package parser import ( "bytes" "errors" "fmt" "regexp" "strconv" "strings" "unicode" "unicode/utf8" "github.com/robertkrimen/otto/file" "github.com/robertkrimen/otto/token" ) type _chr struct { value rune width int } var matchIdentifier = regexp.MustCompile(`^[$_\p{L}][$_\p{L}\d}]*$`) func isDecimalDigit(chr rune) bool { return '0' <= chr && chr <= '9' } func digitValue(chr rune) int { switch { case '0' <= chr && chr <= '9': return int(chr - '0') case 'a' <= chr && chr <= 'f': return int(chr - 'a' + 10) case 'A' <= chr && chr <= 'F': return int(chr - 'A' + 10) } return 16 // Larger than any legal digit value } func isDigit(chr rune, base int) bool { return digitValue(chr) < base } func isIdentifierStart(chr rune) bool { return chr == '$' || chr == '_' || chr == '\\' || 'a' <= chr && chr <= 'z' || 'A' <= chr && chr <= 'Z' || chr >= utf8.RuneSelf && unicode.IsLetter(chr) } func isIdentifierPart(chr rune) bool { return chr == '$' || chr == '_' || chr == '\\' || 'a' <= chr && chr <= 'z' || 'A' <= chr && chr <= 'Z' || '0' <= chr && chr <= '9' || chr >= utf8.RuneSelf && (unicode.IsLetter(chr) || unicode.IsDigit(chr)) } func (self *_parser) scanIdentifier() (string, error) { offset := self.chrOffset parse := false for isIdentifierPart(self.chr) { if self.chr == '\\' { distance := self.chrOffset - offset self.read() if self.chr != 'u' { return "", fmt.Errorf("Invalid identifier escape character: %c (%s)", self.chr, string(self.chr)) } parse = true var value rune for j := 0; j < 4; j++ { self.read() decimal, ok := hex2decimal(byte(self.chr)) if !ok { return "", fmt.Errorf("Invalid identifier escape character: %c (%s)", self.chr, string(self.chr)) } value = value<<4 | decimal } if value == '\\' { return "", fmt.Errorf("Invalid identifier escape value: %c (%s)", value, string(value)) } else if distance == 0 { if !isIdentifierStart(value) { return "", fmt.Errorf("Invalid identifier escape value: %c (%s)", value, string(value)) } } else if distance > 0 { if !isIdentifierPart(value) { return "", fmt.Errorf("Invalid identifier escape value: %c (%s)", value, string(value)) } } } self.read() } literal := string(self.str[offset:self.chrOffset]) if parse { return parseStringLiteral(literal) } return literal, nil } // 7.2 func isLineWhiteSpace(chr rune) bool { switch chr { case '\u0009', '\u000b', '\u000c', '\u0020', '\u00a0', '\ufeff': return true case '\u000a', '\u000d', '\u2028', '\u2029': return false case '\u0085': return false } return unicode.IsSpace(chr) } // 7.3 func isLineTerminator(chr rune) bool { switch chr { case '\u000a', '\u000d', '\u2028', '\u2029': return true } return false } func (self *_parser) scan() (tkn token.Token, literal string, idx file.Idx) { self.implicitSemicolon = false for { self.skipWhiteSpace() idx = self.idxOf(self.chrOffset) insertSemicolon := false switch chr := self.chr; { case isIdentifierStart(chr): var err error literal, err = self.scanIdentifier() if err != nil { tkn = token.ILLEGAL break } if len(literal) > 1 { // Keywords are longer than 1 character, avoid lookup otherwise var strict bool tkn, strict = token.IsKeyword(literal) switch tkn { case 0: // Not a keyword if literal == "true" || literal == "false" { self.insertSemicolon = true tkn = token.BOOLEAN return } else if literal == "null" { self.insertSemicolon = true tkn = token.NULL return } case token.KEYWORD: tkn = token.KEYWORD if strict { // TODO If strict and in strict mode, then this is not a break break } return case token.THIS, token.BREAK, token.THROW, // A newline after a throw is not allowed, but we need to detect it token.RETURN, token.CONTINUE, token.DEBUGGER: self.insertSemicolon = true return default: return } } self.insertSemicolon = true tkn = token.IDENTIFIER return case '0' <= chr && chr <= '9': self.insertSemicolon = true tkn, literal = self.scanNumericLiteral(false) return default: self.read() switch chr { case -1: if self.insertSemicolon { self.insertSemicolon = false self.implicitSemicolon = true } tkn = token.EOF case '\r', '\n', '\u2028', '\u2029': self.insertSemicolon = false self.implicitSemicolon = true continue case ':': tkn = token.COLON case '.': if digitValue(self.chr) < 10 { insertSemicolon = true tkn, literal = self.scanNumericLiteral(true) } else { tkn = token.PERIOD } case ',': tkn = token.COMMA case ';': tkn = token.SEMICOLON case '(': tkn = token.LEFT_PARENTHESIS case ')': tkn = token.RIGHT_PARENTHESIS insertSemicolon = true case '[': tkn = token.LEFT_BRACKET case ']': tkn = token.RIGHT_BRACKET insertSemicolon = true case '{': tkn = token.LEFT_BRACE case '}': tkn = token.RIGHT_BRACE insertSemicolon = true case '+': tkn = self.switch3(token.PLUS, token.ADD_ASSIGN, '+', token.INCREMENT) if tkn == token.INCREMENT { insertSemicolon = true } case '-': tkn = self.switch3(token.MINUS, token.SUBTRACT_ASSIGN, '-', token.DECREMENT) if tkn == token.DECREMENT { insertSemicolon = true } case '*': tkn = self.switch2(token.MULTIPLY, token.MULTIPLY_ASSIGN) case '/': if self.chr == '/' { self.skipSingleLineComment() continue } else if self.chr == '*' { self.skipMultiLineComment() continue } else { // Could be division, could be RegExp literal tkn = self.switch2(token.SLASH, token.QUOTIENT_ASSIGN) insertSemicolon = true } case '%': tkn = self.switch2(token.REMAINDER, token.REMAINDER_ASSIGN) case '^': tkn = self.switch2(token.EXCLUSIVE_OR, token.EXCLUSIVE_OR_ASSIGN) case '<': tkn = self.switch4(token.LESS, token.LESS_OR_EQUAL, '<', token.SHIFT_LEFT, token.SHIFT_LEFT_ASSIGN) case '>': tkn = self.switch6(token.GREATER, token.GREATER_OR_EQUAL, '>', token.SHIFT_RIGHT, token.SHIFT_RIGHT_ASSIGN, '>', token.UNSIGNED_SHIFT_RIGHT, token.UNSIGNED_SHIFT_RIGHT_ASSIGN) case '=': tkn = self.switch2(token.ASSIGN, token.EQUAL) if tkn == token.EQUAL && self.chr == '=' { self.read() tkn = token.STRICT_EQUAL } case '!': tkn = self.switch2(token.NOT, token.NOT_EQUAL) if tkn == token.NOT_EQUAL && self.chr == '=' { self.read() tkn = token.STRICT_NOT_EQUAL } case '&': if self.chr == '^' { self.read() tkn = self.switch2(token.AND_NOT, token.AND_NOT_ASSIGN) } else { tkn = self.switch3(token.AND, token.AND_ASSIGN, '&', token.LOGICAL_AND) } case '|': tkn = self.switch3(token.OR, token.OR_ASSIGN, '|', token.LOGICAL_OR) case '~': tkn = token.BITWISE_NOT case '?': tkn = token.QUESTION_MARK case '"', '\'': insertSemicolon = true tkn = token.STRING var err error literal, err = self.scanString(self.chrOffset - 1) if err != nil { tkn = token.ILLEGAL } default: self.errorUnexpected(idx, chr) tkn = token.ILLEGAL } } self.insertSemicolon = insertSemicolon return } } func (self *_parser) switch2(tkn0, tkn1 token.Token) token.Token { if self.chr == '=' { self.read() return tkn1 } return tkn0 } func (self *_parser) switch3(tkn0, tkn1 token.Token, chr2 rune, tkn2 token.Token) token.Token { if self.chr == '=' { self.read() return tkn1 } if self.chr == chr2 { self.read() return tkn2 } return tkn0 } func (self *_parser) switch4(tkn0, tkn1 token.Token, chr2 rune, tkn2, tkn3 token.Token) token.Token { if self.chr == '=' { self.read() return tkn1 } if self.chr == chr2 { self.read() if self.chr == '=' { self.read() return tkn3 } return tkn2 } return tkn0 } func (self *_parser) switch6(tkn0, tkn1 token.Token, chr2 rune, tkn2, tkn3 token.Token, chr3 rune, tkn4, tkn5 token.Token) token.Token { if self.chr == '=' { self.read() return tkn1 } if self.chr == chr2 { self.read() if self.chr == '=' { self.read() return tkn3 } if self.chr == chr3 { self.read() if self.chr == '=' { self.read() return tkn5 } return tkn4 } return tkn2 } return tkn0 } func (self *_parser) chrAt(index int) _chr { value, width := utf8.DecodeRuneInString(self.str[index:]) return _chr{ value: value, width: width, } } func (self *_parser) _peek() rune { if self.offset+1 < self.length { return rune(self.str[self.offset+1]) } return -1 } func (self *_parser) read() { if self.offset < self.length { self.chrOffset = self.offset chr, width := rune(self.str[self.offset]), 1 if chr >= utf8.RuneSelf { // !ASCII chr, width = utf8.DecodeRuneInString(self.str[self.offset:]) if chr == utf8.RuneError && width == 1 { self.error(self.chrOffset, "Invalid UTF-8 character") } } self.offset += width self.chr = chr } else { self.chrOffset = self.length self.chr = -1 // EOF } } // This is here since the functions are so similar func (self *_RegExp_parser) read() { if self.offset < self.length { self.chrOffset = self.offset chr, width := rune(self.str[self.offset]), 1 if chr >= utf8.RuneSelf { // !ASCII chr, width = utf8.DecodeRuneInString(self.str[self.offset:]) if chr == utf8.RuneError && width == 1 { self.error(self.chrOffset, "Invalid UTF-8 character") } } self.offset += width self.chr = chr } else { self.chrOffset = self.length self.chr = -1 // EOF } } func (self *_parser) skipSingleLineComment() { for self.chr != -1 { self.read() if isLineTerminator(self.chr) { return } } } func (self *_parser) skipMultiLineComment() { self.read() for self.chr >= 0 { chr := self.chr self.read() if chr == '*' && self.chr == '/' { self.read() return } } self.errorUnexpected(0, self.chr) } func (self *_parser) skipWhiteSpace() { for { switch self.chr { case ' ', '\t', '\f', '\v', '\u00a0', '\ufeff': self.read() continue case '\r': if self._peek() == '\n' { self.read() } fallthrough case '\u2028', '\u2029', '\n': if self.insertSemicolon { return } self.read() continue } if self.chr >= utf8.RuneSelf { if unicode.IsSpace(self.chr) { self.read() continue } } break } } func (self *_parser) skipLineWhiteSpace() { for isLineWhiteSpace(self.chr) { self.read() } } func (self *_parser) scanMantissa(base int) { for digitValue(self.chr) < base { self.read() } } func (self *_parser) scanEscape(quote rune) { var length, base uint32 switch self.chr { //case '0', '1', '2', '3', '4', '5', '6', '7': // Octal: // length, base, limit = 3, 8, 255 case 'a', 'b', 'f', 'n', 'r', 't', 'v', '\\', '"', '\'', '0': self.read() return case '\r', '\n', '\u2028', '\u2029': self.scanNewline() return case 'x': self.read() length, base = 2, 16 case 'u': self.read() length, base = 4, 16 default: self.read() // Always make progress return } var value uint32 for ; length > 0 && self.chr != quote && self.chr >= 0; length-- { digit := uint32(digitValue(self.chr)) if digit >= base { break } value = value*base + digit self.read() } } func (self *_parser) scanString(offset int) (string, error) { // " ' / quote := rune(self.str[offset]) for self.chr != quote { chr := self.chr if chr == '\n' || chr == '\r' || chr == '\u2028' || chr == '\u2029' || chr < 0 { goto newline } self.read() if chr == '\\' { if quote == '/' { if self.chr == '\n' || self.chr == '\r' || self.chr == '\u2028' || self.chr == '\u2029' || self.chr < 0 { goto newline } self.read() } else { self.scanEscape(quote) } } else if chr == '[' && quote == '/' { // Allow a slash (/) in a bracket character class ([...]) // TODO Fix this, this is hacky... quote = -1 } else if chr == ']' && quote == -1 { quote = '/' } } // " ' / self.read() return string(self.str[offset:self.chrOffset]), nil newline: self.scanNewline() err := "String not terminated" if quote == '/' { err = "Invalid regular expression: missing /" self.error(self.idxOf(offset), err) } return "", errors.New(err) } func (self *_parser) scanNewline() { if self.chr == '\r' { self.read() if self.chr != '\n' { return } } self.read() } func hex2decimal(chr byte) (value rune, ok bool) { { chr := rune(chr) switch { case '0' <= chr && chr <= '9': return chr - '0', true case 'a' <= chr && chr <= 'f': return chr - 'a' + 10, true case 'A' <= chr && chr <= 'F': return chr - 'A' + 10, true } return } } func parseNumberLiteral(literal string) (value interface{}, err error) { // TODO Is Uint okay? What about -MAX_UINT value, err = strconv.ParseInt(literal, 0, 64) if err == nil { return } parseIntErr := err // Save this first error, just in case value, err = strconv.ParseFloat(literal, 64) if err == nil { return } else if err.(*strconv.NumError).Err == strconv.ErrRange { // Infinity, etc. return value, nil } err = parseIntErr if err.(*strconv.NumError).Err == strconv.ErrRange { if len(literal) > 2 && literal[0] == '0' && (literal[1] == 'X' || literal[1] == 'x') { // Could just be a very large number (e.g. 0x8000000000000000) var value float64 literal = literal[2:] for _, chr := range literal { digit := digitValue(chr) if digit >= 16 { goto error } value = value*16 + float64(digit) } return value, nil } } error: return nil, errors.New("Illegal numeric literal") } func parseStringLiteral(literal string) (string, error) { // Best case scenario... if literal == "" { return "", nil } // Slightly less-best case scenario... if !strings.ContainsRune(literal, '\\') { return literal, nil } str := literal buffer := bytes.NewBuffer(make([]byte, 0, 3*len(literal)/2)) for len(str) > 0 { switch chr := str[0]; { // We do not explicitly handle the case of the quote // value, which can be: " ' / // This assumes we're already passed a partially well-formed literal case chr >= utf8.RuneSelf: chr, size := utf8.DecodeRuneInString(str) buffer.WriteRune(chr) str = str[size:] continue case chr != '\\': buffer.WriteByte(chr) str = str[1:] continue } if len(str) <= 1 { panic("len(str) <= 1") } chr := str[1] var value rune if chr >= utf8.RuneSelf { str = str[1:] var size int value, size = utf8.DecodeRuneInString(str) str = str[size:] // \ + } else { str = str[2:] // \ switch chr { case 'b': value = '\b' case 'f': value = '\f' case 'n': value = '\n' case 'r': value = '\r' case 't': value = '\t' case 'v': value = '\v' case 'x', 'u': size := 0 switch chr { case 'x': size = 2 case 'u': size = 4 } if len(str) < size { return "", fmt.Errorf("invalid escape: \\%s: len(%q) != %d", string(chr), str, size) } for j := 0; j < size; j++ { decimal, ok := hex2decimal(str[j]) if !ok { return "", fmt.Errorf("invalid escape: \\%s: %q", string(chr), str[:size]) } value = value<<4 | decimal } str = str[size:] if chr == 'x' { break } if value > utf8.MaxRune { panic("value > utf8.MaxRune") } case '0': if len(str) == 0 || '0' > str[0] || str[0] > '7' { value = 0 break } fallthrough case '1', '2', '3', '4', '5', '6', '7': // TODO strict value = rune(chr) - '0' j := 0 for ; j < 2; j++ { if len(str) < j+1 { break } chr := str[j] if '0' > chr || chr > '7' { break } decimal := rune(str[j]) - '0' value = (value << 3) | decimal } str = str[j:] case '\\': value = '\\' case '\'', '"': value = rune(chr) case '\r': if len(str) > 0 { if str[0] == '\n' { str = str[1:] } } fallthrough case '\n': continue default: value = rune(chr) } } buffer.WriteRune(value) } return buffer.String(), nil } func (self *_parser) scanNumericLiteral(decimalPoint bool) (token.Token, string) { offset := self.chrOffset tkn := token.NUMBER if decimalPoint { offset-- self.scanMantissa(10) goto exponent } if self.chr == '0' { offset := self.chrOffset self.read() if self.chr == 'x' || self.chr == 'X' { // Hexadecimal self.read() if isDigit(self.chr, 16) { self.read() } else { return token.ILLEGAL, self.str[offset:self.chrOffset] } self.scanMantissa(16) if self.chrOffset-offset <= 2 { // Only "0x" or "0X" self.error(0, "Illegal hexadecimal number") } goto hexadecimal } else if self.chr == '.' { // Float goto float } else { // Octal, Float if self.chr == 'e' || self.chr == 'E' { goto exponent } self.scanMantissa(8) if self.chr == '8' || self.chr == '9' { return token.ILLEGAL, self.str[offset:self.chrOffset] } goto octal } } self.scanMantissa(10) float: if self.chr == '.' { self.read() self.scanMantissa(10) } exponent: if self.chr == 'e' || self.chr == 'E' { self.read() if self.chr == '-' || self.chr == '+' { self.read() } if isDecimalDigit(self.chr) { self.read() self.scanMantissa(10) } else { return token.ILLEGAL, self.str[offset:self.chrOffset] } } hexadecimal: octal: if isIdentifierStart(self.chr) || isDecimalDigit(self.chr) { return token.ILLEGAL, self.str[offset:self.chrOffset] } return tkn, self.str[offset:self.chrOffset] }