pjs/js/js2/parser.cpp

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25 KiB
C++

// -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*-
//
// The contents of this file are subject to the Netscape Public
// License Version 1.1 (the "License"); you may not use this file
// except in compliance with the License. You may obtain a copy of
// the License at http://www.mozilla.org/NPL/
//
// Software distributed under the License is distributed on an "AS
// IS" basis, WITHOUT WARRANTY OF ANY KIND, either express oqr
// implied. See the License for the specific language governing
// rights and limitations under the License.
//
// The Original Code is the JavaScript 2 Prototype.
//
// The Initial Developer of the Original Code is Netscape
// Communications Corporation. Portions created by Netscape are
// Copyright (C) 1998 Netscape Communications Corporation. All
// Rights Reserved.
#include "numerics.h"
#include "parser.h"
#include "world.h"
namespace JS = JavaScript;
//
// Reader
//
// Create a Reader reading characters from begin up to but not including end.
JS::Reader::Reader(const char16 *begin, const char16 *end):
begin(begin), p(begin), end(end), lineStart(begin), nGetsPastEnd(0), lineNum(1), lineFileOffset(0)
{
ASSERT(begin <= end);
#ifdef DEBUG
recordString = 0;
#endif
}
// Unread the last n characters. unget cannot be called to back up past the position
// of the last call to beginLine().
void JS::Reader::unget(uint32 n)
{
if (nGetsPastEnd) {
if (nGetsPastEnd >= n) {
nGetsPastEnd -= n;
return;
}
n -= nGetsPastEnd;
nGetsPastEnd = 0;
}
ASSERT(p >= begin + n);
p -= n;
}
// Return the characters read in from position begin inclusive to position end
// exclusive relative to the current line. begin <= end <= charPos() is required.
JS::String JS::Reader::extract(uint32 begin, uint32 end) const
{
ASSERT(begin <= end && end + nGetsPastEnd <= charPos());
return String(lineStart + begin, lineStart + end);
}
// Begin accumulating characters into the recordString, whose initial value is
// ignored and cleared. Each character passed to recordChar() is added to the end
// of the recordString. Recording ends when endRecord() or beginLine() is called.
// Recording is significantly optimized when the characters passed to readChar()
// are the same characters as read by get(). In this case the record String does
// not get allocated until endRecord() is called or a discrepancy appears between
// get() and recordChar().
void JS::Reader::beginRecording(String &recordString)
{
Reader::recordString = &recordString;
recordBase = p;
recordPos = p;
}
// Append ch to the recordString.
void JS::Reader::recordChar(char16 ch)
{
ASSERT(recordString);
if (recordPos) {
if (recordPos != end && *recordPos == ch) {
recordPos++;
return;
} else {
recordString->assign(recordBase, recordPos);
recordPos = 0;
}
}
*recordString += ch;
}
// Finish recording characters into the recordString that was last passed to beginRecording().
// Return that recordString.
JS::String &JS::Reader::endRecording()
{
String *rs = recordString;
ASSERT(rs);
if (recordPos)
rs->assign(recordBase, recordPos);
recordString = 0;
return *rs;
}
// Refill the source buffer after running off the end. Get and return
// the next character.
// The default implementation just returns char16eof.
JS::char16orEOF JS::Reader::underflow()
{
++nGetsPastEnd;
return char16eof;
}
// Perform a peek when begin == end.
JS::char16orEOF JS::Reader::peekUnderflow()
{
char16orEOF ch = underflow();
unget();
return ch;
}
// Create a StringReader reading characters from s.
// source describes the origin of string s and may be used for error messages.
JS::StringReader::StringReader(const String &s, const String &source):
str(s), source(source)
{
const char16 *begin = str.data();
setBuffer(begin, begin, begin + str.size());
}
// Set the beginning of the current line. unget cannot be subsequently called past this point.
// This can only be called if the previous character was LF (u000A), CR (u000D), LS (u2028), or PS (u2029).
// Moreover, in these cases this method must be called before reading any more characters.
void JS::StringReader::beginLine()
{
++lineNum;
lineStart = p;
lineFileOffset = static_cast<uint32>(p - begin);
}
JS::String JS::StringReader::sourceFile() const
{
return source;
}
//
// Lexer
//
const char *const JS::Token::kindNames[] = {
// Special
"[End]", // Token::End
"[Identifier]", // Token::Id
"[Numeral]", // Token::Num
"[String]", // Token::Str
"[Unit]", // Token::Unit
"[RegExp]", // Token::RegExp
// Punctuators
"(", // Token::OpenParenthesis
")", // Token::CloseParenthesis
"[", // Token::OpenBracket
"]", // Token::CloseBracket
"{", // Token::OpenBrace
"}", // Token::CloseBrace
",", // Token::Comma
";", // Token::Semicolon
".", // Token::Dot
"..", // Token::DoubleDot
"...", // Token::TripleDot
"->", // Token::Arrow
":", // Token::Colon
"::", // Token::DoubleColon
"#", // Token::Pound
"@", // Token::At
"++", // Token::Increment
"--", // Token::Decrement
"~", // Token::Complement
"!", // Token::Not
"*", // Token::Times
"/", // Token::Divide
"%", // Token::Modulo
"+", // Token::Plus
"-", // Token::Minus
"<<", // Token::LeftShift
">>", // Token::RightShift
">>>", // Token::LogicalRightShift
"&&", // Token::LogicalAnd
"^^", // Token::LogicalXor
"||", // Token::LogicalOr
"&", // Token::And
"^", // Token::Xor
"|", // Token::Or
"=", // Token::Assignment
"*=", // Token::TimesEquals
"/=", // Token::DivideEquals
"%=", // Token::ModuloEquals
"+=", // Token::PlusEquals
"-=", // Token::MinusEquals
"<<=", // Token::LeftShiftEquals
">>=", // Token::RightShiftEquals
">>>=", // Token::LogicalRightShiftEquals
"&&=", // Token::LogicalAndEquals
"^^=", // Token::LogicalXorEquals
"||=", // Token::LogicalOrEquals
"&=", // Token::AndEquals
"^=", // Token::XorEquals
"|=", // Token::OrEquals
"==", // Token::Equal
"!=", // Token::NotEqual
"<", // Token::LessThan
"<=", // Token::LessThanOrEqual
">", // Token::GreaterThan
">=", // Token::GreaterThanOrEqual
"===", // Token::Identical
"!==", // Token::NotIdentical
"?", // Token::Question
// Reserved words
"abstract", // Token::Abstract
"break", // Token::Break
"case", // Token::Case
"catch", // Token::Catch
"class", // Token::Class
"const", // Token::Const
"continue", // Token::Continue
"debugger", // Token::Debugger
"default", // Token::Default
"delete", // Token::Delete
"do", // Token::Do
"else", // Token::Else
"enum", // Token::Enum
"eval", // Token::Eval
"export", // Token::Export
"extends", // Token::Extends
"false", // Token::False
"final", // Token::Final
"finally", // Token::Finally
"for", // Token::For
"function", // Token::Function
"goto", // Token::Goto
"if", // Token::If
"implements", // Token::Implements
"import", // Token::Import
"in", // Token::In
"instanceof", // Token::Instanceof
"native", // Token::Native
"new", // Token::New
"null", // Token::Null
"package", // Token::Package
"private", // Token::Private
"protected", // Token::Protected
"public", // Token::Public
"return", // Token::Return
"static", // Token::Static
"super", // Token::Super
"switch", // Token::Switch
"synchronized", // Token::Synchronized
"this", // Token::This
"throw", // Token::Throw
"throws", // Token::Throws
"transient", // Token::Transient
"true", // Token::True
"try", // Token::Try
"typeof", // Token::Typeof
"var", // Token::Var
"volatile", // Token::Volatile
"while", // Token::While
"with", // Token::With
// Non-reserved words
"box", // Token::Box
"constructor", // Token::Constructor
"field", // Token::Field
"get", // Token::Get
"language", // Token::Language
"local", // Token::Local
"method", // Token::Method
"override", // Token::Override
"set", // Token::Set
"version" // Token::Version
};
// Initialize the keywords in the given world.
void JS::Token::initKeywords(World &world)
{
const char *const*keywordName = kindNames + KeywordsBegin;
for (Kind kind = KeywordsBegin; kind != KeywordsEnd; kind = Kind(kind+1))
world.identifiers[widenCString(*keywordName++)].tokenKind = kind;
}
// Append a description of the token to dst.
void JS::Token::print(String &dst, bool debug) const
{
switch (kind) {
case Id:
if (debug)
dst += "[Id]";
dst += *identifier;
break;
case Num:
if (debug) {
dst += "[Num ";
dst += value;
dst += ']';
}
dst += chars;
break;
case Unit:
if (debug)
dst += "[Unit]";
case Str:
dst += '"';
dst += chars;
dst += '"';
break;
case RegExp:
dst += '/';
dst += *identifier;
dst += '/';
dst += chars;
break;
default:
dst += kind;
}
}
// Create a new Lexer using the provided Reader and interning identifiers, keywords, and regular
// expressions in the designated world.
JS::Lexer::Lexer(Reader &reader, World &world): reader(reader), world(world)
{
nextToken = tokens;
nTokensFwd = 0;
#ifdef DEBUG
nTokensBack = 0;
#endif
lexingUnit = false;
}
// Get and return the next token. The token remains valid until the next call to this Lexer.
// If the Reader reached the end of file, return a Token whose Kind is End.
// The caller may alter the value of this Token (in particular, take control over the
// auto_ptr's data), but if it does so, the caller is not allowed to unget this Token.
//
// If preferRegExp is true, a / will be preferentially interpreted as starting a regular
// expression; otherwise, a / will be preferentially interpreted as division or /=.
JS::Token &JS::Lexer::get(bool preferRegExp)
{
Token &t = const_cast<Token &>(peek(preferRegExp));
if (++nextToken == tokens + tokenBufferSize)
nextToken = tokens;
--nTokensFwd;
DEBUG_ONLY(++nTokensBack);
return t;
}
// Return the next token without consuming it.
//
// If preferRegExp is true, a / will be preferentially interpreted as starting a regular
// expression; otherwise, a / will be preferentially interpreted as division or /=.
// A subsequent call to peek or get will return the same token; that call must be presented
// with the same value for preferRegExp.
const JS::Token &JS::Lexer::peek(bool preferRegExp)
{
// Use an already looked-up token if there is one.
if (nTokensFwd) {
ASSERT(savedPreferRegExp[nextToken - tokens] == preferRegExp);
} else {
lexToken(preferRegExp);
nTokensFwd = 1;
#ifdef DEBUG
savedPreferRegExp[nextToken - tokens] = preferRegExp;
if (nTokensBack == tokenBufferSize)
nTokensBack = tokenBufferSize-1;
#endif
}
return *nextToken;
}
// Unread the last token. This call may be called to unread at most tokenBufferSize tokens
// at a time (where a peek also counts as temporarily reading and unreading one token).
// When a token that has been unread is peeked or read again, the same value must be passed
// in preferRegExp as for the first time that token was read or peeked.
void JS::Lexer::unget()
{
ASSERT(nTokensBack--);
nTokensFwd++;
if (nextToken == tokens)
nextToken = tokens + tokenBufferSize;
--nextToken;
}
// Report a syntax error at the backUp-th last character read by the Reader.
// In other words, if backUp is 0, the error is at the next character to be read by the Reader;
// if backUp is 1, the error is at the last character read by the Reader, and so forth.
void JS::Lexer::syntaxError(const char *message, uint backUp)
{
reader.unget(backUp);
uint32 charPos = reader.charPos();
char16orEOF ch;
do {
ch = reader.get();
} while (ch != char16eof && !isLineBreak(char16orEOFToChar16(ch)));
reader.unget();
SourcePosition position;
position.lineFileOffset = reader.lineFileOffset;
position.lineNum = reader.lineNum;
position.charPos = charPos;
Exception e(Exception::SyntaxError, widenCString(message), reader.sourceFile(), position,
reader.extract(0, reader.charPos()));
throw e;
}
// Get the next character from the reader, skipping any Unicode format-control (Cf) characters.
inline JS::char16orEOF JS::Lexer::getChar()
{
char16orEOF ch = reader.get();
if (static_cast<uint32>(ch) >= firstFormatChar)
ch = internalGetChar(ch);
return ch;
}
// Helper for getChar()
JS::char16orEOF JS::Lexer::internalGetChar(char16orEOF ch)
{
while (isFormat(char16orEOFToChar16(ch)))
ch = reader.get();
return ch;
}
// Peek the next character from the reader, skipping any Unicode format-control (Cf) characters,
// which are read and discarded.
inline JS::char16orEOF JS::Lexer::peekChar()
{
char16orEOF ch = reader.peek();
if (static_cast<uint32>(ch) >= firstFormatChar)
ch = internalPeekChar(ch);
return ch;
}
// Helper for peekChar()
JS::char16orEOF JS::Lexer::internalPeekChar(char16orEOF ch)
{
while (isFormat(char16orEOFToChar16(ch))) {
reader.get();
ch = reader.peek();
}
return ch;
}
// Peek the next character from the reader, skipping any Unicode format-control (Cf) characters,
// which are read and discarded. If the peeked character matches ch, read that character and return true;
// otherwise return false.
bool JS::Lexer::testChar(char16 ch)
{
char16orEOF ch2 = peekChar();
if (ch == ch2) {
reader.get();
return true;
}
return false;
}
// A backslash has been read. Read the rest of the escape code.
// Return the interpreted escaped character. Throw an exception if the escape is not valid.
// If unicodeOnly is true, allow only \uxxxx escapes.
char16 JS::Lexer::lexEscape(bool unicodeOnly)
{
char16orEOF ch = getChar();
int nDigits;
if (!unicodeOnly || ch == 'u')
switch (ch) {
case '0':
// Make sure that the next character isn't a digit.
ch = peekChar();
if (!isASCIIDecimalDigit(char16orEOFToChar16(ch)))
return 0x00;
getChar(); // Point to the next character in the error message
case 'b':
return 0x08;
case 'f':
return 0x0C;
case 'n':
return 0x0A;
case 'r':
return 0x0D;
case 't':
return 0x09;
case 'v':
return 0x0B;
case 'x':
nDigits = 2;
goto lexHex;
case 'u':
nDigits = 4;
lexHex:
{
uint32 n = 0;
while (nDigits--) {
ch = getChar();
uint digit;
if (!isASCIIHexDigit(char16orEOFToChar16(ch), digit))
goto error;
n = (n << 4) | digit;
}
return char16(n);
}
default:
if (ch != char16eof) {
CharInfo chi(char16orEOFToChar16(ch));
if (!isAlphanumeric(chi) && !isLineBreak(chi))
return char16orEOFToChar16(ch);
}
}
error:
syntaxError("Bad escape code");
return 0;
}
// Read an identifier into s. The initial value of s is ignored and cleared.
// Return true if an escape code has been encountered.
// If allowLeadingDigit is true, allow the first character of s to be a digit, just like any
// continuing identifier character.
bool JS::Lexer::lexIdentifier(String &s, bool allowLeadingDigit)
{
reader.beginRecording(s);
bool hasEscape = false;
while (true) {
char16orEOF ch = getChar();
char16orEOF ch2 = ch;
if (ch == '\\') {
ch2 = lexEscape(true);
hasEscape = true;
}
CharInfo chi2(char16orEOFToChar16(ch2));
if (!(allowLeadingDigit ? isIdContinuing(chi2) : isIdLeading(chi2))) {
if (ch == '\\')
syntaxError("Identifier escape expands into non-identifier character");
else
reader.unget();
break;
}
reader.recordChar(char16orEOFToChar16(ch2));
allowLeadingDigit = true;
}
reader.endRecording();
return hasEscape;
}
// Read a numeric literal into nextToken->chars and nextToken->value.
// Return true if the numeric literal is followed by a unit, but don't read the unit yet.
bool JS::Lexer::lexNumeral()
{
int hasDecimalPoint = 0;
String &s = nextToken->chars;
uint digit;
reader.beginRecording(s);
char16orEOF ch = getChar();
if (ch == '0') {
reader.recordChar('0');
ch = getChar();
if ((ch&~0x20) == 'X') {
uint32 pos = reader.charPos();
char16orEOF ch2 = getChar();
if (isASCIIHexDigit(char16orEOFToChar16(ch2), digit)) {
reader.recordChar(char16orEOFToChar16(ch));
do {
reader.recordChar(char16orEOFToChar16(ch2));
ch2 = getChar();
} while (isASCIIHexDigit(char16orEOFToChar16(ch2), digit));
ch = ch2;
} else
reader.backUpTo(pos);
goto done;
} else if (isASCIIDecimalDigit(char16orEOFToChar16(ch))) {
syntaxError("Numeric constant syntax error");
}
}
while (isASCIIDecimalDigit(char16orEOFToChar16(ch)) || ch == '.' && !hasDecimalPoint++) {
reader.recordChar(char16orEOFToChar16(ch));
ch = getChar();
}
if ((ch&~0x20) == 'E') {
uint32 pos = reader.charPos();
char16orEOF ch2 = getChar();
char16 sign = 0;
if (ch2 == '+' || ch2 == '-') {
sign = char16orEOFToChar16(ch2);
ch2 = getChar();
}
if (isASCIIDecimalDigit(char16orEOFToChar16(ch2))) {
reader.recordChar(char16orEOFToChar16(ch));
if (sign)
reader.recordChar(sign);
do {
reader.recordChar(char16orEOFToChar16(ch2));
ch2 = getChar();
} while (isASCIIDecimalDigit(char16orEOFToChar16(ch2)));
ch = ch2;
} else
reader.backUpTo(pos);
}
done:
// At this point the reader is just past the character ch, which is the first non-formatting character
// that is not part of the number.
reader.endRecording();
const char16 *sBegin = s.data();
const char16 *sEnd = sBegin + s.size();
const char16 *numEnd;
nextToken->value = stringToDouble(sBegin, sEnd, numEnd);
ASSERT(numEnd == sEnd);
reader.unget();
ASSERT(ch == reader.peek());
return isIdContinuing(char16orEOFToChar16(ch)) || ch == '\\';
}
// Read a string literal into s. The initial value of s is ignored and cleared.
// The opening quote has already been read into separator.
void JS::Lexer::lexString(String &s, char16 separator)
{
char16orEOF ch;
reader.beginRecording(s);
while ((ch = reader.get()) != separator) {
CharInfo chi(char16orEOFToChar16(ch));
if (!isFormat(chi)) {
if (ch == '\\')
ch = lexEscape(false);
else if (ch == char16eof || isLineBreak(chi))
syntaxError("Unterminated string literal");
reader.recordChar(char16orEOFToChar16(ch));
}
}
reader.endRecording();
}
// Read a regular expression literal. Store the regular expression in nextToken->identifier
// and the flags in nextToken->chars.
// The opening slash has already been read.
void JS::Lexer::lexRegExp()
{
String s;
char16orEOF prevCh = 0;
reader.beginRecording(s);
while (true) {
char16orEOF ch = getChar();
CharInfo chi(char16orEOFToChar16(ch));
if (ch == char16eof || isLineBreak(chi))
syntaxError("Unterminated regular expression literal");
if (prevCh == '\\') {
reader.recordChar(char16orEOFToChar16(ch));
prevCh = 0; // Ignore slashes and backslashes immediately after a backslash
} else if (ch != '/') {
reader.recordChar(char16orEOFToChar16(ch));
prevCh = ch;
} else
break;
}
reader.endRecording();
nextToken->identifier = &world.identifiers[s];
lexIdentifier(nextToken->chars, true);
}
// Read a token from the Reader and store it at *nextToken.
// If the Reader reached the end of file, store a Token whose Kind is End.
void JS::Lexer::lexToken(bool preferRegExp)
{
Token &t = *nextToken;
t.lineBreak = false;
t.identifier = 0;
//clear(t.chars); // Don't really need to waste time clearing this string here
t.value = 0.0;
Token::Kind kind;
if (lexingUnit) {
lexIdentifier(t.chars, false);
ASSERT(t.chars.size());
kind = Token::Unit; // unit
lexingUnit = false;
} else {
next:
char16orEOF ch = reader.get();
if (ch == char16eof) {
endOfInput:
kind = Token::End;
} else {
char16orEOF ch2;
CharInfo chi(char16orEOFToChar16(ch));
switch (cGroup(chi)) {
case CharInfo::FormatGroup:
case CharInfo::WhiteGroup:
goto next;
case CharInfo::IdGroup:
t.pos.charPos = reader.charPos() - 1;
readIdentifier:
{
reader.unget();
String s;
bool hasEscape = lexIdentifier(s, false);
t.identifier = &world.identifiers[s];
kind = hasEscape ? Token::Id : t.identifier->tokenKind;
}
break;
case CharInfo::NonIdGroup:
case CharInfo::IdContinueGroup:
t.pos.charPos = reader.charPos() - 1;
switch (ch) {
case '(':
kind = Token::OpenParenthesis; // (
break;
case ')':
kind = Token::CloseParenthesis; // )
break;
case '[':
kind = Token::OpenBracket; // [
break;
case ']':
kind = Token::CloseBracket; // ]
break;
case '{':
kind = Token::OpenBrace; // {
break;
case '}':
kind = Token::CloseBrace; // }
break;
case ',':
kind = Token::Comma; // ,
break;
case ';':
kind = Token::Semicolon; // ;
break;
case '.':
kind = Token::Dot; // .
ch2 = getChar();
if (isASCIIDecimalDigit(char16orEOFToChar16(ch2))) {
reader.backUpTo(t.pos.charPos);
goto number; // decimal point
} else if (ch2 == '.') {
kind = Token::DoubleDot; // ..
if (testChar('.'))
kind = Token::TripleDot; // ...
} else
reader.unget();
break;
case ':':
kind = Token::Colon; // :
if (testChar(':'))
kind = Token::DoubleColon; // ::
break;
case '#':
kind = Token::Pound; // #
break;
case '@':
kind = Token::At; // @
break;
case '?':
kind = Token::Question; // ?
break;
case '~':
kind = Token::Complement; // ~
break;
case '!':
kind = Token::Not; // !
if (testChar('=')) {
kind = Token::NotEqual; // !=
if (testChar('='))
kind = Token::NotIdentical; // !==
}
break;
case '*':
kind = Token::Times; // * *=
tryAssignment:
if (testChar('='))
kind = Token::Kind(kind + Token::TimesEquals - Token::Times);
break;
case '/':
kind = Token::Divide; // /
ch = getChar();
if (ch == '/') { // // comment
do {
ch = reader.get();
if (ch == char16eof)
goto endOfInput;
} while (!isLineBreak(char16orEOFToChar16(ch)));
goto endOfLine;
} else if (ch == '*') { // /* comment */
ch = 0;
do {
ch2 = ch;
ch = getChar();
if (isLineBreak(char16orEOFToChar16(ch))) {
reader.beginLine();
t.lineBreak = true;
}
if (ch == char16eof)
syntaxError("Unterminated /* comment");
} while (ch != '/' || ch2 != '*');
goto next;
} else {
reader.unget();
if (preferRegExp) { // Regular expression
kind = Token::RegExp;
lexRegExp();
} else
goto tryAssignment; // /=
}
break;
case '%':
kind = Token::Modulo; // %
goto tryAssignment; // %=
case '+':
kind = Token::Plus; // +
if (testChar('+'))
kind = Token::Increment; // ++
else
goto tryAssignment; // +=
break;
case '-':
kind = Token::Minus; // -
ch = getChar();
if (ch == '-')
kind = Token::Decrement; // --
else if (ch == '>')
kind = Token::Arrow; // ->
else {
reader.unget();
goto tryAssignment; // -=
}
break;
case '&':
kind = Token::And; // & && &= &&=
logical:
if (testChar(char16orEOFToChar16(ch)))
kind = Token::Kind(kind - Token::And + Token::LogicalAnd);
goto tryAssignment;
case '^':
kind = Token::Xor; // ^ ^^ ^= ^^=
goto logical;
case '|':
kind = Token::Or; // | || |= ||=
goto logical;
case '=':
kind = Token::Assignment; // =
if (testChar('=')) {
kind = Token::Equal; // ==
if (testChar('='))
kind = Token::Identical; // ===
}
break;
case '<':
kind = Token::LessThan; // <
if (testChar('<')) {
kind = Token::LeftShift; // <<
goto tryAssignment; // <<=
}
comparison:
if (testChar('=')) // <= >=
kind = Token::Kind(kind + Token::LessThanOrEqual - Token::LessThan);
break;
case '>':
kind = Token::GreaterThan; // >
if (testChar('>')) {
kind = Token::RightShift; // >>
if (testChar('>'))
kind = Token::LogicalRightShift; // >>>
goto tryAssignment; // >>= >>>=
}
goto comparison;
case '\\':
goto readIdentifier; // An identifier that starts with an escape
case '\'':
case '"':
kind = Token::Str; // 'string' "string"
lexString(t.chars, char16orEOFToChar16(ch));
break;
case '0':
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
reader.unget(); // Number
number:
kind = Token::Num;
lexingUnit = lexNumeral();
break;
default:
syntaxError("Bad character");
}
break;
case CharInfo::LineBreakGroup:
endOfLine:
reader.beginLine();
t.lineBreak = true;
goto next;
}
}
}
t.kind = kind;
t.pos.lineFileOffset = reader.lineFileOffset;
t.pos.lineNum = reader.lineNum;
}