1// Copyright 2010 The Go Authors. All rights reserved. 2// Use of this source code is governed by a BSD-style 3// license that can be found in the LICENSE file. 4 5package regexp 6 7import ( 8 "bufio" 9 "compress/bzip2" 10 "fmt" 11 "internal/testenv" 12 "io" 13 "os" 14 "path/filepath" 15 "regexp/syntax" 16 "strconv" 17 "strings" 18 "testing" 19 "unicode/utf8" 20) 21 22// TestRE2 tests this package's regexp API against test cases 23// considered during RE2's exhaustive tests, which run all possible 24// regexps over a given set of atoms and operators, up to a given 25// complexity, over all possible strings over a given alphabet, 26// up to a given size. Rather than try to link with RE2, we read a 27// log file containing the test cases and the expected matches. 28// The log file, re2-exhaustive.txt, is generated by running 'make log' 29// in the open source RE2 distribution https://github.com/google/re2/. 30// 31// The test file format is a sequence of stanzas like: 32// 33// strings 34// "abc" 35// "123x" 36// regexps 37// "[a-z]+" 38// 0-3;0-3 39// -;- 40// "([0-9])([0-9])([0-9])" 41// -;- 42// -;0-3 0-1 1-2 2-3 43// 44// The stanza begins by defining a set of strings, quoted 45// using Go double-quote syntax, one per line. Then the 46// regexps section gives a sequence of regexps to run on 47// the strings. In the block that follows a regexp, each line 48// gives the semicolon-separated match results of running 49// the regexp on the corresponding string. 50// Each match result is either a single -, meaning no match, or a 51// space-separated sequence of pairs giving the match and 52// submatch indices. An unmatched subexpression formats 53// its pair as a single - (not illustrated above). For now 54// each regexp run produces two match results, one for a 55// ``full match'' that restricts the regexp to matching the entire 56// string or nothing, and one for a ``partial match'' that gives 57// the leftmost first match found in the string. 58// 59// Lines beginning with # are comments. Lines beginning with 60// a capital letter are test names printed during RE2's test suite 61// and are echoed into t but otherwise ignored. 62// 63// At time of writing, re2-exhaustive.txt is 59 MB but compresses to 385 kB, 64// so we store re2-exhaustive.txt.bz2 in the repository and decompress it on the fly. 65// 66func TestRE2Search(t *testing.T) { 67 testRE2(t, "testdata/re2-search.txt") 68} 69 70func testRE2(t *testing.T, file string) { 71 f, err := os.Open(file) 72 if err != nil { 73 t.Fatal(err) 74 } 75 defer f.Close() 76 var txt io.Reader 77 if strings.HasSuffix(file, ".bz2") { 78 z := bzip2.NewReader(f) 79 txt = z 80 file = file[:len(file)-len(".bz2")] // for error messages 81 } else { 82 txt = f 83 } 84 lineno := 0 85 scanner := bufio.NewScanner(txt) 86 var ( 87 str []string 88 input []string 89 inStrings bool 90 re *Regexp 91 refull *Regexp 92 nfail int 93 ncase int 94 ) 95 for lineno := 1; scanner.Scan(); lineno++ { 96 line := scanner.Text() 97 switch { 98 case line == "": 99 t.Fatalf("%s:%d: unexpected blank line", file, lineno) 100 case line[0] == '#': 101 continue 102 case 'A' <= line[0] && line[0] <= 'Z': 103 // Test name. 104 t.Logf("%s\n", line) 105 continue 106 case line == "strings": 107 str = str[:0] 108 inStrings = true 109 case line == "regexps": 110 inStrings = false 111 case line[0] == '"': 112 q, err := strconv.Unquote(line) 113 if err != nil { 114 // Fatal because we'll get out of sync. 115 t.Fatalf("%s:%d: unquote %s: %v", file, lineno, line, err) 116 } 117 if inStrings { 118 str = append(str, q) 119 continue 120 } 121 // Is a regexp. 122 if len(input) != 0 { 123 t.Fatalf("%s:%d: out of sync: have %d strings left before %#q", file, lineno, len(input), q) 124 } 125 re, err = tryCompile(q) 126 if err != nil { 127 if err.Error() == "error parsing regexp: invalid escape sequence: `\\C`" { 128 // We don't and likely never will support \C; keep going. 129 continue 130 } 131 t.Errorf("%s:%d: compile %#q: %v", file, lineno, q, err) 132 if nfail++; nfail >= 100 { 133 t.Fatalf("stopping after %d errors", nfail) 134 } 135 continue 136 } 137 full := `\A(?:` + q + `)\z` 138 refull, err = tryCompile(full) 139 if err != nil { 140 // Fatal because q worked, so this should always work. 141 t.Fatalf("%s:%d: compile full %#q: %v", file, lineno, full, err) 142 } 143 input = str 144 case line[0] == '-' || '0' <= line[0] && line[0] <= '9': 145 // A sequence of match results. 146 ncase++ 147 if re == nil { 148 // Failed to compile: skip results. 149 continue 150 } 151 if len(input) == 0 { 152 t.Fatalf("%s:%d: out of sync: no input remaining", file, lineno) 153 } 154 var text string 155 text, input = input[0], input[1:] 156 if !isSingleBytes(text) && strings.Contains(re.String(), `\B`) { 157 // RE2's \B considers every byte position, 158 // so it sees 'not word boundary' in the 159 // middle of UTF-8 sequences. This package 160 // only considers the positions between runes, 161 // so it disagrees. Skip those cases. 162 continue 163 } 164 res := strings.Split(line, ";") 165 if len(res) != len(run) { 166 t.Fatalf("%s:%d: have %d test results, want %d", file, lineno, len(res), len(run)) 167 } 168 for i := range res { 169 have, suffix := run[i](re, refull, text) 170 want := parseResult(t, file, lineno, res[i]) 171 if !same(have, want) { 172 t.Errorf("%s:%d: %#q%s.FindSubmatchIndex(%#q) = %v, want %v", file, lineno, re, suffix, text, have, want) 173 if nfail++; nfail >= 100 { 174 t.Fatalf("stopping after %d errors", nfail) 175 } 176 continue 177 } 178 b, suffix := match[i](re, refull, text) 179 if b != (want != nil) { 180 t.Errorf("%s:%d: %#q%s.MatchString(%#q) = %v, want %v", file, lineno, re, suffix, text, b, !b) 181 if nfail++; nfail >= 100 { 182 t.Fatalf("stopping after %d errors", nfail) 183 } 184 continue 185 } 186 } 187 188 default: 189 t.Fatalf("%s:%d: out of sync: %s\n", file, lineno, line) 190 } 191 } 192 if err := scanner.Err(); err != nil { 193 t.Fatalf("%s:%d: %v", file, lineno, err) 194 } 195 if len(input) != 0 { 196 t.Fatalf("%s:%d: out of sync: have %d strings left at EOF", file, lineno, len(input)) 197 } 198 t.Logf("%d cases tested", ncase) 199} 200 201var run = []func(*Regexp, *Regexp, string) ([]int, string){ 202 runFull, 203 runPartial, 204 runFullLongest, 205 runPartialLongest, 206} 207 208func runFull(re, refull *Regexp, text string) ([]int, string) { 209 refull.longest = false 210 return refull.FindStringSubmatchIndex(text), "[full]" 211} 212 213func runPartial(re, refull *Regexp, text string) ([]int, string) { 214 re.longest = false 215 return re.FindStringSubmatchIndex(text), "" 216} 217 218func runFullLongest(re, refull *Regexp, text string) ([]int, string) { 219 refull.longest = true 220 return refull.FindStringSubmatchIndex(text), "[full,longest]" 221} 222 223func runPartialLongest(re, refull *Regexp, text string) ([]int, string) { 224 re.longest = true 225 return re.FindStringSubmatchIndex(text), "[longest]" 226} 227 228var match = []func(*Regexp, *Regexp, string) (bool, string){ 229 matchFull, 230 matchPartial, 231 matchFullLongest, 232 matchPartialLongest, 233} 234 235func matchFull(re, refull *Regexp, text string) (bool, string) { 236 refull.longest = false 237 return refull.MatchString(text), "[full]" 238} 239 240func matchPartial(re, refull *Regexp, text string) (bool, string) { 241 re.longest = false 242 return re.MatchString(text), "" 243} 244 245func matchFullLongest(re, refull *Regexp, text string) (bool, string) { 246 refull.longest = true 247 return refull.MatchString(text), "[full,longest]" 248} 249 250func matchPartialLongest(re, refull *Regexp, text string) (bool, string) { 251 re.longest = true 252 return re.MatchString(text), "[longest]" 253} 254 255func isSingleBytes(s string) bool { 256 for _, c := range s { 257 if c >= utf8.RuneSelf { 258 return false 259 } 260 } 261 return true 262} 263 264func tryCompile(s string) (re *Regexp, err error) { 265 // Protect against panic during Compile. 266 defer func() { 267 if r := recover(); r != nil { 268 err = fmt.Errorf("panic: %v", r) 269 } 270 }() 271 return Compile(s) 272} 273 274func parseResult(t *testing.T, file string, lineno int, res string) []int { 275 // A single - indicates no match. 276 if res == "-" { 277 return nil 278 } 279 // Otherwise, a space-separated list of pairs. 280 n := 1 281 for j := 0; j < len(res); j++ { 282 if res[j] == ' ' { 283 n++ 284 } 285 } 286 out := make([]int, 2*n) 287 i := 0 288 n = 0 289 for j := 0; j <= len(res); j++ { 290 if j == len(res) || res[j] == ' ' { 291 // Process a single pair. - means no submatch. 292 pair := res[i:j] 293 if pair == "-" { 294 out[n] = -1 295 out[n+1] = -1 296 } else { 297 k := strings.Index(pair, "-") 298 if k < 0 { 299 t.Fatalf("%s:%d: invalid pair %s", file, lineno, pair) 300 } 301 lo, err1 := strconv.Atoi(pair[:k]) 302 hi, err2 := strconv.Atoi(pair[k+1:]) 303 if err1 != nil || err2 != nil || lo > hi { 304 t.Fatalf("%s:%d: invalid pair %s", file, lineno, pair) 305 } 306 out[n] = lo 307 out[n+1] = hi 308 } 309 n += 2 310 i = j + 1 311 } 312 } 313 return out 314} 315 316func same(x, y []int) bool { 317 if len(x) != len(y) { 318 return false 319 } 320 for i, xi := range x { 321 if xi != y[i] { 322 return false 323 } 324 } 325 return true 326} 327 328// TestFowler runs this package's regexp API against the 329// POSIX regular expression tests collected by Glenn Fowler 330// at http://www2.research.att.com/~astopen/testregex/testregex.html. 331func TestFowler(t *testing.T) { 332 files, err := filepath.Glob("testdata/*.dat") 333 if err != nil { 334 t.Fatal(err) 335 } 336 for _, file := range files { 337 t.Log(file) 338 testFowler(t, file) 339 } 340} 341 342var notab = MustCompilePOSIX(`[^\t]+`) 343 344func testFowler(t *testing.T, file string) { 345 f, err := os.Open(file) 346 if err != nil { 347 t.Error(err) 348 return 349 } 350 defer f.Close() 351 b := bufio.NewReader(f) 352 lineno := 0 353 lastRegexp := "" 354Reading: 355 for { 356 lineno++ 357 line, err := b.ReadString('\n') 358 if err != nil { 359 if err != io.EOF { 360 t.Errorf("%s:%d: %v", file, lineno, err) 361 } 362 break Reading 363 } 364 365 // http://www2.research.att.com/~astopen/man/man1/testregex.html 366 // 367 // INPUT FORMAT 368 // Input lines may be blank, a comment beginning with #, or a test 369 // specification. A specification is five fields separated by one 370 // or more tabs. NULL denotes the empty string and NIL denotes the 371 // 0 pointer. 372 if line[0] == '#' || line[0] == '\n' { 373 continue Reading 374 } 375 line = line[:len(line)-1] 376 field := notab.FindAllString(line, -1) 377 for i, f := range field { 378 if f == "NULL" { 379 field[i] = "" 380 } 381 if f == "NIL" { 382 t.Logf("%s:%d: skip: %s", file, lineno, line) 383 continue Reading 384 } 385 } 386 if len(field) == 0 { 387 continue Reading 388 } 389 390 // Field 1: the regex(3) flags to apply, one character per REG_feature 391 // flag. The test is skipped if REG_feature is not supported by the 392 // implementation. If the first character is not [BEASKLP] then the 393 // specification is a global control line. One or more of [BEASKLP] may be 394 // specified; the test will be repeated for each mode. 395 // 396 // B basic BRE (grep, ed, sed) 397 // E REG_EXTENDED ERE (egrep) 398 // A REG_AUGMENTED ARE (egrep with negation) 399 // S REG_SHELL SRE (sh glob) 400 // K REG_SHELL|REG_AUGMENTED KRE (ksh glob) 401 // L REG_LITERAL LRE (fgrep) 402 // 403 // a REG_LEFT|REG_RIGHT implicit ^...$ 404 // b REG_NOTBOL lhs does not match ^ 405 // c REG_COMMENT ignore space and #...\n 406 // d REG_SHELL_DOT explicit leading . match 407 // e REG_NOTEOL rhs does not match $ 408 // f REG_MULTIPLE multiple \n separated patterns 409 // g FNM_LEADING_DIR testfnmatch only -- match until / 410 // h REG_MULTIREF multiple digit backref 411 // i REG_ICASE ignore case 412 // j REG_SPAN . matches \n 413 // k REG_ESCAPE \ to escape [...] delimiter 414 // l REG_LEFT implicit ^... 415 // m REG_MINIMAL minimal match 416 // n REG_NEWLINE explicit \n match 417 // o REG_ENCLOSED (|&) magic inside [@|&](...) 418 // p REG_SHELL_PATH explicit / match 419 // q REG_DELIMITED delimited pattern 420 // r REG_RIGHT implicit ...$ 421 // s REG_SHELL_ESCAPED \ not special 422 // t REG_MUSTDELIM all delimiters must be specified 423 // u standard unspecified behavior -- errors not counted 424 // v REG_CLASS_ESCAPE \ special inside [...] 425 // w REG_NOSUB no subexpression match array 426 // x REG_LENIENT let some errors slide 427 // y REG_LEFT regexec() implicit ^... 428 // z REG_NULL NULL subexpressions ok 429 // $ expand C \c escapes in fields 2 and 3 430 // / field 2 is a regsubcomp() expression 431 // = field 3 is a regdecomp() expression 432 // 433 // Field 1 control lines: 434 // 435 // C set LC_COLLATE and LC_CTYPE to locale in field 2 436 // 437 // ?test ... output field 5 if passed and != EXPECTED, silent otherwise 438 // &test ... output field 5 if current and previous passed 439 // |test ... output field 5 if current passed and previous failed 440 // ; ... output field 2 if previous failed 441 // {test ... skip if failed until } 442 // } end of skip 443 // 444 // : comment comment copied as output NOTE 445 // :comment:test :comment: ignored 446 // N[OTE] comment comment copied as output NOTE 447 // T[EST] comment comment 448 // 449 // number use number for nmatch (20 by default) 450 flag := field[0] 451 switch flag[0] { 452 case '?', '&', '|', ';', '{', '}': 453 // Ignore all the control operators. 454 // Just run everything. 455 flag = flag[1:] 456 if flag == "" { 457 continue Reading 458 } 459 case ':': 460 i := strings.Index(flag[1:], ":") 461 if i < 0 { 462 t.Logf("skip: %s", line) 463 continue Reading 464 } 465 flag = flag[1+i+1:] 466 case 'C', 'N', 'T', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9': 467 t.Logf("skip: %s", line) 468 continue Reading 469 } 470 471 // Can check field count now that we've handled the myriad comment formats. 472 if len(field) < 4 { 473 t.Errorf("%s:%d: too few fields: %s", file, lineno, line) 474 continue Reading 475 } 476 477 // Expand C escapes (a.k.a. Go escapes). 478 if strings.Contains(flag, "$") { 479 f := `"` + field[1] + `"` 480 if field[1], err = strconv.Unquote(f); err != nil { 481 t.Errorf("%s:%d: cannot unquote %s", file, lineno, f) 482 } 483 f = `"` + field[2] + `"` 484 if field[2], err = strconv.Unquote(f); err != nil { 485 t.Errorf("%s:%d: cannot unquote %s", file, lineno, f) 486 } 487 } 488 489 // Field 2: the regular expression pattern; SAME uses the pattern from 490 // the previous specification. 491 // 492 if field[1] == "SAME" { 493 field[1] = lastRegexp 494 } 495 lastRegexp = field[1] 496 497 // Field 3: the string to match. 498 text := field[2] 499 500 // Field 4: the test outcome... 501 ok, shouldCompile, shouldMatch, pos := parseFowlerResult(field[3]) 502 if !ok { 503 t.Errorf("%s:%d: cannot parse result %#q", file, lineno, field[3]) 504 continue Reading 505 } 506 507 // Field 5: optional comment appended to the report. 508 509 Testing: 510 // Run test once for each specified capital letter mode that we support. 511 for _, c := range flag { 512 pattern := field[1] 513 syn := syntax.POSIX | syntax.ClassNL 514 switch c { 515 default: 516 continue Testing 517 case 'E': 518 // extended regexp (what we support) 519 case 'L': 520 // literal 521 pattern = QuoteMeta(pattern) 522 } 523 524 for _, c := range flag { 525 switch c { 526 case 'i': 527 syn |= syntax.FoldCase 528 } 529 } 530 531 re, err := compile(pattern, syn, true) 532 if err != nil { 533 if shouldCompile { 534 t.Errorf("%s:%d: %#q did not compile", file, lineno, pattern) 535 } 536 continue Testing 537 } 538 if !shouldCompile { 539 t.Errorf("%s:%d: %#q should not compile", file, lineno, pattern) 540 continue Testing 541 } 542 match := re.MatchString(text) 543 if match != shouldMatch { 544 t.Errorf("%s:%d: %#q.Match(%#q) = %v, want %v", file, lineno, pattern, text, match, shouldMatch) 545 continue Testing 546 } 547 have := re.FindStringSubmatchIndex(text) 548 if (len(have) > 0) != match { 549 t.Errorf("%s:%d: %#q.Match(%#q) = %v, but %#q.FindSubmatchIndex(%#q) = %v", file, lineno, pattern, text, match, pattern, text, have) 550 continue Testing 551 } 552 if len(have) > len(pos) { 553 have = have[:len(pos)] 554 } 555 if !same(have, pos) { 556 t.Errorf("%s:%d: %#q.FindSubmatchIndex(%#q) = %v, want %v", file, lineno, pattern, text, have, pos) 557 } 558 } 559 } 560} 561 562func parseFowlerResult(s string) (ok, compiled, matched bool, pos []int) { 563 // Field 4: the test outcome. This is either one of the posix error 564 // codes (with REG_ omitted) or the match array, a list of (m,n) 565 // entries with m and n being first and last+1 positions in the 566 // field 3 string, or NULL if REG_NOSUB is in effect and success 567 // is expected. BADPAT is acceptable in place of any regcomp(3) 568 // error code. The match[] array is initialized to (-2,-2) before 569 // each test. All array elements from 0 to nmatch-1 must be specified 570 // in the outcome. Unspecified endpoints (offset -1) are denoted by ?. 571 // Unset endpoints (offset -2) are denoted by X. {x}(o:n) denotes a 572 // matched (?{...}) expression, where x is the text enclosed by {...}, 573 // o is the expression ordinal counting from 1, and n is the length of 574 // the unmatched portion of the subject string. If x starts with a 575 // number then that is the return value of re_execf(), otherwise 0 is 576 // returned. 577 switch { 578 case s == "": 579 // Match with no position information. 580 ok = true 581 compiled = true 582 matched = true 583 return 584 case s == "NOMATCH": 585 // Match failure. 586 ok = true 587 compiled = true 588 matched = false 589 return 590 case 'A' <= s[0] && s[0] <= 'Z': 591 // All the other error codes are compile errors. 592 ok = true 593 compiled = false 594 return 595 } 596 compiled = true 597 598 var x []int 599 for s != "" { 600 var end byte = ')' 601 if len(x)%2 == 0 { 602 if s[0] != '(' { 603 ok = false 604 return 605 } 606 s = s[1:] 607 end = ',' 608 } 609 i := 0 610 for i < len(s) && s[i] != end { 611 i++ 612 } 613 if i == 0 || i == len(s) { 614 ok = false 615 return 616 } 617 var v = -1 618 var err error 619 if s[:i] != "?" { 620 v, err = strconv.Atoi(s[:i]) 621 if err != nil { 622 ok = false 623 return 624 } 625 } 626 x = append(x, v) 627 s = s[i+1:] 628 } 629 if len(x)%2 != 0 { 630 ok = false 631 return 632 } 633 ok = true 634 matched = true 635 pos = x 636 return 637} 638 639var text []byte 640 641func makeText(n int) []byte { 642 if len(text) >= n { 643 return text[:n] 644 } 645 text = make([]byte, n) 646 x := ^uint32(0) 647 for i := range text { 648 x += x 649 x ^= 1 650 if int32(x) < 0 { 651 x ^= 0x88888eef 652 } 653 if x%31 == 0 { 654 text[i] = '\n' 655 } else { 656 text[i] = byte(x%(0x7E+1-0x20) + 0x20) 657 } 658 } 659 return text 660} 661 662func BenchmarkMatch(b *testing.B) { 663 isRaceBuilder := strings.HasSuffix(testenv.Builder(), "-race") 664 665 for _, data := range benchData { 666 r := MustCompile(data.re) 667 for _, size := range benchSizes { 668 if (isRaceBuilder || testing.Short()) && size.n > 1<<10 { 669 continue 670 } 671 t := makeText(size.n) 672 b.Run(data.name+"/"+size.name, func(b *testing.B) { 673 b.SetBytes(int64(size.n)) 674 for i := 0; i < b.N; i++ { 675 if r.Match(t) { 676 b.Fatal("match!") 677 } 678 } 679 }) 680 } 681 } 682} 683 684func BenchmarkMatch_onepass_regex(b *testing.B) { 685 isRaceBuilder := strings.HasSuffix(testenv.Builder(), "-race") 686 r := MustCompile(`(?s)\A.*\z`) 687 if r.onepass == nil { 688 b.Fatalf("want onepass regex, but %q is not onepass", r) 689 } 690 for _, size := range benchSizes { 691 if (isRaceBuilder || testing.Short()) && size.n > 1<<10 { 692 continue 693 } 694 t := makeText(size.n) 695 b.Run(size.name, func(b *testing.B) { 696 b.SetBytes(int64(size.n)) 697 b.ReportAllocs() 698 for i := 0; i < b.N; i++ { 699 if !r.Match(t) { 700 b.Fatal("not match!") 701 } 702 } 703 }) 704 } 705} 706 707var benchData = []struct{ name, re string }{ 708 {"Easy0", "ABCDEFGHIJKLMNOPQRSTUVWXYZ$"}, 709 {"Easy0i", "(?i)ABCDEFGHIJklmnopqrstuvwxyz$"}, 710 {"Easy1", "A[AB]B[BC]C[CD]D[DE]E[EF]F[FG]G[GH]H[HI]I[IJ]J$"}, 711 {"Medium", "[XYZ]ABCDEFGHIJKLMNOPQRSTUVWXYZ$"}, 712 {"Hard", "[ -~]*ABCDEFGHIJKLMNOPQRSTUVWXYZ$"}, 713 {"Hard1", "ABCD|CDEF|EFGH|GHIJ|IJKL|KLMN|MNOP|OPQR|QRST|STUV|UVWX|WXYZ"}, 714} 715 716var benchSizes = []struct { 717 name string 718 n int 719}{ 720 {"16", 16}, 721 {"32", 32}, 722 {"1K", 1 << 10}, 723 {"32K", 32 << 10}, 724 {"1M", 1 << 20}, 725 {"32M", 32 << 20}, 726} 727 728func TestLongest(t *testing.T) { 729 re, err := Compile(`a(|b)`) 730 if err != nil { 731 t.Fatal(err) 732 } 733 if g, w := re.FindString("ab"), "a"; g != w { 734 t.Errorf("first match was %q, want %q", g, w) 735 } 736 re.Longest() 737 if g, w := re.FindString("ab"), "ab"; g != w { 738 t.Errorf("longest match was %q, want %q", g, w) 739 } 740} 741 742// TestProgramTooLongForBacktrack tests that a regex which is too long 743// for the backtracker still executes properly. 744func TestProgramTooLongForBacktrack(t *testing.T) { 745 longRegex := MustCompile(`(one|two|three|four|five|six|seven|eight|nine|ten|eleven|twelve|thirteen|fourteen|fifteen|sixteen|seventeen|eighteen|nineteen|twenty|twentyone|twentytwo|twentythree|twentyfour|twentyfive|twentysix|twentyseven|twentyeight|twentynine|thirty|thirtyone|thirtytwo|thirtythree|thirtyfour|thirtyfive|thirtysix|thirtyseven|thirtyeight|thirtynine|forty|fortyone|fortytwo|fortythree|fortyfour|fortyfive|fortysix|fortyseven|fortyeight|fortynine|fifty|fiftyone|fiftytwo|fiftythree|fiftyfour|fiftyfive|fiftysix|fiftyseven|fiftyeight|fiftynine|sixty|sixtyone|sixtytwo|sixtythree|sixtyfour|sixtyfive|sixtysix|sixtyseven|sixtyeight|sixtynine|seventy|seventyone|seventytwo|seventythree|seventyfour|seventyfive|seventysix|seventyseven|seventyeight|seventynine|eighty|eightyone|eightytwo|eightythree|eightyfour|eightyfive|eightysix|eightyseven|eightyeight|eightynine|ninety|ninetyone|ninetytwo|ninetythree|ninetyfour|ninetyfive|ninetysix|ninetyseven|ninetyeight|ninetynine|onehundred)`) 746 if !longRegex.MatchString("two") { 747 t.Errorf("longRegex.MatchString(\"two\") was false, want true") 748 } 749 if longRegex.MatchString("xxx") { 750 t.Errorf("longRegex.MatchString(\"xxx\") was true, want false") 751 } 752} 753