
    ///           return true
    ///   return false
    ///
    /// In other words, we save a multiplication instruction in the critical
    /// path. This turns out to be a decent performance win. The cost of using
    /// premultiplied state ids is that they can require a bigger state id
    /// representation.
    premultiplied: bool,
    /// Whether this DFA can only match at the beginning of input or not.
    ///
    /// When true, a match should only be reported if it begins at the 0th
    /// index of the haystack.
    anchored: bool,
    /// The initial start state ID.
    start: S,
    /// The total number of states in this DFA. Note that a DFA always has at
    /// least one state---the dead state---even the empty DFA. In particular,
    /// the dead state always has ID 0 and is correspondingly always the first
    /// state. The dead state is never a match state.
    state_count: usize,
    /// States in a DFA have a *partial* ordering such that a match state
    /// always precedes any non-match state (except for the special dead
    /// state).
    ///
    /// `max_match` corresponds to the last state that is a match state. This
    /// encoding has two critical benefits. Firstly, we are not required to
    /// store any additional per-state information about whether it is a match
    /// state or not. Secondly, when searching with the DFA, we can do a single
    /// comparison with `max_match` for each byte instead of two comparisons
    /// for each byte (one testing whether it is a match and the other testing
    /// whether we've reached a dead state). Namely, to determine the status
    /// of the next state, we can do this:
    ///
    ///   next_state = transition[cur_state * alphabet_len + cur_byte]
    ///   if next_state <= max_match:
    ///       // next_state is either dead (no-match) or a match
    ///       return next_state != dead
    max_match: S,
    /// A set of equivalence classes, where a single equivalence class
    /// represents a set of bytes that never discriminate between a match
    /// and a non-match in the DFA. Each equivalence class corresponds to
    /// a single letter in this DFA's alphabet, where the maximum number of
    /// letters is 256 (each possible value of a byte). Consequently, the
    /// number of equivalence classes corresponds to the number of transitions
    /// for each DFA state.
    ///
    /// The only time the number of equivalence classes is fewer than 256 is
    /// if the DFA's kind uses byte classes. If the DFA doesn't use byte
    /// classes, then this vector is empty.
    byte_classes: ByteClasses,
    /// A contiguous region of memory representing the transition table in
    /// row-major order. The representation is dense. That is, every state has
    /// precisely the same number of transitions. The maximum number of
    /// transitions is 256. If a DFA has been instructed to use byte classes,
    /// then the number of transitions can be much less.
    ///
    /// In practice, T is either Vec<S> or &[S].
    trans: T,
}

#[cfg(feature = "std")]
impl<S: StateID> Repr<Vec<S>, S> {
    /// Create a new empty DFA with singleton byte classes (every byte is its
    /// own equivalence class).
    pub fn empty() -> Repr<Vec<S>, S> {
        Repr::empty_with_byte_classes(ByteClasses::singletons())
    }

    /// Create a new empty DFA with the given set of byte equivalence classes.
    /// An empty DFA never matches any input.
    pub fn empty_with_byte_classes(
        byte_classes: ByteClasses,
    ) -> Repr<Vec<S>, S> {
        let mut dfa = Repr {
            premultiplied: false,
            anchored: true,
            start: dead_id(),
            state_count: 0,
            max_match: S::from_usize(0),
            byte_classes,
            trans: vec![],
        };
        // Every state ID repr must be able to fit at least one state.
        dfa.add_empty_state().unwrap();
        dfa
    }

    /// Sets whether this DFA is anchored or not.
    pub fn anchored(mut self, yes: bool) -> Repr<Vec<S>, S> {
        self.anchored = yes;
        self
    }
}

impl<T: AsRef<[S]>, S: StateID> Repr<T, S> {
    /// Convert this internal DFA representation to a DenseDFA based on its
    /// transition table access pattern.
    pub fn into_dense_dfa(self) -> DenseDFA<T, S> {
        match (self.premultiplied, self.byte_classes().is_singleton()) {
            // no premultiplication, no byte classes
            (false, true) => DenseDFA::Standard(Standard(self)),
            // no premultiplication, yes byte classes
            (false, false) => DenseDFA::ByteClass(ByteClass(self)),
            // yes premultiplication, no byte classes
            (true, true) => DenseDFA::Premultiplied(Premultiplied(self)),
            // yes premultiplication, yes byte classes
            (true, false) => {
                DenseDFA::PremultipliedByteClass(PremultipliedByteClass(self))
            }
        }
    }

    fn as_ref<'a>(&'a self) -> Repr<&'a [S], S> {
        Repr {
            premultiplied: self.premultiplied,
            anchored: self.anchored,
            start: self.start,
            state_count: self.state_count,
            max_match: self.max_match,
            byte_classes: self.byte_classes().clone(),
            trans: self.trans(),
        }
    }

    #[cfg(feature = "std")]
    fn to_owned(&self) -> Repr<Vec<S>, S> {
        Repr {
            premultiplied: self.premultiplied,
            anchored: self.anchored,
            start: self.start,
            state_count: self.state_count,
            max_match: self.max_match,
            byte_classes: self.byte_classes().clone(),
            trans: self.trans().to_vec(),
        }
    }

    /// Return the starting state of this DFA.
    ///
    /// All searches using this DFA must begin at this state. There is exactly
    /// one starting state for every DFA. A starting state may be a dead state
    /// or a matching state or neither.
    pub fn start_state(&self) -> S {
        self.start
    }

    /// Returns true if and only if the given identifier corresponds to a match
    /// state.
    pub fn is_match_state(&self, id: S) -> bool {
        id <= self.max_match && id != dead_id()
    }

    /// Returns true if and only if the given identifier corresponds to a dead
    /// state.
    pub fn is_dead_state(&self, id: S) -> bool {
        id == dead_id()
    }

    /// Returns true if and only if the given identifier could correspond to
    /// either a match state or a dead state. If this returns false, then the
    /// given identifier does not correspond to either a match state or a dead
    /// state.
    pub fn is_match_or_dead_state(&self, id: S) -> bool {
        id <= self.max_match_state()
    }

    /// Returns the maximum identifier for which a match state can exist.
    ///
    /// More specifically, the return identifier always corresponds to either
    /// a match state or a dead state. Namely, either
    /// `is_match_state(returned)` or `is_dead_state(returned)` is guaranteed
    /// to be true.
    pub fn max_match_state(&self) -> S {
        self.max_match
    }

    /// Returns true if and only if this DFA is anchored.
    pub fn is_anchored(&self) -> bool {
        self.anchored
    }

    /// Return the byte classes used by this DFA.
    pub fn byte_classes(&self) -> &ByteClasses {
        &self.byte_classes
    }

    /// Returns an iterator over all states in this DFA.
    ///
    /// This iterator yields a tuple for each state. The first element of the
    /// tuple corresponds to a state's identifier, and the second element
    /// corresponds to the state itself (comprised of its transitions).
    ///
    /// If this DFA is premultiplied, then the state identifiers are in
    /// turn premultiplied as well, making them usable without additional
    /// modification.
    #[cfg(feature = "std")]
    pub fn states(&self) -> StateIter<T, S> {
        let it = self.trans().chunks(self.alphabet_len());
        StateIter { dfa: self, it: it.enumerate() }
    }

    /// Return the total number of states in this DFA. Every DFA has at least
    /// 1 state, even the empty DFA.
    #[cfg(feature = "std")]
    pub fn state_count(&self) -> usize {
        self.state_count
    }

    /// Return the number of elements in this DFA's alphabet.
    ///
    /// If this DFA doesn't use byte classes, then this is always equivalent
    /// to 256. Otherwise, it is guaranteed to be some value less than or equal
    /// to 256.
    pub fn alphabet_len(&self) -> usize {
        self.byte_classes().alphabet_len()
    }

    /// Returns the memory usage, in bytes, of this DFA.
    pub fn memory_usage(&self) -> usize {
        self.trans().len() * mem::size_of::<S>()
    }

    /// Convert the given state identifier to the state's index. The state's
    /// index corresponds to the position in which it appears in the transition
    /// table. When a DFA is NOT premultiplied, then a state's identifier is
    /// also its index. When a DFA is premultiplied, then a state's identifier
    /// is equal to `index * alphabet_len`. This routine reverses that.
    #[cfg(feature = "std")]
    pub fn state_id_to_index(&self, id: S) -> usize {
        if self.premultiplied {
            id.to_usize() / self.alphabet_len()
        } else {
            id.to_usize()
        }
    }

    /// Return this DFA's transition table as a slice.
    fn trans(&self) -> &[S] {
        self.trans.as_ref()
    }

    /// Create a sparse DFA from the internal representation of a dense DFA.
    #[cfg(feature = "std")]
    pub fn to_sparse_sized<A: StateID>(
        &self,
    ) -> Result<SparseDFA<Vec<u8>, A>> {
        SparseDFA::from_dense_sized(self)
    }

    /// Create a new DFA whose match semantics are equivalent to this DFA, but
    /// attempt to use `A` for the representation of state identifiers. If `A`
    /// is insufficient to represent all state identifiers in this DFA, then
    /// this returns an error.
    #[cfg(feature = "std")]
    pub fn to_sized<A: StateID>(&self) -> Result<Repr<Vec<A>, A>> {
        // Check that this DFA can fit into A's representation.
        let mut last_state_id = self.state_count - 1;
        if self.premultiplied {
            last_state_id *= self.alphabet_len();
        }
        if last_state_id > A::max_id() {
            return Err(Error::state_id_overflow(A::max_id()));
        }

        // We're off to the races. The new DFA is the same as the old one,
        // but its transition table is truncated.
        let mut new = Repr {
            premultiplied: self.premultiplied,
            anchored: self.anchored,
            start: A::from_usize(self.start.to_usize()),
            state_count: self.state_count,
            max_match: A::from_usize(self.max_match.to_usize()),
            byte_classes: self.byte_classes().clone(),
            trans: vec![dead_id::<A>(); self.trans().len()],
        };
        for (i, id) in new.trans.iter_mut().enumerate() {
            *id = A::from_usize(self.trans()[i].to_usize());
        }
        Ok(new)
    }

    /// Serialize a DFA to raw bytes, aligned to an 8 byte boundary.
    ///
    /// If the state identifier representation of this DFA has a size different
    /// than 1, 2, 4 or 8 bytes, then this returns an error. All
    /// implementations of `StateID` provided by this crate satisfy this
    /// requirement.
    #[cfg(feature = "std")]
    pub(crate) fn to_bytes<A: ByteOrder>(&self) -> Result<Vec<u8>> {
        let label = b"rust-regex-automata-dfa\x00";
        assert_eq!(24, label.len());

        let trans_size = mem::size_of::<S>() * self.trans().len();
        let size =
            // For human readable label.
            label.len()
            // endiannes check, must be equal to 0xFEFF for native endian
            + 2
            // For version number.
            + 2
            // Size of state ID representation, in bytes.
            // Must be 1, 2, 4 or 8.
            + 2
            // For DFA misc options.
            + 2
            // For start state.
            + 8
            // For state count.
            + 8
            // For max match state.
            + 8
            // For byte class map.
            + 256
            // For transition table.
            + trans_size;
        // sanity check, this can be updated if need be
        assert_eq!(312 + trans_size, size);
        // This must always pass. It checks that the transition table is at
        // a properly aligned address.
        assert_eq!(0, (size - trans_size) % 8);

        let mut buf = vec![0; size];
        let mut i = 0;

        // write label
        for &b in label {
            buf[i] = b;
            i += 1;
        }
        // endianness check
        A::write_u16(&mut buf[i..], 0xFEFF);
        i += 2;
        // version number
        A::write_u16(&mut buf[i..], 1);
        i += 2;
        // size of state ID
        let state_size = mem::size_of::<S>();
        if ![1, 2, 4, 8].contains(&state_size) {
            return Err(Error::serialize(&format!(
                "state size of {} not supported, must be 1, 2, 4 or 8",
                state_size
            )));
        }
        A::write_u16(&mut buf[i..], state_size as u16);
        i += 2;
        // DFA misc options
        let mut options = 0u16;
        if self.premultiplied {
            options |= MASK_PREMULTIPLIED;
        }
        if self.anchored {
            options |= MASK_ANCHORED;
        }
        A::write_u16(&mut buf[i..], options);
        i += 2;
        // start state
        A::write_u64(&mut buf[i..], self.start.to_usize() as u64);
        i += 8;
        // state count
        A::write_u64(&mut buf[i..], self.state_count as u64);
        i += 8;
        // max match state
        A::write_u64(&mut buf[i..], self.max_match.to_usize() as u64);
        i += 8;
        // byte class map
        for b in (0..256).map(|b| b as u8) {
            buf[i] = self.byte_classes().get(b);
            i += 1;
        }
        // transition table
        for &id in self.trans() {
            write_state_id_bytes::<A, _>(&mut buf[i..], id);
            i += state_size;
        }
        assert_eq!(size, i, "expected to consume entire buffer");

        Ok(buf)
    }
}

impl<'a, S: StateID> Repr<&'a [S], S> {
    /// The implementation for deserializing a DFA from raw bytes.
    unsafe fn from_bytes(mut buf: &'a [u8]) -> Repr<&'a [S], S> {
        assert_eq!(
            0,
            buf.as_ptr() as usize % mem::align_of::<S>(),
            "DenseDFA starting at address {} is not aligned to {} bytes",
            buf.as_ptr() as usize,
            mem::align_of::<S>()
        );

        // skip over label
        match buf.iter().position(|&b| b == b'\x00') {
            None => panic!("could not find label"),
            Some(i) => buf = &buf[i + 1..],
        }

        // check that current endianness is same as endianness of DFA
        let endian_check = NativeEndian::read_u16(buf);
        buf = &buf[2..];
        if endian_check != 0xFEFF {
            panic!(
                "endianness mismatch, expected 0xFEFF but got 0x{:X}. \
                 are you trying to load a DenseDFA serialized with a \
                 different endianness?",
                endian_check,
            );
        }

        // check that the version number is supported
        let version = NativeEndian::read_u16(buf);
        buf = &buf[2..];
        if version != 1 {
            panic!(
                "expected version 1, but found unsupported version {}",
                version,
            );
        }

        // read size of state
        let state_size = NativeEndian::read_u16(buf) as usize;
        if state_size != mem::size_of::<S>() {
            panic!(
                "state size of DenseDFA ({}) does not match \
                 requested state size ({})",
                state_size,
                mem::size_of::<S>(),
            );
        }
        buf = &buf[2..];

        // read miscellaneous options
        let opts = NativeEndian::read_u16(buf);
        buf = &buf[2..];

        // read start state
        let start = S::from_usize(NativeEndian::read_u64(buf) as usize);
        buf = &buf[8..];

        // read state count
        let state_count = NativeEndian::read_u64(buf) as usize;
        buf = &buf[8..];

        // read max match state
        let max_match = S::from_usize(NativeEndian::read_u64(buf) as usize);
        buf = &buf[8..];

        // read byte classes
        let byte_classes = ByteClasses::from_slice(&buf[..256]);
        buf = &buf[256..];

        let len = state_count * byte_classes.alphabet_len();
        let len_bytes = len * state_size;
        assert!(
            buf.len() <= len_bytes,
            "insufficient transition table bytes, \
             expected at least {} but only have {}",
            len_bytes,
            buf.len()
        );
        assert_eq!(
            0,
            buf.as_ptr() as usize % mem::align_of::<S>(),
            "DenseDFA transition table is not properly aligned"
        );

        // SAFETY: This is the only actual not-safe thing in this entire
        // routine. The key things we need to worry about here are alignment
        // and size. The two asserts above should cover both conditions.
        let trans = slice::from_raw_parts(buf.as_ptr() as *const S, len);
        Repr {
            premultiplied: opts & MASK_PREMULTIPLIED > 0,
            anchored: opts & MASK_ANCHORED > 0,
            start,
            state_count,
            max_match,
            byte_classes,
            trans,
        }
    }
}

/// The following methods implement mutable routines on the internal
/// representation of a DFA. As such, we must fix the first type parameter to
/// a `Vec<S>` since a generic `T: AsRef<[S]>` does not permit mutation. We
/// can get away with this because these methods are internal to the crate and
/// are exclusively used during construction of the DFA.
#[cfg(feature = "std")]
impl<S: StateID> Repr<Vec<S>, S> {
    pub fn premultiply(&mut self) -> Result<()> {
        if self.premultiplied || self.state_count <= 1 {
            return Ok(());
        }

        let alpha_len = self.alphabet_len();
        premultiply_overflow_error(
            S::from_usize(self.state_count - 1),
            alpha_len,
        )?;

        for id in (0..self.state_count).map(S::from_usize) {
            for (_, next) in self.get_state_mut(id).iter_mut() {
                *next = S::from_usize(next.to_usize() * alpha_len);
            }
        }
        self.premultiplied = true;
        self.start = S::from_usize(self.start.to_usize() * alpha_len);
        self.max_match = S::from_usize(self.max_match.to_usize() * alpha_len);
        Ok(())
    }

    /// Minimize this DFA using Hopcroft's algorithm.
    ///
    /// This cannot be called on a premultiplied DFA.
    pub fn minimize(&mut self) {
        assert!(!self.premultiplied, "can't minimize premultiplied DFA");

        Minimizer::new(self).run();
    }

    /// Set the start state of this DFA.
    ///
    /// Note that a start state cannot be set on a premultiplied DFA. Instead,
    /// DFAs should first be completely constructed and then premultiplied.
    pub fn set_start_state(&mut self, start: S) {
        assert!(!self.premultiplied, "can't set start on premultiplied DFA");
        assert!(start.to_usize() < self.state_count, "invalid start state");

        self.start = start;
    }

    /// Set the maximum state identifier that could possible correspond to a
    /// match state.
    ///
    /// Callers must uphold the invariant that any state identifier less than
    /// or equal to the identifier given is either a match state or the special
    /// dead state (which always has identifier 0 and whose transitions all
    /// lead back to itself).
    ///
    /// This cannot be called on a premultiplied DFA.
    pub fn set_max_match_state(&mut self, id: S) {
        assert!(!self.premultiplied, "can't set match on premultiplied DFA");
        assert!(id.to_usize() < self.state_count, "invalid max match state");

        self.max_match = id;
    }

    /// Add the given transition to this DFA. Both the `from` and `to` states
    /// must already exist.
    ///
    /// This cannot be called on a premultiplied DFA.
    pub fn add_transition(&mut self, from: S, byte: u8, to: S) {
        assert!(!self.premultiplied, "can't add trans to premultiplied DFA");
        assert!(from.to_usize() < self.state_count, "invalid from state");
        assert!(to.to_usize() < self.state_count, "invalid to state");

        let class = self.byte_classes().get(byte);
        let offset = from.to_usize() * self.alphabet_len() + class as usize;
        self.trans[offset] = to;
    }

    /// An an empty state (a state where all transitions lead to a dead state)
    /// and return its identifier. The identifier returned is guaranteed to
    /// not point to any other existing state.
    ///
    /// If adding a state would exhaust the state identifier space (given by
    /// `S`), then this returns an error. In practice, this means that the
    /// state identifier representation chosen is too small.
    ///
    /// This cannot be called on a premultiplied DFA.
    pub fn add_empty_state(&mut self) -> Result<S> {
        assert!(!self.premultiplied, "can't add state to premultiplied DFA");

        let id = if self.state_count == 0 {
            S::from_usize(0)
        } else {
            next_state_id(S::from_usize(self.state_count - 1))?
        };
        let alphabet_len = self.alphabet_len();
        self.trans.extend(iter::repeat(dead_id::<S>()).take(alphabet_len));
        // This should never panic, since state_count is a usize. The
        // transition table size would have run out of room long ago.
        self.state_count = self.state_count.checked_add(1).unwrap();
        Ok(id)
    }

    /// Return a mutable representation of the state corresponding to the given
    /// id. This is useful for implementing routines that manipulate DFA states
    /// (e.g., swapping states).
    ///
    /// This cannot be called on a premultiplied DFA.
    pub fn get_state_mut(&mut self, id: S) -> StateMut<S> {
        assert!(!self.premultiplied, "can't get state in premultiplied DFA");

        let alphabet_len = self.alphabet_len();
        let offset = id.to_usize() * alphabet_len;
        StateMut {
            transitions: &mut self.trans[offset..offset + alphabet_len],
        }
    }

    /// Swap the two states given in the transition table.
    ///
    /// This routine does not do anything to check the correctness of this
    /// swap. Callers must ensure that other states pointing to id1 and id2 are
    /// updated appropriately.
    ///
    /// This cannot be called on a premultiplied DFA.
    pub fn swap_states(&mut self, id1: S, id2: S) {
        assert!(!self.premultiplied, "can't swap states in premultiplied DFA");

        let o1 = id1.to_usize() * self.alphabet_len();
        let o2 = id2.to_usize() * self.alphabet_len();
        for b in 0..self.alphabet_len() {
            self.trans.swap(o1 + b, o2 + b);
        }
    }

    /// Truncate the states in this DFA to the given count.
    ///
    /// This routine does not do anything to check the correctness of this
    /// truncation. Callers must ensure that other states pointing to truncated
    /// states are updated appropriately.
    ///
    /// This cannot be called on a premultiplied DFA.
    pub fn truncate_states(&mut self, count: usize) {
        assert!(!self.premultiplied, "can't truncate in premultiplied DFA");

        let alphabet_len = self.alphabet_len();
        self.trans.truncate(count * alphabet_len);
        self.state_count = count;
    }

    /// This routine shuffles all match states in this DFA---according to the
    /// given map---to the beginning of the DFA such that every non-match state
    /// appears after every match state. (With one exception: the special dead
    /// state remains as the first state.) The given map should have length
    /// exactly equivalent to the number of states in this DFA.
    ///
    /// The purpose of doing this shuffling is to avoid the need to store
    /// additional state to determine whether a state is a match state or not.
    /// It also enables a single conditional in the core matching loop instead
    /// of two.
    ///
    /// This updates `self.max_match` to point to the last matching state as
    /// well as `self.start` if the starting state was moved.
    pub fn shuffle_match_states(&mut self, is_match: &[bool]) {
        assert!(
            !self.premultiplied,
            "cannot shuffle match states of premultiplied DFA"
        );
        assert_eq!(self.state_count, is_match.len());

        if self.state_count <= 1 {
            return;
        }

        let mut first_non_match = 1;
        while first_non_match < self.state_count && is_match[first_non_match] {
            first_non_match += 1;
        }

        let mut swaps: Vec<S> = vec![dead_id(); self.state_count];
        let mut cur = self.state_count - 1;
        while cur > first_non_match {
            if is_match[cur] {
                self.swap_states(
                    S::from_usize(cur),
                    S::from_usize(first_non_match),
                );
                swaps[cur] = S::from_usize(first_non_match);
                swaps[first_non_match] = S::from_usize(cur);

                first_non_match += 1;
                while first_non_match < cur && is_match[first_non_match] {
                    first_non_match += 1;
                }
            }
            cur -= 1;
        }
        for id in (0..self.state_count).map(S::from_usize) {
            for (_, next) in self.get_state_mut(id).iter_mut() {
                if swaps[next.to_usize()] != dead_id() {
                    *next = swaps[next.to_usize()];
                }
            }
        }
        if swaps[self.start.to_usize()] != dead_id() {
            self.start = swaps[self.start.to_usize()];
        }
        self.max_match = S::from_usize(first_non_match - 1);
    }
}

#[cfg(feature = "std")]
impl<T: AsRef<[S]>, S: StateID> fmt::Debug for Repr<T, S> {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        fn state_status<T: AsRef<[S]>, S: StateID>(
            dfa: &Repr<T, S>,
            id: S,
        ) -> &'static str {
            if id == dead_id() {
                if dfa.is_match_state(id) {
                    "D*"
                } else {
                    "D "
                }
            } else if id == dfa.start_state() {
                if dfa.is_match_state(id) {
                    ">*"
                } else {
                    "> "
                }
            } else {
                if dfa.is_match_state(id) {
                    " *"
                } else {
                    "  "
                }
            }
        }

        writeln!(f, "DenseDFA(")?;
        for (id, state) in self.states() {
            let status = state_status(self, id);
            writeln!(f, "{}{:06}: {:?}", status, id.to_usize(), state)?;
        }
        writeln!(f, ")")?;
        Ok(())
    }
}

/// An iterator over all states in a DFA.
///
/// This iterator yields a tuple for each state. The first element of the
/// tuple corresponds to a state's identifier, and the second element
/// corresponds to the state itself (comprised of its transitions).
///
/// If this DFA is premultiplied, then the state identifiers are in turn
/// premultiplied as well, making them usable without additional modification.
///
/// `'a` corresponding to the lifetime of original DFA, `T` corresponds to
/// the type of the transition table itself and `S` corresponds to the state
/// identifier representation.
#[cfg(feature = "std")]
pub(crate) struct StateIter<'a, T: 'a, S: 'a> {
    dfa: &'a Repr<T, S>,
    it: iter::Enumerate<slice::Chunks<'a, S>>,
}

#[cfg(feature = "std")]
impl<'a, T: AsRef<[S]>, S: StateID> Iterator for StateIter<'a, T, S> {
    type Item = (S, State<'a, S>);

    fn next(&mut self) -> Option<(S, State<'a, S>)> {
        self.it.next().map(|(id, chunk)| {
            let state = State { transitions: chunk };
            let id = if self.dfa.premultiplied {
                id * self.dfa.alphabet_len()
            } else {
                id
            };
            (S::from_usize(id), state)
        })
    }
}

/// An immutable representation of a single DFA state.
///
/// `'a` correspondings to the lifetime of a DFA's transition table and `S`
/// corresponds to the state identifier representation.
#[cfg(feature = "std")]
pub(crate) struct State<'a, S: 'a> {
    transitions: &'a [S],
}

#[cfg(feature = "std")]
impl<'a, S: StateID> State<'a, S> {
    /// Return an iterator over all transitions in this state. This yields
    /// a number of transitions equivalent to the alphabet length of the
    /// corresponding DFA.
    ///
    /// Each transition is represented by a tuple. The first element is
    /// the input byte for that transition and the second element is the
    /// transitions itself.
    pub fn transitions(&self) -> StateTransitionIter<S> {
        StateTransitionIter { it: self.transitions.iter().enumerate() }
    }

    /// Return an iterator over a sparse representation of the transitions in
    /// this state. Only non-dead transitions are returned.
    ///
    /// The "sparse" representation in this case corresponds to a sequence of
    /// triples. The first two elements of the triple comprise an inclusive
    /// byte range while the last element corresponds to the transition taken
    /// for all bytes in the range.
    ///
    /// This is somewhat more condensed than the classical sparse
    /// representation (where you have an element for every non-dead
    /// transition), but in practice, checking if a byte is in a range is very
    /// cheap and using ranges tends to conserve quite a bit more space.
    pub fn sparse_transitions(&self) -> StateSparseTransitionIter<S> {
        StateSparseTransitionIter { dense: self.transitions(), cur: None }
    }
}

#[cfg(feature = "std")]
impl<'a, S: StateID> fmt::Debug for State<'a, S> {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        let mut transitions = vec![];
        for (start, end, next_id) in self.sparse_transitions() {
            let line = if start == end {
                format!("{} => {}", escape(start), next_id.to_usize())
            } else {
                format!(
                    "{}-{} => {}",
                    escape(start),
                    escape(end),
                    next_id.to_usize(),
                )
            };
            transitions.push(line);
        }
        write!(f, "{}", transitions.join(", "))?;
        Ok(())
    }
}

/// An iterator over all transitions in a single DFA state. This yields
/// a number of transitions equivalent to the alphabet length of the
/// corresponding DFA.
///
/// Each transition is represented by a tuple. The first element is the input
/// byte for that transition and the second element is the transitions itself.
#[cfg(feature = "std")]
#[derive(Debug)]
pub(crate) struct StateTransitionIter<'a, S: 'a> {
    it: iter::Enumerate<slice::Iter<'a, S>>,
}

#[cfg(feature = "std")]
impl<'a, S: StateID> Iterator for StateTransitionIter<'a, S> {
    type Item = (u8, S);

    fn next(&mut self) -> Option<(u8, S)> {
        self.it.next().map(|(i, &id)| (i as u8, id))
    }
}

/// An iterator over all transitions in a single DFA state using a sparse
/// representation.
///
/// Each transition is represented by a triple. The first two elements of the
/// triple comprise an inclusive byte range while the last element corresponds
/// to the transition taken for all bytes in the range.
#[cfg(feature = "std")]
#[derive(Debug)]
pub(crate) struct StateSparseTransitionIter<'a, S: 'a> {
    dense: StateTransitionIter<'a, S>,
    cur: Option<(u8, u8, S)>,
}

#[cfg(feature = "std")]
impl<'a, S: StateID> Iterator for StateSparseTransitionIter<'a, S> {
    type Item = (u8, u8, S);

    fn next(&mut self) -> Option<(u8, u8, S)> {
        while let Some((b, next)) = self.dense.next() {
            let (prev_start, prev_end, prev_next) = match self.cur {
                Some(t) => t,
                None => {
                    self.cur = Some((b, b, next));
                    continue;
                }
            };
            if prev_next == next {
                self.cur = Some((prev_start, b, prev_next));
            } else {
                self.cur = Some((b, b, next));
                if prev_next != dead_id() {
                    return Some((prev_start, prev_end, prev_next));
                }
            }
        }
        if let Some((start, end, next)) = self.cur.take() {
            if next != dead_id() {
                return Some((start, end, next));
            }
        }
        None
    }
}

/// A mutable representation of a single DFA state.
///
/// `'a` correspondings to the lifetime of a DFA's transition table and `S`
/// corresponds to the state identifier representation.
#[cfg(feature = "std")]
pub(crate) struct StateMut<'a, S: 'a> {
    transitions: &'a mut [S],
}

#[cfg(feature = "std")]
impl<'a, S: StateID> StateMut<'a, S> {
    /// Return an iterator over all transitions in this state. This yields
    /// a number of transitions equivalent to the alphabet length of the
    /// corresponding DFA.
    ///
    /// Each transition is represented by a tuple. The first element is the
    /// input byte for that transition and the second element is a mutable
    /// reference to the transition itself.
    pub fn iter_mut(&mut self) -> StateTransitionIterMut<S> {
        StateTransitionIterMut { it: self.transitions.iter_mut().enumerate() }
    }
}

#[cfg(feature = "std")]
impl<'a, S: StateID> fmt::Debug for StateMut<'a, S> {
    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
        fmt::Debug::fmt(&State { transitions: self.transitions }, f)
    }
}

/// A mutable iterator over all transitions in a DFA state.
///
/// Each transition is represented by a tuple. The first element is the
/// input byte for that transition and the second element is a mutable
/// reference to the transition itself.
#[cfg(feature = "std")]
#[derive(Debug)]
pub(crate) struct StateTransitionIterMut<'a, S: 'a> {
    it: iter::Enumerate<slice::IterMut<'a, S>>,
}

#[cfg(feature = "std")]
impl<'a, S: StateID> Iterator for StateTransitionIterMut<'a, S> {
    type Item = (u8, &'a mut S);

    fn next(&mut self) -> Option<(u8, &'a mut S)> {
        self.it.next().map(|(i, id)| (i as u8, id))
    }
}

/// A builder for constructing a deterministic finite automaton from regular
/// expressions.
///
/// This builder permits configuring several aspects of the construction
/// process such as case insensitivity, Unicode support and various options
/// that impact the size of the generated DFA. In some cases, options (like
/// performing DFA minimization) can come with a substantial additional cost.
///
/// This builder always constructs a *single* DFA. As such, this builder can
/// only be used to construct regexes that either detect the presence of a
/// match or find the end location of a match. A single DFA cannot produce both
/// the start and end of a match. For that information, use a
/// [`Regex`](struct.Regex.html), which can be similarly configured using
/// [`RegexBuilder`](struct.RegexBuilder.html).
#[cfg(feature = "std")]
#[derive(Clone, Debug)]
pub struct Builder {
    parser: ParserBuilder,
    nfa: nfa::Builder,
    anchored: bool,
    minimize: bool,
    premultiply: bool,
    byte_classes: bool,
    reverse: bool,
    longest_match: bool,
}

#[cfg(feature = "std")]
impl Builder {
    /// Create a new DenseDFA builder with the default configuration.
    pub fn new() -> Builder {
        let mut nfa = nfa::Builder::new();
        // This is enabled by default, but we set it here anyway. Since we're
        // building a DFA, shrinking the NFA is always a good idea.
        nfa.shrink(true);
        Builder {
            parser: ParserBuilder::new(),
            nfa,
            anchored: false,
            minimize: false,
            premultiply: true,
            byte_classes: true,
            reverse: false,
            longest_match: false,
        }
    }

    /// Build a DFA from the given pattern.
    ///
    /// If there was a problem parsing or compiling the pattern, then an error
    /// is returned.
    pub fn build(&self, pattern: &str) -> Result<DenseDFA<Vec<usize>, usize>> {
        self.build_with_size::<usize>(pattern)
    }

    /// Build a DFA from the given pattern using a specific representation for
    /// the DFA's state IDs.
    ///
    /// If there was a problem parsing or compiling the pattern, then an error
    /// is returned.
    ///
    /// The representation of state IDs is determined by the `S` type
    /// parameter. In general, `S` is usually one of `u8`, `u16`, `u32`, `u64`
    /// or `usize`, where `usize` is the default used for `build`. The purpose
    /// of specifying a representation for state IDs is to reduce the memory
    /// footprint of a DFA.
    ///
    /// When using this routine, the chosen state ID representation will be
    /// used throughout determinization and minimization, if minimization
    /// was requested. Even if the minimized DFA can fit into the chosen
    /// state ID representation but the initial determinized DFA cannot,
    /// then this will still return an error. To get a minimized DFA with a
    /// smaller state ID representation, first build it with a bigger state ID
    /// representation, and then shrink the size of the DFA using one of its
    /// conversion routines, such as
    /// [`DenseDFA::to_u16`](enum.DenseDFA.html#method.to_u16).
    pub fn build_with_size<S: StateID>(
        &self,
        pattern: &str,
    ) -> Result<DenseDFA<Vec<S>, S>> {
        self.build_from_nfa(&self.build_nfa(pattern)?)
    }

    /// An internal only (for now) API for building a dense DFA directly from
    /// an NFA.
    pub(crate) fn build_from_nfa<S: StateID>(
        &self,
        nfa: &NFA,
    ) -> Result<DenseDFA<Vec<S>, S>> {
        if self.longest_match && !self.anchored {
            return Err(Error::unsupported_longest_match());
        }

        let mut dfa = if self.byte_classes {
            Determinizer::new(nfa)
                .with_byte_classes()
                .longest_match(self.longest_match)
                .build()
        } else {
            Determinizer::new(nfa).longest_match(self.longest_match).build()
        }?;
        if self.minimize {
            dfa.minimize();
        }
        if self.premultiply {
            dfa.premultiply()?;
        }
        Ok(dfa.into_dense_dfa())
    }

    /// Builds an NFA from the given pattern.
    pub(crate) fn build_nfa(&self, pattern: &str) -> Result<NFA> {
        let hir = self.parser.build().parse(pattern).map_err(Error::syntax)?;
        Ok(self.nfa.build(&hir)?)
    }

    /// Set whether matching must be anchored at the beginning of the input.
    ///
    /// When enabled, a match must begin at the start of the input. When
    /// disabled, the DFA will act as if the pattern started with a `.*?`,
    /// which enables a match to appear anywhere.
    ///
    /// By default this is disabled.
    pub fn anchored(&mut self, yes: bool) -> &mut Builder {
        self.anchored = yes;
        self.nfa.anchored(yes);
        self
    }

    /// Enable or disable the case insensitive flag by default.
    ///
    /// By default this is disabled. It may alternatively be selectively
    /// enabled in the regular expression itself via the `i` flag.
    pub fn case_insensitive(&mut self, yes: bool) -> &mut Builder {
        self.parser.case_insensitive(yes);
        self
    }

    /// Enable verbose mode in the regular expression.
    ///
    /// When enabled, verbose mode permits insigificant whitespace in many
    /// places in the regular expression, as well as comments. Comments are
    /// started using `#` and continue until the end of the line.
    ///
    /// By default, this is disabled. It may be selectively enabled in the
    /// regular expression by using the `x` flag regardless of this setting.
    pub fn ignore_whitespace(&mut self, yes: bool) -> &mut Builder {
        self.parser.ignore_whitespace(yes);
        self
    }

    /// Enable or disable the "dot matches any character" flag by default.
    ///
    /// By default this is disabled. It may alternatively be selectively
    /// enabled in the regular expression itself via the `s` flag.
    pub fn dot_matches_new_line(&mut self, yes: bool) -> &mut Builder {
        self.parser.dot_matches_new_line(yes);
        self
    }

    /// Enable or disable the "swap greed" flag by default.
    ///
    /// By default this is disabled. It may alternatively be selectively
    /// enabled in the regular expression itself via the `U` flag.
    pub fn swap_greed(&mut self, yes: bool) -> &mut Builder {
        self.parser.swap_greed(yes);
        self
    }

    /// Enable or disable the Unicode flag (`u`) by default.
    ///
    /// By default this is **enabled**. It may alternatively be selectively
    /// disabled in the regular expression itself via the `u` flag.
    ///
    /// Note that unless `allow_invalid_utf8` is enabled (it's disabled by
    /// default), a regular expression will fail to parse if Unicode mode is
    /// disabled and a sub-expression could possibly match invalid UTF-8.
    pub fn unicode(&mut self, yes: bool) -> &mut Builder {
        self.parser.unicode(yes);
        self
    }

    /// When enabled, the builder will permit the construction of a regular
    /// expression that may match invalid UTF-8.
    ///
    /// When disabled (the default), the builder is guaranteed to produce a
    /// regex that will only ever match valid UTF-8 (otherwise, the builder
    /// will return an error).
    pub fn allow_invalid_utf8(&mut self, yes: bool) -> &mut Builder {
        self.parser.allow_invalid_utf8(yes);
        self.nfa.allow_invalid_utf8(yes);
        self
    }

    /// Set the nesting limit used for the regular expression parser.
    ///
    /// The nesting limit controls how deep the abstract syntax tree is allowed
    /// to be. If the AST exceeds the given limit (e.g., with too many nested
    /// groups), then an error is returned by the parser.
    ///
    /// The purpose of this limit is to act as a heuristic to prevent stack
    /// overflow when building a finite automaton from a regular expression's
    /// abstract syntax tree. In particular, construction currently uses
    /// recursion. In the future, the implementation may stop using recursion
    /// and this option will no longer be necessary.
    ///
    /// This limit is not checked until the entire AST is parsed. Therefore,
    /// if callers want to put a limit on the amount of heap space used, then
    /// they should impose a limit on the length, in bytes, of the concrete
    /// pattern string. In particular, this is viable since the parser will
    /// limit itself to heap space proportional to the lenth of the pattern
    /// string.
    ///
    /// Note that a nest limit of `0` will return a nest limit error for most
    /// patterns but not all. For example, a nest limit of `0` permits `a` but
    /// not `ab`, since `ab` requires a concatenation AST item, which results
    /// in a nest depth of `1`. In general, a nest limit is not something that
    /// manifests in an obvious way in the concrete syntax, therefore, it
    /// should not be used in a granular way.
    pub fn nest_limit(&mut self, limit: u32) -> &mut Builder {
        self.parser.nest_limit(limit);
        self
    }

    /// Minimize the DFA.
    ///
    /// When enabled, the DFA built will be minimized such that it is as small
    /// as possible.
    ///
    /// Whether one enables minimization or not depends on the types of costs
    /// you're willing to pay and how much you care about its benefits. In
    /// particular, minimization has worst case `O(n*k*logn)` time and `O(k*n)`
    /// space, where `n` is the number of DFA states and `k` is the alphabet
    /// size. In practice, minimization can be quite costly in terms of both
    /// space and time, so it should only be done if you're willing to wait
    /// longer to produce a DFA. In general, you might want a minimal DFA in
    /// the following circumstances:
    ///
    /// 1. You would like to optimize for the size of the automaton. This can
    ///    manifest in one of two ways. Firstly, if you're converting the
    ///    DFA into Rust code (or a table embedded in the code), then a minimal
    ///    DFA will translate into a corresponding reduction in code  size, and
    ///    thus, also the final compiled binary size. Secondly, if you are
    ///    building many DFAs and putting them on the heap, you'll be able to
    ///    fit more if they are smaller. Note though that building a minimal
    ///    DFA itself requires additional space; you only realize the space
    ///    savings once the minimal DFA is constructed (at which point, the
    ///    space used for minimization is freed).
    /// 2. You've observed that a smaller DFA results in faster match
    ///    performance. Naively, this isn't guaranteed since there is no
    ///    inherent difference between matching with a bigger-than-minimal
    ///    DFA and a minimal DFA. However, a smaller DFA may make use of your
    ///    CPU's cache more efficiently.
    /// 3. You are trying to establish an equivalence between regular
    ///    languages. The standard method for this is to build a minimal DFA
    ///    for each language and then compare them. If the DFAs are equivalent
    ///    (up to state renaming), then the languages are equivalent.
    ///
    /// This option is disabled by default.
    pub fn minimize(&mut self, yes: bool) -> &mut Builder {
        self.minimize = yes;
        self
    }

    /// Premultiply state identifiers in the DFA's transition table.
    ///
    /// When enabled, state identifiers are premultiplied to point to their
    /// corresponding row in the DFA's transition table. That is, given the
    /// `i`th state, its corresponding premultiplied identifier is `i * k`
    /// where `k` is the alphabet size of the DFA. (The alphabet size is at
    /// most 256, but is in practice smaller if byte classes is enabled.)
    ///
    /// When state identifiers are not premultiplied, then the identifier of
    /// the `i`th state is `i`.
    ///
    /// The advantage of premultiplying state identifiers is that is saves
    /// a multiplication instruction per byte when searching with the DFA.
    /// This has been observed to lead to a 20% performance benefit in
    /// micro-benchmarks.
    ///
    /// The primary disadvantage of premultiplying state identifiers is
    /// that they require a larger integer size to represent. For example,
    /// if your DFA has 200 states, then its premultiplied form requires
    /// 16 bits to represent every possible state identifier, where as its
    /// non-premultiplied form only requires 8 bits.
    ///
    /// This option is enabled by default.
    pub fn premultiply(&mut self, yes: bool) -> &mut Builder {
        self.premultiply = yes;
        self
    }

    /// Shrink the size of the DFA's alphabet by mapping bytes to their
    /// equivalence classes.
    ///
    /// When enabled, each DFA will use a map from all possible bytes to their
    /// corresponding equivalence class. Each equivalence class represents a
    /// set of bytes that does not discriminate between a match and a non-match
    /// in the DFA. For example, the pattern `[ab]+` has at least two
    /// equivalence classes: a set containing `a` and `b` and a set containing
    /// every byte except for `a` and `b`. `a` and `b` are in the same
    /// equivalence classes because they never discriminate between a match
    /// and a non-match.
    ///
    /// The advantage of this map is that the size of the transition table can
    /// be reduced drastically from `#states * 256 * sizeof(id)` to
    /// `#states * k * sizeof(id)` where `k` is the number of equivalence
    /// classes. As a result, total space usage can decrease substantially.
    /// Moreover, since a smaller alphabet is used, compilation becomes faster
    /// as well.
    ///
    /// The disadvantage of this map is that every byte searched must be
    /// passed through this map before it can be used to determine the next
    /// transition. This has a small match time performance cost.
    ///
    /// This option is enabled by default.
    pub fn byte_classes(&mut self, yes: bool) -> &mut Builder {
        self.byte_classes = yes;
        self
    }

    /// Reverse the DFA.
    ///
    /// A DFA reversal is performed by reversing all of the concatenated
    /// sub-expressions in the original pattern, recursively. The resulting
    /// DFA can be used to match the pattern starting from the end of a string
    /// instead of the beginning of a string.
    ///
    /// Generally speaking, a reversed DFA is most useful for finding the start
    /// of a match, since a single forward DFA is only capable of finding the
    /// end of a match. This start of match handling is done for you
    /// automatically if you build a [`Regex`](struct.Regex.html).
    pub fn reverse(&mut self, yes: bool) -> &mut Builder {
        self.reverse = yes;
        self.nfa.reverse(yes);
        self
    }

    /// Find the longest possible match.
    ///
    /// This is distinct from the default leftmost-first match semantics in
    /// that it treats all NFA states as having equivalent priority. In other
    /// words, the longest possible match is always found and it is not
    /// possible to implement non-greedy match semantics when this is set. That
    /// is, `a+` and `a+?` are equivalent when this is enabled.
    ///
    /// In particular, a practical issue with this option at the moment is that
    /// it prevents unanchored searches from working correctly, since
    /// unanchored searches are implemented by prepending an non-greedy `.*?`
    /// to the beginning of the pattern. As stated above, non-greedy match
    /// semantics aren't supported. Therefore, if this option is enabled and
    /// an unanchored search is requested, then building a DFA will return an
    /// error.
    ///
    /// This option is principally useful when building a reverse DFA for
    /// finding the start of a match. If you are building a regex with
    /// [`RegexBuilder`](struct.RegexBuilder.html), then this is handled for
    /// you automatically. The reason why this is necessary for start of match
    /// handling is because we want to find the earliest possible starting
    /// position of a match to satisfy leftmost-first match semantics. When
    /// matching in reverse, this means finding the longest possible match,
    /// hence, this option.
    ///
    /// By default this is disabled.
    pub fn longest_match(&mut self, yes: bool) -> &mut Builder {
        // There is prior art in RE2 that shows how this can support unanchored
        // searches. Instead of treating all NFA states as having equivalent
        // priority, we instead group NFA states into sets, and treat members
        // of each set as having equivalent priority, but having greater
        // priority than all following members of different sets. We then
        // essentially assign a higher priority to everything over the prefix
        // `.*?`.
        self.longest_match = yes;
        self
    }

    /// Apply best effort heuristics to shrink the NFA at the expense of more
    /// time/memory.
    ///
    /// This may be exposed in the future, but for now is exported for use in
    /// the `regex-automata-debug` tool.
    #[doc(hidden)]
    pub fn shrink(&mut self, yes: bool) -> &mut Builder {
        self.nfa.shrink(yes);
        self
    }
}

#[cfg(feature = "std")]
impl Default for Builder {
    fn default() -> Builder {
        Builder::new()
    }
}

/// Return the given byte as its escaped string form.
#[cfg(feature = "std")]
fn escape(b: u8) -> String {
    use std::ascii;

    String::from_utf8(ascii::escape_default(b).collect::<Vec<_>>()).unwrap()
}

#[cfg(all(test, feature = "std"))]
mod tests {
    use super::*;

    #[test]
    fn errors_when_converting_to_smaller_dfa() {
        let pattern = r"\w{10}";
        let dfa = Builder::new()
            .byte_classes(false)
            .anchored(true)
            .premultiply(false)
            .build_with_size::<u16>(pattern)
            .unwrap();
        assert!(dfa.to_u8().is_err());
    }

    #[test]
    fn errors_when_determinization_would_overflow() {
        let pattern = r"\w{10}";

        let mut builder = Builder::new();
        builder.byte_classes(false).anchored(true).premultiply(false);
        // using u16 is fine
        assert!(builder.build_with_size::<u16>(pattern).is_ok());
        // // ... but u8 results in overflow (because there are >256 states)
        assert!(builder.build_with_size::<u8>(pattern).is_err());
    }

    #[test]
    fn errors_when_premultiply_would_overflow() {
        let pattern = r"[a-z]";

        let mut builder = Builder::new();
        builder.byte_classes(false).anchored(true).premultiply(false);
        // without premultiplication is OK
        assert!(builder.build_with_size::<u8>(pattern).is_ok());
        // ... but with premultiplication overflows u8
        builder.premultiply(true);
        assert!(builder.build_with_size::<u8>(pattern).is_err());
    }

    // let data = ::std::fs::read_to_string("/usr/share/dict/words").unwrap();
    // let mut words: Vec<&str> = data.lines().collect();
    // println!("{} words", words.len());
    // words.sort_by(|w1, w2| w1.len().cmp(&w2.len()).reverse());
    // let pattern = words.join("|");
    // print_automata_counts(&pattern);
    // print_automata(&pattern);

    // print_automata(r"[01]*1[01]{5}");
    // print_automata(r"X(.?){0,8}Y");
    // print_automata_counts(r"\p{alphabetic}");
    // print_automata(r"a*b+|cdefg");
    // print_automata(r"(..)*(...)*");

    // let pattern = r"\p{any}*?\p{Other_Uppercase}";
    // let pattern = r"\p{any}*?\w+";
    // print_automata_counts(pattern);
    // print_automata_counts(r"(?-u:\w)");

    // let pattern = r"\p{Greek}";
    // let pattern = r"zZzZzZzZzZ";
    // let pattern = grapheme_pattern();
    // let pattern = r"\p{Ideographic}";
    // let pattern = r"\w{10}"; // 51784 --> 41264
    // let pattern = r"\w"; // 5182
    // let pattern = r"a*";
    // print_automata(pattern);
    // let (_, _, dfa) = build_automata(pattern);
}