// Copyright 2011 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package syntax import ( "bytes" "fmt" "testing" "unicode" ) var parseTests = []struct { Regexp string Dump string }{ // Base cases {`a`, `lit{a}`}, {`a.`, `cat{lit{a}dot{}}`}, {`a.b`, `cat{lit{a}dot{}lit{b}}`}, {`ab`, `str{ab}`}, {`a.b.c`, `cat{lit{a}dot{}lit{b}dot{}lit{c}}`}, {`abc`, `str{abc}`}, {`a|^`, `alt{lit{a}bol{}}`}, {`a|b`, `cc{0x61-0x62}`}, {`(a)`, `cap{lit{a}}`}, {`(a)|b`, `alt{cap{lit{a}}lit{b}}`}, {`a*`, `star{lit{a}}`}, {`a+`, `plus{lit{a}}`}, {`a?`, `que{lit{a}}`}, {`a{2}`, `rep{2,2 lit{a}}`}, {`a{2,3}`, `rep{2,3 lit{a}}`}, {`a{2,}`, `rep{2,-1 lit{a}}`}, {`a*?`, `nstar{lit{a}}`}, {`a+?`, `nplus{lit{a}}`}, {`a??`, `nque{lit{a}}`}, {`a{2}?`, `nrep{2,2 lit{a}}`}, {`a{2,3}?`, `nrep{2,3 lit{a}}`}, {`a{2,}?`, `nrep{2,-1 lit{a}}`}, {``, `emp{}`}, {`|`, `emp{}`}, // alt{emp{}emp{}} but got factored {`|x|`, `alt{emp{}lit{x}emp{}}`}, {`.`, `dot{}`}, {`^`, `bol{}`}, {`$`, `eol{}`}, {`\|`, `lit{|}`}, {`\(`, `lit{(}`}, {`\)`, `lit{)}`}, {`\*`, `lit{*}`}, {`\+`, `lit{+}`}, {`\?`, `lit{?}`}, {`{`, `lit{{}`}, {`}`, `lit{}}`}, {`\.`, `lit{.}`}, {`\^`, `lit{^}`}, {`\$`, `lit{$}`}, {`\\`, `lit{\}`}, {`[ace]`, `cc{0x61 0x63 0x65}`}, {`[abc]`, `cc{0x61-0x63}`}, {`[a-z]`, `cc{0x61-0x7a}`}, {`[a]`, `lit{a}`}, {`\-`, `lit{-}`}, {`-`, `lit{-}`}, {`\_`, `lit{_}`}, {`abc`, `str{abc}`}, {`abc|def`, `alt{str{abc}str{def}}`}, {`abc|def|ghi`, `alt{str{abc}str{def}str{ghi}}`}, // Posix and Perl extensions {`[[:lower:]]`, `cc{0x61-0x7a}`}, {`[a-z]`, `cc{0x61-0x7a}`}, {`[^[:lower:]]`, `cc{0x0-0x60 0x7b-0x10ffff}`}, {`[[:^lower:]]`, `cc{0x0-0x60 0x7b-0x10ffff}`}, {`(?i)[[:lower:]]`, `cc{0x41-0x5a 0x61-0x7a 0x17f 0x212a}`}, {`(?i)[a-z]`, `cc{0x41-0x5a 0x61-0x7a 0x17f 0x212a}`}, {`(?i)[^[:lower:]]`, `cc{0x0-0x40 0x5b-0x60 0x7b-0x17e 0x180-0x2129 0x212b-0x10ffff}`}, {`(?i)[[:^lower:]]`, `cc{0x0-0x40 0x5b-0x60 0x7b-0x17e 0x180-0x2129 0x212b-0x10ffff}`}, {`\d`, `cc{0x30-0x39}`}, {`\D`, `cc{0x0-0x2f 0x3a-0x10ffff}`}, {`\s`, `cc{0x9-0xa 0xc-0xd 0x20}`}, {`\S`, `cc{0x0-0x8 0xb 0xe-0x1f 0x21-0x10ffff}`}, {`\w`, `cc{0x30-0x39 0x41-0x5a 0x5f 0x61-0x7a}`}, {`\W`, `cc{0x0-0x2f 0x3a-0x40 0x5b-0x5e 0x60 0x7b-0x10ffff}`}, {`(?i)\w`, `cc{0x30-0x39 0x41-0x5a 0x5f 0x61-0x7a 0x17f 0x212a}`}, {`(?i)\W`, `cc{0x0-0x2f 0x3a-0x40 0x5b-0x5e 0x60 0x7b-0x17e 0x180-0x2129 0x212b-0x10ffff}`}, {`[^\\]`, `cc{0x0-0x5b 0x5d-0x10ffff}`}, // { `\C`, `byte{}` }, // probably never // Unicode, negatives, and a double negative. {`\p{Braille}`, `cc{0x2800-0x28ff}`}, {`\P{Braille}`, `cc{0x0-0x27ff 0x2900-0x10ffff}`}, {`\p{^Braille}`, `cc{0x0-0x27ff 0x2900-0x10ffff}`}, {`\P{^Braille}`, `cc{0x2800-0x28ff}`}, {`\pZ`, `cc{0x20 0xa0 0x1680 0x180e 0x2000-0x200a 0x2028-0x2029 0x202f 0x205f 0x3000}`}, {`[\p{Braille}]`, `cc{0x2800-0x28ff}`}, {`[\P{Braille}]`, `cc{0x0-0x27ff 0x2900-0x10ffff}`}, {`[\p{^Braille}]`, `cc{0x0-0x27ff 0x2900-0x10ffff}`}, {`[\P{^Braille}]`, `cc{0x2800-0x28ff}`}, {`[\pZ]`, `cc{0x20 0xa0 0x1680 0x180e 0x2000-0x200a 0x2028-0x2029 0x202f 0x205f 0x3000}`}, {`\p{Lu}`, mkCharClass(unicode.IsUpper)}, {`[\p{Lu}]`, mkCharClass(unicode.IsUpper)}, {`(?i)[\p{Lu}]`, mkCharClass(isUpperFold)}, // Hex, octal. {`[\012-\234]\141`, `cat{cc{0xa-0x9c}lit{a}}`}, {`[\x{41}-\x7a]\x61`, `cat{cc{0x41-0x7a}lit{a}}`}, // More interesting regular expressions. {`a{,2}`, `str{a{,2}}`}, {`\.\^\$\\`, `str{.^$\}`}, {`[a-zABC]`, `cc{0x41-0x43 0x61-0x7a}`}, {`[^a]`, `cc{0x0-0x60 0x62-0x10ffff}`}, {`[α-ε☺]`, `cc{0x3b1-0x3b5 0x263a}`}, // utf-8 {`a*{`, `cat{star{lit{a}}lit{{}}`}, // Test precedences {`(?:ab)*`, `star{str{ab}}`}, {`(ab)*`, `star{cap{str{ab}}}`}, {`ab|cd`, `alt{str{ab}str{cd}}`}, {`a(b|c)d`, `cat{lit{a}cap{cc{0x62-0x63}}lit{d}}`}, // Test flattening. {`(?:a)`, `lit{a}`}, {`(?:ab)(?:cd)`, `str{abcd}`}, {`(?:a+b+)(?:c+d+)`, `cat{plus{lit{a}}plus{lit{b}}plus{lit{c}}plus{lit{d}}}`}, {`(?:a+|b+)|(?:c+|d+)`, `alt{plus{lit{a}}plus{lit{b}}plus{lit{c}}plus{lit{d}}}`}, {`(?:a|b)|(?:c|d)`, `cc{0x61-0x64}`}, {`a|.`, `dot{}`}, {`.|a`, `dot{}`}, {`(?:[abc]|A|Z|hello|world)`, `alt{cc{0x41 0x5a 0x61-0x63}str{hello}str{world}}`}, {`(?:[abc]|A|Z)`, `cc{0x41 0x5a 0x61-0x63}`}, // Test Perl quoted literals {`\Q+|*?{[\E`, `str{+|*?{[}`}, {`\Q+\E+`, `plus{lit{+}}`}, {`\Q\\E`, `lit{\}`}, {`\Q\\\E`, `str{\\}`}, // Test Perl \A and \z {`(?m)^`, `bol{}`}, {`(?m)$`, `eol{}`}, {`(?-m)^`, `bot{}`}, {`(?-m)$`, `eot{}`}, {`(?m)\A`, `bot{}`}, {`(?m)\z`, `eot{\z}`}, {`(?-m)\A`, `bot{}`}, {`(?-m)\z`, `eot{\z}`}, // Test named captures {`(?Pa)`, `cap{name:lit{a}}`}, // Case-folded literals {`[Aa]`, `litfold{A}`}, {`[\x{100}\x{101}]`, `litfold{Ā}`}, {`[Δδ]`, `litfold{Δ}`}, // Strings {`abcde`, `str{abcde}`}, {`[Aa][Bb]cd`, `cat{strfold{AB}str{cd}}`}, // Factoring. {`abc|abd|aef|bcx|bcy`, `alt{cat{lit{a}alt{cat{lit{b}cc{0x63-0x64}}str{ef}}}cat{str{bc}cc{0x78-0x79}}}`}, {`ax+y|ax+z|ay+w`, `cat{lit{a}alt{cat{plus{lit{x}}cc{0x79-0x7a}}cat{plus{lit{y}}lit{w}}}}`}, } const testFlags = MatchNL | PerlX | UnicodeGroups // Test Parse -> Dump. func TestParseDump(t *testing.T) { for _, tt := range parseTests { re, err := Parse(tt.Regexp, testFlags) if err != nil { t.Errorf("Parse(%#q): %v", tt.Regexp, err) continue } d := dump(re) if d != tt.Dump { t.Errorf("Parse(%#q).Dump() = %#q want %#q", tt.Regexp, d, tt.Dump) } } } // dump prints a string representation of the regexp showing // the structure explicitly. func dump(re *Regexp) string { var b bytes.Buffer dumpRegexp(&b, re) return b.String() } var opNames = []string{ OpNoMatch: "no", OpEmptyMatch: "emp", OpLiteral: "lit", OpCharClass: "cc", OpAnyCharNotNL: "dnl", OpAnyChar: "dot", OpBeginLine: "bol", OpEndLine: "eol", OpBeginText: "bot", OpEndText: "eot", OpWordBoundary: "wb", OpNoWordBoundary: "nwb", OpCapture: "cap", OpStar: "star", OpPlus: "plus", OpQuest: "que", OpRepeat: "rep", OpConcat: "cat", OpAlternate: "alt", } // dumpRegexp writes an encoding of the syntax tree for the regexp re to b. // It is used during testing to distinguish between parses that might print // the same using re's String method. func dumpRegexp(b *bytes.Buffer, re *Regexp) { if int(re.Op) >= len(opNames) || opNames[re.Op] == "" { fmt.Fprintf(b, "op%d", re.Op) } else { switch re.Op { default: b.WriteString(opNames[re.Op]) case OpStar, OpPlus, OpQuest, OpRepeat: if re.Flags&NonGreedy != 0 { b.WriteByte('n') } b.WriteString(opNames[re.Op]) case OpLiteral: if len(re.Rune) > 1 { b.WriteString("str") } else { b.WriteString("lit") } if re.Flags&FoldCase != 0 { for _, r := range re.Rune { if unicode.SimpleFold(r) != r { b.WriteString("fold") break } } } } } b.WriteByte('{') switch re.Op { case OpEndText: if re.Flags&WasDollar == 0 { b.WriteString(`\z`) } case OpLiteral: for _, r := range re.Rune { b.WriteRune(r) } case OpConcat, OpAlternate: for _, sub := range re.Sub { dumpRegexp(b, sub) } case OpStar, OpPlus, OpQuest: dumpRegexp(b, re.Sub[0]) case OpRepeat: fmt.Fprintf(b, "%d,%d ", re.Min, re.Max) dumpRegexp(b, re.Sub[0]) case OpCapture: if re.Name != "" { b.WriteString(re.Name) b.WriteByte(':') } dumpRegexp(b, re.Sub[0]) case OpCharClass: sep := "" for i := 0; i < len(re.Rune); i += 2 { b.WriteString(sep) sep = " " lo, hi := re.Rune[i], re.Rune[i+1] if lo == hi { fmt.Fprintf(b, "%#x", lo) } else { fmt.Fprintf(b, "%#x-%#x", lo, hi) } } } b.WriteByte('}') } func mkCharClass(f func(int) bool) string { re := &Regexp{Op: OpCharClass} lo := -1 for i := 0; i <= unicode.MaxRune; i++ { if f(i) { if lo < 0 { lo = i } } else { if lo >= 0 { re.Rune = append(re.Rune, lo, i-1) lo = -1 } } } if lo >= 0 { re.Rune = append(re.Rune, lo, unicode.MaxRune) } return dump(re) } func isUpperFold(rune int) bool { if unicode.IsUpper(rune) { return true } c := unicode.SimpleFold(rune) for c != rune { if unicode.IsUpper(c) { return true } c = unicode.SimpleFold(c) } return false } func TestFoldConstants(t *testing.T) { last := -1 for i := 0; i <= unicode.MaxRune; i++ { if unicode.SimpleFold(i) == i { continue } if last == -1 && minFold != i { t.Errorf("minFold=%#U should be %#U", minFold, i) } last = i } if maxFold != last { t.Errorf("maxFold=%#U should be %#U", maxFold, last) } } func TestAppendRangeCollapse(t *testing.T) { // AppendRange should collapse each of the new ranges // into the earlier ones (it looks back two ranges), so that // the slice never grows very large. // Note that we are not calling cleanClass. var r []int for i := 'A'; i <= 'Z'; i++ { r = appendRange(r, i, i) r = appendRange(r, i+'a'-'A', i+'a'-'A') } if string(r) != "AZaz" { t.Errorf("appendRange interlaced A-Z a-z = %s, want AZaz", string(r)) } }