/* * Copyright (C) 1999-2000 Harri Porten (porten@kde.org) * Copyright (C) 2006, 2007, 2008, 2009, 2011, 2012, 2013 Apple Inc. All Rights Reserved. * Copyright (C) 2007 Cameron Zwarich (cwzwarich@uwaterloo.ca) * Copyright (C) 2010 Zoltan Herczeg (zherczeg@inf.u-szeged.hu) * Copyright (C) 2012 Mathias Bynens (mathias@qiwi.be) * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. * */ #include "config.h" #include "Lexer.h" #include "BuiltinNames.h" #include "Identifier.h" #include "JSCInlines.h" #include "JSFunctionInlines.h" #include "JSGlobalObjectFunctions.h" #include "KeywordLookup.h" #include "Lexer.lut.h" #include "Nodes.h" #include "Parser.h" #include #include #include #include #include namespace JSC { bool isLexerKeyword(const Identifier& identifier) { return JSC::mainTable.entry(identifier); } enum CharacterType { // Types for the main switch // The first three types are fixed, and also used for identifying // ASCII alpha and alphanumeric characters (see isIdentStart and isIdentPart). CharacterIdentifierStart, CharacterZero, CharacterNumber, CharacterInvalid, CharacterLineTerminator, CharacterExclamationMark, CharacterOpenParen, CharacterCloseParen, CharacterOpenBracket, CharacterCloseBracket, CharacterComma, CharacterColon, CharacterQuestion, CharacterTilde, CharacterQuote, CharacterBackQuote, CharacterDot, CharacterSlash, CharacterBackSlash, CharacterSemicolon, CharacterOpenBrace, CharacterCloseBrace, CharacterAdd, CharacterSub, CharacterMultiply, CharacterModulo, CharacterAnd, CharacterXor, CharacterOr, CharacterLess, CharacterGreater, CharacterEqual, // Other types (only one so far) CharacterWhiteSpace, CharacterPrivateIdentifierStart }; // 256 Latin-1 codes static const unsigned short typesOfLatin1Characters[256] = { /* 0 - Null */ CharacterInvalid, /* 1 - Start of Heading */ CharacterInvalid, /* 2 - Start of Text */ CharacterInvalid, /* 3 - End of Text */ CharacterInvalid, /* 4 - End of Transm. */ CharacterInvalid, /* 5 - Enquiry */ CharacterInvalid, /* 6 - Acknowledgment */ CharacterInvalid, /* 7 - Bell */ CharacterInvalid, /* 8 - Back Space */ CharacterInvalid, /* 9 - Horizontal Tab */ CharacterWhiteSpace, /* 10 - Line Feed */ CharacterLineTerminator, /* 11 - Vertical Tab */ CharacterWhiteSpace, /* 12 - Form Feed */ CharacterWhiteSpace, /* 13 - Carriage Return */ CharacterLineTerminator, /* 14 - Shift Out */ CharacterInvalid, /* 15 - Shift In */ CharacterInvalid, /* 16 - Data Line Escape */ CharacterInvalid, /* 17 - Device Control 1 */ CharacterInvalid, /* 18 - Device Control 2 */ CharacterInvalid, /* 19 - Device Control 3 */ CharacterInvalid, /* 20 - Device Control 4 */ CharacterInvalid, /* 21 - Negative Ack. */ CharacterInvalid, /* 22 - Synchronous Idle */ CharacterInvalid, /* 23 - End of Transmit */ CharacterInvalid, /* 24 - Cancel */ CharacterInvalid, /* 25 - End of Medium */ CharacterInvalid, /* 26 - Substitute */ CharacterInvalid, /* 27 - Escape */ CharacterInvalid, /* 28 - File Separator */ CharacterInvalid, /* 29 - Group Separator */ CharacterInvalid, /* 30 - Record Separator */ CharacterInvalid, /* 31 - Unit Separator */ CharacterInvalid, /* 32 - Space */ CharacterWhiteSpace, /* 33 - ! */ CharacterExclamationMark, /* 34 - " */ CharacterQuote, /* 35 - # */ CharacterInvalid, /* 36 - $ */ CharacterIdentifierStart, /* 37 - % */ CharacterModulo, /* 38 - & */ CharacterAnd, /* 39 - ' */ CharacterQuote, /* 40 - ( */ CharacterOpenParen, /* 41 - ) */ CharacterCloseParen, /* 42 - * */ CharacterMultiply, /* 43 - + */ CharacterAdd, /* 44 - , */ CharacterComma, /* 45 - - */ CharacterSub, /* 46 - . */ CharacterDot, /* 47 - / */ CharacterSlash, /* 48 - 0 */ CharacterZero, /* 49 - 1 */ CharacterNumber, /* 50 - 2 */ CharacterNumber, /* 51 - 3 */ CharacterNumber, /* 52 - 4 */ CharacterNumber, /* 53 - 5 */ CharacterNumber, /* 54 - 6 */ CharacterNumber, /* 55 - 7 */ CharacterNumber, /* 56 - 8 */ CharacterNumber, /* 57 - 9 */ CharacterNumber, /* 58 - : */ CharacterColon, /* 59 - ; */ CharacterSemicolon, /* 60 - < */ CharacterLess, /* 61 - = */ CharacterEqual, /* 62 - > */ CharacterGreater, /* 63 - ? */ CharacterQuestion, /* 64 - @ */ CharacterPrivateIdentifierStart, /* 65 - A */ CharacterIdentifierStart, /* 66 - B */ CharacterIdentifierStart, /* 67 - C */ CharacterIdentifierStart, /* 68 - D */ CharacterIdentifierStart, /* 69 - E */ CharacterIdentifierStart, /* 70 - F */ CharacterIdentifierStart, /* 71 - G */ CharacterIdentifierStart, /* 72 - H */ CharacterIdentifierStart, /* 73 - I */ CharacterIdentifierStart, /* 74 - J */ CharacterIdentifierStart, /* 75 - K */ CharacterIdentifierStart, /* 76 - L */ CharacterIdentifierStart, /* 77 - M */ CharacterIdentifierStart, /* 78 - N */ CharacterIdentifierStart, /* 79 - O */ CharacterIdentifierStart, /* 80 - P */ CharacterIdentifierStart, /* 81 - Q */ CharacterIdentifierStart, /* 82 - R */ CharacterIdentifierStart, /* 83 - S */ CharacterIdentifierStart, /* 84 - T */ CharacterIdentifierStart, /* 85 - U */ CharacterIdentifierStart, /* 86 - V */ CharacterIdentifierStart, /* 87 - W */ CharacterIdentifierStart, /* 88 - X */ CharacterIdentifierStart, /* 89 - Y */ CharacterIdentifierStart, /* 90 - Z */ CharacterIdentifierStart, /* 91 - [ */ CharacterOpenBracket, /* 92 - \ */ CharacterBackSlash, /* 93 - ] */ CharacterCloseBracket, /* 94 - ^ */ CharacterXor, /* 95 - _ */ CharacterIdentifierStart, /* 96 - ` */ CharacterBackQuote, /* 97 - a */ CharacterIdentifierStart, /* 98 - b */ CharacterIdentifierStart, /* 99 - c */ CharacterIdentifierStart, /* 100 - d */ CharacterIdentifierStart, /* 101 - e */ CharacterIdentifierStart, /* 102 - f */ CharacterIdentifierStart, /* 103 - g */ CharacterIdentifierStart, /* 104 - h */ CharacterIdentifierStart, /* 105 - i */ CharacterIdentifierStart, /* 106 - j */ CharacterIdentifierStart, /* 107 - k */ CharacterIdentifierStart, /* 108 - l */ CharacterIdentifierStart, /* 109 - m */ CharacterIdentifierStart, /* 110 - n */ CharacterIdentifierStart, /* 111 - o */ CharacterIdentifierStart, /* 112 - p */ CharacterIdentifierStart, /* 113 - q */ CharacterIdentifierStart, /* 114 - r */ CharacterIdentifierStart, /* 115 - s */ CharacterIdentifierStart, /* 116 - t */ CharacterIdentifierStart, /* 117 - u */ CharacterIdentifierStart, /* 118 - v */ CharacterIdentifierStart, /* 119 - w */ CharacterIdentifierStart, /* 120 - x */ CharacterIdentifierStart, /* 121 - y */ CharacterIdentifierStart, /* 122 - z */ CharacterIdentifierStart, /* 123 - { */ CharacterOpenBrace, /* 124 - | */ CharacterOr, /* 125 - } */ CharacterCloseBrace, /* 126 - ~ */ CharacterTilde, /* 127 - Delete */ CharacterInvalid, /* 128 - Cc category */ CharacterInvalid, /* 129 - Cc category */ CharacterInvalid, /* 130 - Cc category */ CharacterInvalid, /* 131 - Cc category */ CharacterInvalid, /* 132 - Cc category */ CharacterInvalid, /* 133 - Cc category */ CharacterInvalid, /* 134 - Cc category */ CharacterInvalid, /* 135 - Cc category */ CharacterInvalid, /* 136 - Cc category */ CharacterInvalid, /* 137 - Cc category */ CharacterInvalid, /* 138 - Cc category */ CharacterInvalid, /* 139 - Cc category */ CharacterInvalid, /* 140 - Cc category */ CharacterInvalid, /* 141 - Cc category */ CharacterInvalid, /* 142 - Cc category */ CharacterInvalid, /* 143 - Cc category */ CharacterInvalid, /* 144 - Cc category */ CharacterInvalid, /* 145 - Cc category */ CharacterInvalid, /* 146 - Cc category */ CharacterInvalid, /* 147 - Cc category */ CharacterInvalid, /* 148 - Cc category */ CharacterInvalid, /* 149 - Cc category */ CharacterInvalid, /* 150 - Cc category */ CharacterInvalid, /* 151 - Cc category */ CharacterInvalid, /* 152 - Cc category */ CharacterInvalid, /* 153 - Cc category */ CharacterInvalid, /* 154 - Cc category */ CharacterInvalid, /* 155 - Cc category */ CharacterInvalid, /* 156 - Cc category */ CharacterInvalid, /* 157 - Cc category */ CharacterInvalid, /* 158 - Cc category */ CharacterInvalid, /* 159 - Cc category */ CharacterInvalid, /* 160 - Zs category (nbsp) */ CharacterWhiteSpace, /* 161 - Po category */ CharacterInvalid, /* 162 - Sc category */ CharacterInvalid, /* 163 - Sc category */ CharacterInvalid, /* 164 - Sc category */ CharacterInvalid, /* 165 - Sc category */ CharacterInvalid, /* 166 - So category */ CharacterInvalid, /* 167 - So category */ CharacterInvalid, /* 168 - Sk category */ CharacterInvalid, /* 169 - So category */ CharacterInvalid, /* 170 - Ll category */ CharacterIdentifierStart, /* 171 - Pi category */ CharacterInvalid, /* 172 - Sm category */ CharacterInvalid, /* 173 - Cf category */ CharacterInvalid, /* 174 - So category */ CharacterInvalid, /* 175 - Sk category */ CharacterInvalid, /* 176 - So category */ CharacterInvalid, /* 177 - Sm category */ CharacterInvalid, /* 178 - No category */ CharacterInvalid, /* 179 - No category */ CharacterInvalid, /* 180 - Sk category */ CharacterInvalid, /* 181 - Ll category */ CharacterIdentifierStart, /* 182 - So category */ CharacterInvalid, /* 183 - Po category */ CharacterInvalid, /* 184 - Sk category */ CharacterInvalid, /* 185 - No category */ CharacterInvalid, /* 186 - Ll category */ CharacterIdentifierStart, /* 187 - Pf category */ CharacterInvalid, /* 188 - No category */ CharacterInvalid, /* 189 - No category */ CharacterInvalid, /* 190 - No category */ CharacterInvalid, /* 191 - Po category */ CharacterInvalid, /* 192 - Lu category */ CharacterIdentifierStart, /* 193 - Lu category */ CharacterIdentifierStart, /* 194 - Lu category */ CharacterIdentifierStart, /* 195 - Lu category */ CharacterIdentifierStart, /* 196 - Lu category */ CharacterIdentifierStart, /* 197 - Lu category */ CharacterIdentifierStart, /* 198 - Lu category */ CharacterIdentifierStart, /* 199 - Lu category */ CharacterIdentifierStart, /* 200 - Lu category */ CharacterIdentifierStart, /* 201 - Lu category */ CharacterIdentifierStart, /* 202 - Lu category */ CharacterIdentifierStart, /* 203 - Lu category */ CharacterIdentifierStart, /* 204 - Lu category */ CharacterIdentifierStart, /* 205 - Lu category */ CharacterIdentifierStart, /* 206 - Lu category */ CharacterIdentifierStart, /* 207 - Lu category */ CharacterIdentifierStart, /* 208 - Lu category */ CharacterIdentifierStart, /* 209 - Lu category */ CharacterIdentifierStart, /* 210 - Lu category */ CharacterIdentifierStart, /* 211 - Lu category */ CharacterIdentifierStart, /* 212 - Lu category */ CharacterIdentifierStart, /* 213 - Lu category */ CharacterIdentifierStart, /* 214 - Lu category */ CharacterIdentifierStart, /* 215 - Sm category */ CharacterInvalid, /* 216 - Lu category */ CharacterIdentifierStart, /* 217 - Lu category */ CharacterIdentifierStart, /* 218 - Lu category */ CharacterIdentifierStart, /* 219 - Lu category */ CharacterIdentifierStart, /* 220 - Lu category */ CharacterIdentifierStart, /* 221 - Lu category */ CharacterIdentifierStart, /* 222 - Lu category */ CharacterIdentifierStart, /* 223 - Ll category */ CharacterIdentifierStart, /* 224 - Ll category */ CharacterIdentifierStart, /* 225 - Ll category */ CharacterIdentifierStart, /* 226 - Ll category */ CharacterIdentifierStart, /* 227 - Ll category */ CharacterIdentifierStart, /* 228 - Ll category */ CharacterIdentifierStart, /* 229 - Ll category */ CharacterIdentifierStart, /* 230 - Ll category */ CharacterIdentifierStart, /* 231 - Ll category */ CharacterIdentifierStart, /* 232 - Ll category */ CharacterIdentifierStart, /* 233 - Ll category */ CharacterIdentifierStart, /* 234 - Ll category */ CharacterIdentifierStart, /* 235 - Ll category */ CharacterIdentifierStart, /* 236 - Ll category */ CharacterIdentifierStart, /* 237 - Ll category */ CharacterIdentifierStart, /* 238 - Ll category */ CharacterIdentifierStart, /* 239 - Ll category */ CharacterIdentifierStart, /* 240 - Ll category */ CharacterIdentifierStart, /* 241 - Ll category */ CharacterIdentifierStart, /* 242 - Ll category */ CharacterIdentifierStart, /* 243 - Ll category */ CharacterIdentifierStart, /* 244 - Ll category */ CharacterIdentifierStart, /* 245 - Ll category */ CharacterIdentifierStart, /* 246 - Ll category */ CharacterIdentifierStart, /* 247 - Sm category */ CharacterInvalid, /* 248 - Ll category */ CharacterIdentifierStart, /* 249 - Ll category */ CharacterIdentifierStart, /* 250 - Ll category */ CharacterIdentifierStart, /* 251 - Ll category */ CharacterIdentifierStart, /* 252 - Ll category */ CharacterIdentifierStart, /* 253 - Ll category */ CharacterIdentifierStart, /* 254 - Ll category */ CharacterIdentifierStart, /* 255 - Ll category */ CharacterIdentifierStart }; // This table provides the character that results from \X where X is the index in the table beginning // with SPACE. A table value of 0 means that more processing needs to be done. static const LChar singleCharacterEscapeValuesForASCII[128] = { /* 0 - Null */ 0, /* 1 - Start of Heading */ 0, /* 2 - Start of Text */ 0, /* 3 - End of Text */ 0, /* 4 - End of Transm. */ 0, /* 5 - Enquiry */ 0, /* 6 - Acknowledgment */ 0, /* 7 - Bell */ 0, /* 8 - Back Space */ 0, /* 9 - Horizontal Tab */ 0, /* 10 - Line Feed */ 0, /* 11 - Vertical Tab */ 0, /* 12 - Form Feed */ 0, /* 13 - Carriage Return */ 0, /* 14 - Shift Out */ 0, /* 15 - Shift In */ 0, /* 16 - Data Line Escape */ 0, /* 17 - Device Control 1 */ 0, /* 18 - Device Control 2 */ 0, /* 19 - Device Control 3 */ 0, /* 20 - Device Control 4 */ 0, /* 21 - Negative Ack. */ 0, /* 22 - Synchronous Idle */ 0, /* 23 - End of Transmit */ 0, /* 24 - Cancel */ 0, /* 25 - End of Medium */ 0, /* 26 - Substitute */ 0, /* 27 - Escape */ 0, /* 28 - File Separator */ 0, /* 29 - Group Separator */ 0, /* 30 - Record Separator */ 0, /* 31 - Unit Separator */ 0, /* 32 - Space */ ' ', /* 33 - ! */ '!', /* 34 - " */ '"', /* 35 - # */ '#', /* 36 - $ */ '$', /* 37 - % */ '%', /* 38 - & */ '&', /* 39 - ' */ '\'', /* 40 - ( */ '(', /* 41 - ) */ ')', /* 42 - * */ '*', /* 43 - + */ '+', /* 44 - , */ ',', /* 45 - - */ '-', /* 46 - . */ '.', /* 47 - / */ '/', /* 48 - 0 */ 0, /* 49 - 1 */ 0, /* 50 - 2 */ 0, /* 51 - 3 */ 0, /* 52 - 4 */ 0, /* 53 - 5 */ 0, /* 54 - 6 */ 0, /* 55 - 7 */ 0, /* 56 - 8 */ 0, /* 57 - 9 */ 0, /* 58 - : */ ':', /* 59 - ; */ ';', /* 60 - < */ '<', /* 61 - = */ '=', /* 62 - > */ '>', /* 63 - ? */ '?', /* 64 - @ */ '@', /* 65 - A */ 'A', /* 66 - B */ 'B', /* 67 - C */ 'C', /* 68 - D */ 'D', /* 69 - E */ 'E', /* 70 - F */ 'F', /* 71 - G */ 'G', /* 72 - H */ 'H', /* 73 - I */ 'I', /* 74 - J */ 'J', /* 75 - K */ 'K', /* 76 - L */ 'L', /* 77 - M */ 'M', /* 78 - N */ 'N', /* 79 - O */ 'O', /* 80 - P */ 'P', /* 81 - Q */ 'Q', /* 82 - R */ 'R', /* 83 - S */ 'S', /* 84 - T */ 'T', /* 85 - U */ 'U', /* 86 - V */ 'V', /* 87 - W */ 'W', /* 88 - X */ 'X', /* 89 - Y */ 'Y', /* 90 - Z */ 'Z', /* 91 - [ */ '[', /* 92 - \ */ '\\', /* 93 - ] */ ']', /* 94 - ^ */ '^', /* 95 - _ */ '_', /* 96 - ` */ '`', /* 97 - a */ 'a', /* 98 - b */ 0x08, /* 99 - c */ 'c', /* 100 - d */ 'd', /* 101 - e */ 'e', /* 102 - f */ 0x0C, /* 103 - g */ 'g', /* 104 - h */ 'h', /* 105 - i */ 'i', /* 106 - j */ 'j', /* 107 - k */ 'k', /* 108 - l */ 'l', /* 109 - m */ 'm', /* 110 - n */ 0x0A, /* 111 - o */ 'o', /* 112 - p */ 'p', /* 113 - q */ 'q', /* 114 - r */ 0x0D, /* 115 - s */ 's', /* 116 - t */ 0x09, /* 117 - u */ 0, /* 118 - v */ 0x0B, /* 119 - w */ 'w', /* 120 - x */ 0, /* 121 - y */ 'y', /* 122 - z */ 'z', /* 123 - { */ '{', /* 124 - | */ '|', /* 125 - } */ '}', /* 126 - ~ */ '~', /* 127 - Delete */ 0 }; template Lexer::Lexer(VM* vm, JSParserBuiltinMode builtinMode) : m_isReparsingFunction(false) , m_vm(vm) , m_parsingBuiltinFunction(builtinMode == JSParserBuiltinMode::Builtin) { } static inline JSTokenType tokenTypeForIntegerLikeToken(double doubleValue) { if ((doubleValue || !std::signbit(doubleValue)) && static_cast(doubleValue) == doubleValue) return INTEGER; return DOUBLE; } template Lexer::~Lexer() { } template String Lexer::invalidCharacterMessage() const { switch (m_current) { case 0: return ASCIILiteral("Invalid character: '\\0'"); case 10: return ASCIILiteral("Invalid character: '\\n'"); case 11: return ASCIILiteral("Invalid character: '\\v'"); case 13: return ASCIILiteral("Invalid character: '\\r'"); case 35: return ASCIILiteral("Invalid character: '#'"); case 64: return ASCIILiteral("Invalid character: '@'"); case 96: return ASCIILiteral("Invalid character: '`'"); default: return String::format("Invalid character '\\u%04u'", static_cast(m_current)); } } template ALWAYS_INLINE const T* Lexer::currentSourcePtr() const { ASSERT(m_code <= m_codeEnd); return m_code; } template void Lexer::setCode(const SourceCode& source, ParserArena* arena) { m_arena = &arena->identifierArena(); m_lineNumber = source.firstLine(); m_lastToken = -1; StringView sourceString = source.provider()->source(); if (!sourceString.isNull()) setCodeStart(sourceString); else m_codeStart = 0; m_source = &source; m_sourceOffset = source.startOffset(); m_codeStartPlusOffset = m_codeStart + source.startOffset(); m_code = m_codeStartPlusOffset; m_codeEnd = m_codeStart + source.endOffset(); m_error = false; m_atLineStart = true; m_lineStart = m_code; m_lexErrorMessage = String(); m_sourceURLDirective = String(); m_sourceMappingURLDirective = String(); m_buffer8.reserveInitialCapacity(initialReadBufferCapacity); m_buffer16.reserveInitialCapacity((m_codeEnd - m_code) / 2); m_bufferForRawTemplateString16.reserveInitialCapacity(initialReadBufferCapacity); if (LIKELY(m_code < m_codeEnd)) m_current = *m_code; else m_current = 0; ASSERT(currentOffset() == source.startOffset()); } template template ALWAYS_INLINE void Lexer::internalShift() { m_code += shiftAmount; ASSERT(currentOffset() >= currentLineStartOffset()); m_current = *m_code; } template ALWAYS_INLINE void Lexer::shift() { // At one point timing showed that setting m_current to 0 unconditionally was faster than an if-else sequence. m_current = 0; ++m_code; if (LIKELY(m_code < m_codeEnd)) m_current = *m_code; } template ALWAYS_INLINE bool Lexer::atEnd() const { ASSERT(!m_current || m_code < m_codeEnd); return UNLIKELY(UNLIKELY(!m_current) && m_code == m_codeEnd); } template ALWAYS_INLINE T Lexer::peek(int offset) const { ASSERT(offset > 0 && offset < 5); const T* code = m_code + offset; return (code < m_codeEnd) ? *code : 0; } struct ParsedUnicodeEscapeValue { ParsedUnicodeEscapeValue(UChar32 value) : m_value(value) { ASSERT(isValid()); } enum SpecialValueType { Incomplete = -2, Invalid = -1 }; ParsedUnicodeEscapeValue(SpecialValueType type) : m_value(type) { } bool isValid() const { return m_value >= 0; } bool isIncomplete() const { return m_value == Incomplete; } UChar32 value() const { ASSERT(isValid()); return m_value; } private: UChar32 m_value; }; template ParsedUnicodeEscapeValue Lexer::parseUnicodeEscape() { if (m_current == '{') { shift(); UChar32 codePoint = 0; do { if (!isASCIIHexDigit(m_current)) return m_current ? ParsedUnicodeEscapeValue::Invalid : ParsedUnicodeEscapeValue::Incomplete; codePoint = (codePoint << 4) | toASCIIHexValue(m_current); if (codePoint > UCHAR_MAX_VALUE) return ParsedUnicodeEscapeValue::Invalid; shift(); } while (m_current != '}'); shift(); return codePoint; } auto character2 = peek(1); auto character3 = peek(2); auto character4 = peek(3); if (UNLIKELY(!isASCIIHexDigit(m_current) || !isASCIIHexDigit(character2) || !isASCIIHexDigit(character3) || !isASCIIHexDigit(character4))) return (m_code + 4) >= m_codeEnd ? ParsedUnicodeEscapeValue::Incomplete : ParsedUnicodeEscapeValue::Invalid; auto result = convertUnicode(m_current, character2, character3, character4); shift(); shift(); shift(); shift(); return result; } template void Lexer::shiftLineTerminator() { ASSERT(isLineTerminator(m_current)); m_positionBeforeLastNewline = currentPosition(); T prev = m_current; shift(); // Allow both CRLF and LFCR. if (prev + m_current == '\n' + '\r') shift(); ++m_lineNumber; } template ALWAYS_INLINE bool Lexer::lastTokenWasRestrKeyword() const { return m_lastToken == CONTINUE || m_lastToken == BREAK || m_lastToken == RETURN || m_lastToken == THROW; } template ALWAYS_INLINE void Lexer::skipWhitespace() { while (isWhiteSpace(m_current)) shift(); } static NEVER_INLINE bool isNonLatin1IdentStart(UChar c) { return U_GET_GC_MASK(c) & U_GC_L_MASK; } static ALWAYS_INLINE bool isLatin1(LChar) { return true; } static ALWAYS_INLINE bool isLatin1(UChar c) { return c < 256; } static ALWAYS_INLINE bool isLatin1(UChar32 c) { return !(c & ~0xFF); } static inline bool isIdentStart(LChar c) { return typesOfLatin1Characters[c] == CharacterIdentifierStart; } static inline bool isIdentStart(UChar32 c) { return isLatin1(c) ? isIdentStart(static_cast(c)) : isNonLatin1IdentStart(c); } static NEVER_INLINE bool isNonLatin1IdentPart(UChar32 c) { // FIXME: ES6 says this should be based on the Unicode property ID_Continue now instead. return (U_GET_GC_MASK(c) & (U_GC_L_MASK | U_GC_MN_MASK | U_GC_MC_MASK | U_GC_ND_MASK | U_GC_PC_MASK)) || c == 0x200C || c == 0x200D; } static ALWAYS_INLINE bool isIdentPart(LChar c) { // Character types are divided into two groups depending on whether they can be part of an // identifier or not. Those whose type value is less or equal than CharacterNumber can be // part of an identifier. (See the CharacterType definition for more details.) return typesOfLatin1Characters[c] <= CharacterNumber; } static ALWAYS_INLINE bool isIdentPart(UChar32 c) { return isLatin1(c) ? isIdentPart(static_cast(c)) : isNonLatin1IdentPart(c); } static ALWAYS_INLINE bool isIdentPart(UChar c) { return isIdentPart(static_cast(c)); } template ALWAYS_INLINE bool isIdentPartIncludingEscapeTemplate(const CharacterType* code, const CharacterType* codeEnd) { if (isIdentPart(code[0])) return true; // Shortest sequence handled below is \u{0}, which is 5 characters. if (!(code[0] == '\\' && codeEnd - code >= 5 && code[1] == 'u')) return false; if (code[2] == '{') { UChar32 codePoint = 0; const CharacterType* pointer; for (pointer = &code[3]; pointer < codeEnd; ++pointer) { auto digit = *pointer; if (!isASCIIHexDigit(digit)) break; codePoint = (codePoint << 4) | toASCIIHexValue(digit); if (codePoint > UCHAR_MAX_VALUE) return false; } return isIdentPart(codePoint) && pointer < codeEnd && *pointer == '}'; } // Shortest sequence handled below is \uXXXX, which is 6 characters. if (codeEnd - code < 6) return false; auto character1 = code[2]; auto character2 = code[3]; auto character3 = code[4]; auto character4 = code[5]; return isASCIIHexDigit(character1) && isASCIIHexDigit(character2) && isASCIIHexDigit(character3) && isASCIIHexDigit(character4) && isIdentPart(Lexer::convertUnicode(character1, character2, character3, character4)); } static ALWAYS_INLINE bool isIdentPartIncludingEscape(const LChar* code, const LChar* codeEnd) { return isIdentPartIncludingEscapeTemplate(code, codeEnd); } static ALWAYS_INLINE bool isIdentPartIncludingEscape(const UChar* code, const UChar* codeEnd) { return isIdentPartIncludingEscapeTemplate(code, codeEnd); } static inline LChar singleEscape(int c) { if (c < 128) { ASSERT(static_cast(c) < ARRAY_SIZE(singleCharacterEscapeValuesForASCII)); return singleCharacterEscapeValuesForASCII[c]; } return 0; } template inline void Lexer::record8(int c) { ASSERT(c >= 0); ASSERT(c <= 0xFF); m_buffer8.append(static_cast(c)); } template inline void assertCharIsIn8BitRange(T c) { UNUSED_PARAM(c); ASSERT(c >= 0); ASSERT(c <= 0xFF); } template <> inline void assertCharIsIn8BitRange(UChar c) { UNUSED_PARAM(c); ASSERT(c <= 0xFF); } template <> inline void assertCharIsIn8BitRange(LChar) { } template inline void Lexer::append8(const T* p, size_t length) { size_t currentSize = m_buffer8.size(); m_buffer8.grow(currentSize + length); LChar* rawBuffer = m_buffer8.data() + currentSize; for (size_t i = 0; i < length; i++) { T c = p[i]; assertCharIsIn8BitRange(c); rawBuffer[i] = c; } } template inline void Lexer::append16(const LChar* p, size_t length) { size_t currentSize = m_buffer16.size(); m_buffer16.grow(currentSize + length); UChar* rawBuffer = m_buffer16.data() + currentSize; for (size_t i = 0; i < length; i++) rawBuffer[i] = p[i]; } template inline void Lexer::record16(T c) { m_buffer16.append(c); } template inline void Lexer::record16(int c) { ASSERT(c >= 0); ASSERT(c <= static_cast(USHRT_MAX)); m_buffer16.append(static_cast(c)); } template inline void Lexer::recordUnicodeCodePoint(UChar32 codePoint) { ASSERT(codePoint >= 0); ASSERT(codePoint <= UCHAR_MAX_VALUE); if (U_IS_BMP(codePoint)) record16(codePoint); else { UChar codeUnits[2] = { U16_LEAD(codePoint), U16_TRAIL(codePoint) }; append16(codeUnits, 2); } } #if !ASSERT_DISABLED bool isSafeBuiltinIdentifier(VM& vm, const Identifier* ident) { if (!ident) return true; /* Just block any use of suspicious identifiers. This is intended to * be used as a safety net while implementing builtins. */ // FIXME: How can a debug-only assertion be a safety net? if (*ident == vm.propertyNames->builtinNames().callPublicName()) return false; if (*ident == vm.propertyNames->builtinNames().applyPublicName()) return false; if (*ident == vm.propertyNames->eval) return false; if (*ident == vm.propertyNames->Function) return false; return true; } #endif template <> template ALWAYS_INLINE JSTokenType Lexer::parseIdentifier(JSTokenData* tokenData, unsigned lexerFlags, bool strictMode) { const ptrdiff_t remaining = m_codeEnd - m_code; if ((remaining >= maxTokenLength) && !(lexerFlags & LexerFlagsIgnoreReservedWords)) { JSTokenType keyword = parseKeyword(tokenData); if (keyword != IDENT) { ASSERT((!shouldCreateIdentifier) || tokenData->ident); return keyword == RESERVED_IF_STRICT && !strictMode ? IDENT : keyword; } } bool isPrivateName = m_current == '@' && m_parsingBuiltinFunction; if (isPrivateName) shift(); const LChar* identifierStart = currentSourcePtr(); unsigned identifierLineStart = currentLineStartOffset(); while (isIdentPart(m_current)) shift(); if (UNLIKELY(m_current == '\\')) { setOffsetFromSourcePtr(identifierStart, identifierLineStart); return parseIdentifierSlowCase(tokenData, lexerFlags, strictMode); } const Identifier* ident = 0; if (shouldCreateIdentifier || m_parsingBuiltinFunction) { int identifierLength = currentSourcePtr() - identifierStart; ident = makeIdentifier(identifierStart, identifierLength); if (m_parsingBuiltinFunction) { if (!isSafeBuiltinIdentifier(*m_vm, ident) && !isPrivateName) { m_lexErrorMessage = makeString("The use of '", ident->string(), "' is disallowed in builtin functions."); return ERRORTOK; } if (isPrivateName) ident = m_vm->propertyNames->lookUpPrivateName(*ident); else if (*ident == m_vm->propertyNames->undefinedKeyword) tokenData->ident = &m_vm->propertyNames->undefinedPrivateName; if (!ident) return INVALID_PRIVATE_NAME_ERRORTOK; } tokenData->ident = ident; } else tokenData->ident = 0; if (UNLIKELY((remaining < maxTokenLength) && !(lexerFlags & LexerFlagsIgnoreReservedWords)) && !isPrivateName) { ASSERT(shouldCreateIdentifier); if (remaining < maxTokenLength) { const HashTableValue* entry = JSC::mainTable.entry(*ident); ASSERT((remaining < maxTokenLength) || !entry); if (!entry) return IDENT; JSTokenType token = static_cast(entry->lexerValue()); return (token != RESERVED_IF_STRICT) || strictMode ? token : IDENT; } return IDENT; } return IDENT; } template <> template ALWAYS_INLINE JSTokenType Lexer::parseIdentifier(JSTokenData* tokenData, unsigned lexerFlags, bool strictMode) { const ptrdiff_t remaining = m_codeEnd - m_code; if ((remaining >= maxTokenLength) && !(lexerFlags & LexerFlagsIgnoreReservedWords)) { JSTokenType keyword = parseKeyword(tokenData); if (keyword != IDENT) { ASSERT((!shouldCreateIdentifier) || tokenData->ident); return keyword == RESERVED_IF_STRICT && !strictMode ? IDENT : keyword; } } bool isPrivateName = m_current == '@' && m_parsingBuiltinFunction; if (isPrivateName) shift(); const UChar* identifierStart = currentSourcePtr(); int identifierLineStart = currentLineStartOffset(); UChar orAllChars = 0; while (isIdentPart(m_current)) { orAllChars |= m_current; shift(); } if (UNLIKELY(m_current == '\\')) { ASSERT(!isPrivateName); setOffsetFromSourcePtr(identifierStart, identifierLineStart); return parseIdentifierSlowCase(tokenData, lexerFlags, strictMode); } bool isAll8Bit = false; if (!(orAllChars & ~0xff)) isAll8Bit = true; const Identifier* ident = 0; if (shouldCreateIdentifier || m_parsingBuiltinFunction) { int identifierLength = currentSourcePtr() - identifierStart; if (isAll8Bit) ident = makeIdentifierLCharFromUChar(identifierStart, identifierLength); else ident = makeIdentifier(identifierStart, identifierLength); if (m_parsingBuiltinFunction) { if (!isSafeBuiltinIdentifier(*m_vm, ident) && !isPrivateName) { m_lexErrorMessage = makeString("The use of '", ident->string(), "' is disallowed in builtin functions."); return ERRORTOK; } if (isPrivateName) ident = m_vm->propertyNames->lookUpPrivateName(*ident); else if (*ident == m_vm->propertyNames->undefinedKeyword) tokenData->ident = &m_vm->propertyNames->undefinedPrivateName; if (!ident) return INVALID_PRIVATE_NAME_ERRORTOK; } tokenData->ident = ident; } else tokenData->ident = 0; if (UNLIKELY((remaining < maxTokenLength) && !(lexerFlags & LexerFlagsIgnoreReservedWords)) && !isPrivateName) { ASSERT(shouldCreateIdentifier); if (remaining < maxTokenLength) { const HashTableValue* entry = JSC::mainTable.entry(*ident); ASSERT((remaining < maxTokenLength) || !entry); if (!entry) return IDENT; JSTokenType token = static_cast(entry->lexerValue()); return (token != RESERVED_IF_STRICT) || strictMode ? token : IDENT; } return IDENT; } return IDENT; } template template JSTokenType Lexer::parseIdentifierSlowCase(JSTokenData* tokenData, unsigned lexerFlags, bool strictMode) { auto identifierStart = currentSourcePtr(); bool bufferRequired = false; while (true) { if (LIKELY(isIdentPart(m_current))) { shift(); continue; } if (LIKELY(m_current != '\\')) break; // \uXXXX unicode characters. bufferRequired = true; if (identifierStart != currentSourcePtr()) m_buffer16.append(identifierStart, currentSourcePtr() - identifierStart); shift(); if (UNLIKELY(m_current != 'u')) return atEnd() ? UNTERMINATED_IDENTIFIER_ESCAPE_ERRORTOK : INVALID_IDENTIFIER_ESCAPE_ERRORTOK; shift(); auto character = parseUnicodeEscape(); if (UNLIKELY(!character.isValid())) return character.isIncomplete() ? UNTERMINATED_IDENTIFIER_UNICODE_ESCAPE_ERRORTOK : INVALID_IDENTIFIER_UNICODE_ESCAPE_ERRORTOK; if (UNLIKELY(m_buffer16.size() ? !isIdentPart(character.value()) : !isIdentStart(character.value()))) return INVALID_IDENTIFIER_UNICODE_ESCAPE_ERRORTOK; if (shouldCreateIdentifier) recordUnicodeCodePoint(character.value()); identifierStart = currentSourcePtr(); } int identifierLength; const Identifier* ident = nullptr; if (shouldCreateIdentifier) { if (!bufferRequired) { identifierLength = currentSourcePtr() - identifierStart; ident = makeIdentifier(identifierStart, identifierLength); } else { if (identifierStart != currentSourcePtr()) m_buffer16.append(identifierStart, currentSourcePtr() - identifierStart); ident = makeIdentifier(m_buffer16.data(), m_buffer16.size()); } tokenData->ident = ident; } else tokenData->ident = nullptr; m_buffer16.shrink(0); if (LIKELY(!(lexerFlags & LexerFlagsIgnoreReservedWords))) { ASSERT(shouldCreateIdentifier); const HashTableValue* entry = JSC::mainTable.entry(*ident); if (!entry) return IDENT; JSTokenType token = static_cast(entry->lexerValue()); return (token != RESERVED_IF_STRICT) || strictMode ? token : IDENT; } return IDENT; } static ALWAYS_INLINE bool characterRequiresParseStringSlowCase(LChar character) { return character < 0xE; } static ALWAYS_INLINE bool characterRequiresParseStringSlowCase(UChar character) { return character < 0xE || character > 0xFF; } template template ALWAYS_INLINE typename Lexer::StringParseResult Lexer::parseString(JSTokenData* tokenData, bool strictMode) { int startingOffset = currentOffset(); int startingLineStartOffset = currentLineStartOffset(); int startingLineNumber = lineNumber(); T stringQuoteCharacter = m_current; shift(); const T* stringStart = currentSourcePtr(); while (m_current != stringQuoteCharacter) { if (UNLIKELY(m_current == '\\')) { if (stringStart != currentSourcePtr() && shouldBuildStrings) append8(stringStart, currentSourcePtr() - stringStart); shift(); LChar escape = singleEscape(m_current); // Most common escape sequences first. if (escape) { if (shouldBuildStrings) record8(escape); shift(); } else if (UNLIKELY(isLineTerminator(m_current))) shiftLineTerminator(); else if (m_current == 'x') { shift(); if (!isASCIIHexDigit(m_current) || !isASCIIHexDigit(peek(1))) { m_lexErrorMessage = ASCIILiteral("\\x can only be followed by a hex character sequence"); return (atEnd() || (isASCIIHexDigit(m_current) && (m_code + 1 == m_codeEnd))) ? StringUnterminated : StringCannotBeParsed; } T prev = m_current; shift(); if (shouldBuildStrings) record8(convertHex(prev, m_current)); shift(); } else { setOffset(startingOffset, startingLineStartOffset); setLineNumber(startingLineNumber); m_buffer8.shrink(0); return parseStringSlowCase(tokenData, strictMode); } stringStart = currentSourcePtr(); continue; } if (UNLIKELY(characterRequiresParseStringSlowCase(m_current))) { setOffset(startingOffset, startingLineStartOffset); setLineNumber(startingLineNumber); m_buffer8.shrink(0); return parseStringSlowCase(tokenData, strictMode); } shift(); } if (currentSourcePtr() != stringStart && shouldBuildStrings) append8(stringStart, currentSourcePtr() - stringStart); if (shouldBuildStrings) { tokenData->ident = makeIdentifier(m_buffer8.data(), m_buffer8.size()); m_buffer8.shrink(0); } else tokenData->ident = 0; return StringParsedSuccessfully; } template template ALWAYS_INLINE auto Lexer::parseComplexEscape(EscapeParseMode escapeParseMode, bool strictMode, T stringQuoteCharacter) -> StringParseResult { if (m_current == 'x') { shift(); if (!isASCIIHexDigit(m_current) || !isASCIIHexDigit(peek(1))) { m_lexErrorMessage = ASCIILiteral("\\x can only be followed by a hex character sequence"); return StringCannotBeParsed; } T prev = m_current; shift(); if (shouldBuildStrings) record16(convertHex(prev, m_current)); shift(); return StringParsedSuccessfully; } if (m_current == 'u') { shift(); if (escapeParseMode == EscapeParseMode::String && m_current == stringQuoteCharacter) { if (shouldBuildStrings) record16('u'); return StringParsedSuccessfully; } auto character = parseUnicodeEscape(); if (character.isValid()) { if (shouldBuildStrings) recordUnicodeCodePoint(character.value()); return StringParsedSuccessfully; } m_lexErrorMessage = ASCIILiteral("\\u can only be followed by a Unicode character sequence"); return character.isIncomplete() ? StringUnterminated : StringCannotBeParsed; } if (strictMode) { if (isASCIIDigit(m_current)) { // The only valid numeric escape in strict mode is '\0', and this must not be followed by a decimal digit. int character1 = m_current; shift(); if (character1 != '0' || isASCIIDigit(m_current)) { m_lexErrorMessage = ASCIILiteral("The only valid numeric escape in strict mode is '\\0'"); return StringCannotBeParsed; } if (shouldBuildStrings) record16(0); return StringParsedSuccessfully; } } else { if (isASCIIOctalDigit(m_current)) { // Octal character sequences T character1 = m_current; shift(); if (isASCIIOctalDigit(m_current)) { // Two octal characters T character2 = m_current; shift(); if (character1 >= '0' && character1 <= '3' && isASCIIOctalDigit(m_current)) { if (shouldBuildStrings) record16((character1 - '0') * 64 + (character2 - '0') * 8 + m_current - '0'); shift(); } else { if (shouldBuildStrings) record16((character1 - '0') * 8 + character2 - '0'); } } else { if (shouldBuildStrings) record16(character1 - '0'); } return StringParsedSuccessfully; } } if (!atEnd()) { if (shouldBuildStrings) record16(m_current); shift(); return StringParsedSuccessfully; } m_lexErrorMessage = ASCIILiteral("Unterminated string constant"); return StringUnterminated; } template template auto Lexer::parseStringSlowCase(JSTokenData* tokenData, bool strictMode) -> StringParseResult { T stringQuoteCharacter = m_current; shift(); const T* stringStart = currentSourcePtr(); while (m_current != stringQuoteCharacter) { if (UNLIKELY(m_current == '\\')) { if (stringStart != currentSourcePtr() && shouldBuildStrings) append16(stringStart, currentSourcePtr() - stringStart); shift(); LChar escape = singleEscape(m_current); // Most common escape sequences first if (escape) { if (shouldBuildStrings) record16(escape); shift(); } else if (UNLIKELY(isLineTerminator(m_current))) shiftLineTerminator(); else { StringParseResult result = parseComplexEscape(EscapeParseMode::String, strictMode, stringQuoteCharacter); if (result != StringParsedSuccessfully) return result; } stringStart = currentSourcePtr(); continue; } // Fast check for characters that require special handling. // Catches 0, \n, \r, 0x2028, and 0x2029 as efficiently // as possible, and lets through all common ASCII characters. if (UNLIKELY(((static_cast(m_current) - 0xE) & 0x2000))) { // New-line or end of input is not allowed if (atEnd() || isLineTerminator(m_current)) { m_lexErrorMessage = ASCIILiteral("Unexpected EOF"); return atEnd() ? StringUnterminated : StringCannotBeParsed; } // Anything else is just a normal character } shift(); } if (currentSourcePtr() != stringStart && shouldBuildStrings) append16(stringStart, currentSourcePtr() - stringStart); if (shouldBuildStrings) tokenData->ident = makeIdentifier(m_buffer16.data(), m_buffer16.size()); else tokenData->ident = 0; m_buffer16.shrink(0); return StringParsedSuccessfully; } // While the lexer accepts (not ) sequence // as one line terminator and increments one line number, // TemplateLiteral considers it as two line terminators and . // // TemplateLiteral normalizes line terminators as follows. // // => // => // => // <\u2028> => <\u2028> // <\u2029> => <\u2029> // // So, should be normalized to . // However, the lexer should increment the line number only once for . // // To achieve this, LineNumberAdder holds the current status of line terminator sequence. // When TemplateLiteral lexer encounters a line terminator, it notifies to LineNumberAdder. // LineNumberAdder maintains the status and increments the line number when it's necessary. // For example, LineNumberAdder increments the line number only once for and . template class LineNumberAdder { public: LineNumberAdder(int& lineNumber) : m_lineNumber(lineNumber) { } void clear() { m_previous = 0; } void add(CharacterType character) { ASSERT(Lexer::isLineTerminator(character)); if ((character + m_previous) == ('\n' + '\r')) m_previous = 0; else { ++m_lineNumber; m_previous = character; } } private: int& m_lineNumber; CharacterType m_previous { 0 }; }; template template typename Lexer::StringParseResult Lexer::parseTemplateLiteral(JSTokenData* tokenData, RawStringsBuildMode rawStringsBuildMode) { const T* stringStart = currentSourcePtr(); const T* rawStringStart = currentSourcePtr(); LineNumberAdder lineNumberAdder(m_lineNumber); while (m_current != '`') { if (UNLIKELY(m_current == '\\')) { lineNumberAdder.clear(); if (stringStart != currentSourcePtr() && shouldBuildStrings) append16(stringStart, currentSourcePtr() - stringStart); shift(); LChar escape = singleEscape(m_current); // Most common escape sequences first. if (escape) { if (shouldBuildStrings) record16(escape); shift(); } else if (UNLIKELY(isLineTerminator(m_current))) { if (m_current == '\r') { lineNumberAdder.add(m_current); shift(); if (m_current == '\n') { lineNumberAdder.add(m_current); shift(); } } else { lineNumberAdder.add(m_current); shift(); } } else { bool strictMode = true; StringParseResult result = parseComplexEscape(EscapeParseMode::Template, strictMode, '`'); if (result != StringParsedSuccessfully) return result; } stringStart = currentSourcePtr(); continue; } if (m_current == '$' && peek(1) == '{') break; // Fast check for characters that require special handling. // Catches 0, \n, \r, 0x2028, and 0x2029 as efficiently // as possible, and lets through all common ASCII characters. if (UNLIKELY(((static_cast(m_current) - 0xE) & 0x2000))) { // End of input is not allowed. // Unlike String, line terminator is allowed. if (atEnd()) { m_lexErrorMessage = ASCIILiteral("Unexpected EOF"); return atEnd() ? StringUnterminated : StringCannotBeParsed; } if (isLineTerminator(m_current)) { if (m_current == '\r') { // Normalize , to . if (shouldBuildStrings) { if (stringStart != currentSourcePtr()) append16(stringStart, currentSourcePtr() - stringStart); if (rawStringStart != currentSourcePtr() && rawStringsBuildMode == RawStringsBuildMode::BuildRawStrings) m_bufferForRawTemplateString16.append(rawStringStart, currentSourcePtr() - rawStringStart); record16('\n'); if (rawStringsBuildMode == RawStringsBuildMode::BuildRawStrings) m_bufferForRawTemplateString16.append('\n'); } lineNumberAdder.add(m_current); shift(); if (m_current == '\n') { lineNumberAdder.add(m_current); shift(); } stringStart = currentSourcePtr(); rawStringStart = currentSourcePtr(); } else { lineNumberAdder.add(m_current); shift(); } continue; } // Anything else is just a normal character } lineNumberAdder.clear(); shift(); } bool isTail = m_current == '`'; if (shouldBuildStrings) { if (currentSourcePtr() != stringStart) append16(stringStart, currentSourcePtr() - stringStart); if (rawStringStart != currentSourcePtr() && rawStringsBuildMode == RawStringsBuildMode::BuildRawStrings) m_bufferForRawTemplateString16.append(rawStringStart, currentSourcePtr() - rawStringStart); } if (shouldBuildStrings) { tokenData->cooked = makeIdentifier(m_buffer16.data(), m_buffer16.size()); // Line terminator normalization (e.g. => ) should be applied to both the raw and cooked representations. if (rawStringsBuildMode == RawStringsBuildMode::BuildRawStrings) tokenData->raw = makeIdentifier(m_bufferForRawTemplateString16.data(), m_bufferForRawTemplateString16.size()); else tokenData->raw = makeEmptyIdentifier(); } else { tokenData->cooked = makeEmptyIdentifier(); tokenData->raw = makeEmptyIdentifier(); } tokenData->isTail = isTail; m_buffer16.shrink(0); m_bufferForRawTemplateString16.shrink(0); if (isTail) { // Skip ` shift(); } else { // Skip $ and { shift(); shift(); } return StringParsedSuccessfully; } template ALWAYS_INLINE void Lexer::parseHex(double& returnValue) { // Optimization: most hexadecimal values fit into 4 bytes. uint32_t hexValue = 0; int maximumDigits = 7; do { hexValue = (hexValue << 4) + toASCIIHexValue(m_current); shift(); --maximumDigits; } while (isASCIIHexDigit(m_current) && maximumDigits >= 0); if (maximumDigits >= 0) { returnValue = hexValue; return; } // No more place in the hexValue buffer. // The values are shifted out and placed into the m_buffer8 vector. for (int i = 0; i < 8; ++i) { int digit = hexValue >> 28; if (digit < 10) record8(digit + '0'); else record8(digit - 10 + 'a'); hexValue <<= 4; } while (isASCIIHexDigit(m_current)) { record8(m_current); shift(); } returnValue = parseIntOverflow(m_buffer8.data(), m_buffer8.size(), 16); } template ALWAYS_INLINE bool Lexer::parseBinary(double& returnValue) { // Optimization: most binary values fit into 4 bytes. uint32_t binaryValue = 0; const unsigned maximumDigits = 32; int digit = maximumDigits - 1; // Temporary buffer for the digits. Makes easier // to reconstruct the input characters when needed. LChar digits[maximumDigits]; do { binaryValue = (binaryValue << 1) + (m_current - '0'); digits[digit] = m_current; shift(); --digit; } while (isASCIIBinaryDigit(m_current) && digit >= 0); if (!isASCIIDigit(m_current) && digit >= 0) { returnValue = binaryValue; return true; } for (int i = maximumDigits - 1; i > digit; --i) record8(digits[i]); while (isASCIIBinaryDigit(m_current)) { record8(m_current); shift(); } if (isASCIIDigit(m_current)) { returnValue = 0; return false; } returnValue = parseIntOverflow(m_buffer8.data(), m_buffer8.size(), 2); return true; } template ALWAYS_INLINE bool Lexer::parseOctal(double& returnValue) { // Optimization: most octal values fit into 4 bytes. uint32_t octalValue = 0; const unsigned maximumDigits = 10; int digit = maximumDigits - 1; // Temporary buffer for the digits. Makes easier // to reconstruct the input characters when needed. LChar digits[maximumDigits]; do { octalValue = octalValue * 8 + (m_current - '0'); digits[digit] = m_current; shift(); --digit; } while (isASCIIOctalDigit(m_current) && digit >= 0); if (!isASCIIDigit(m_current) && digit >= 0) { returnValue = octalValue; return true; } for (int i = maximumDigits - 1; i > digit; --i) record8(digits[i]); while (isASCIIOctalDigit(m_current)) { record8(m_current); shift(); } if (isASCIIDigit(m_current)) { returnValue = 0; return false; } returnValue = parseIntOverflow(m_buffer8.data(), m_buffer8.size(), 8); return true; } template ALWAYS_INLINE bool Lexer::parseDecimal(double& returnValue) { // Optimization: most decimal values fit into 4 bytes. uint32_t decimalValue = 0; // Since parseOctal may be executed before parseDecimal, // the m_buffer8 may hold ascii digits. if (!m_buffer8.size()) { const unsigned maximumDigits = 10; int digit = maximumDigits - 1; // Temporary buffer for the digits. Makes easier // to reconstruct the input characters when needed. LChar digits[maximumDigits]; do { decimalValue = decimalValue * 10 + (m_current - '0'); digits[digit] = m_current; shift(); --digit; } while (isASCIIDigit(m_current) && digit >= 0); if (digit >= 0 && m_current != '.' && (m_current | 0x20) != 'e') { returnValue = decimalValue; return true; } for (int i = maximumDigits - 1; i > digit; --i) record8(digits[i]); } while (isASCIIDigit(m_current)) { record8(m_current); shift(); } return false; } template ALWAYS_INLINE void Lexer::parseNumberAfterDecimalPoint() { record8('.'); while (isASCIIDigit(m_current)) { record8(m_current); shift(); } } template ALWAYS_INLINE bool Lexer::parseNumberAfterExponentIndicator() { record8('e'); shift(); if (m_current == '+' || m_current == '-') { record8(m_current); shift(); } if (!isASCIIDigit(m_current)) return false; do { record8(m_current); shift(); } while (isASCIIDigit(m_current)); return true; } template ALWAYS_INLINE bool Lexer::parseMultilineComment() { while (true) { while (UNLIKELY(m_current == '*')) { shift(); if (m_current == '/') { shift(); return true; } } if (atEnd()) return false; if (isLineTerminator(m_current)) { shiftLineTerminator(); m_terminator = true; } else shift(); } } template ALWAYS_INLINE void Lexer::parseCommentDirective() { // sourceURL and sourceMappingURL directives. if (!consume("source")) return; if (consume("URL=")) { m_sourceURLDirective = parseCommentDirectiveValue(); return; } if (consume("MappingURL=")) { m_sourceMappingURLDirective = parseCommentDirectiveValue(); return; } } template ALWAYS_INLINE String Lexer::parseCommentDirectiveValue() { skipWhitespace(); const T* stringStart = currentSourcePtr(); while (!isWhiteSpace(m_current) && !isLineTerminator(m_current) && m_current != '"' && m_current != '\'' && !atEnd()) shift(); const T* stringEnd = currentSourcePtr(); skipWhitespace(); if (!isLineTerminator(m_current) && !atEnd()) return String(); append8(stringStart, stringEnd - stringStart); String result = String(m_buffer8.data(), m_buffer8.size()); m_buffer8.shrink(0); return result; } template template ALWAYS_INLINE bool Lexer::consume(const char (&input)[length]) { unsigned lengthToCheck = length - 1; // Ignore the ending NULL byte in the string literal. unsigned i = 0; for (; i < lengthToCheck && m_current == input[i]; i++) shift(); return i == lengthToCheck; } template bool Lexer::nextTokenIsColon() { const T* code = m_code; while (code < m_codeEnd && (isWhiteSpace(*code) || isLineTerminator(*code))) code++; return code < m_codeEnd && *code == ':'; } template JSTokenType Lexer::lex(JSToken* tokenRecord, unsigned lexerFlags, bool strictMode) { JSTokenData* tokenData = &tokenRecord->m_data; JSTokenLocation* tokenLocation = &tokenRecord->m_location; m_lastTokenLocation = JSTokenLocation(tokenRecord->m_location); ASSERT(!m_error); ASSERT(m_buffer8.isEmpty()); ASSERT(m_buffer16.isEmpty()); JSTokenType token = ERRORTOK; m_terminator = false; start: skipWhitespace(); if (atEnd()) return EOFTOK; tokenLocation->startOffset = currentOffset(); ASSERT(currentOffset() >= currentLineStartOffset()); tokenRecord->m_startPosition = currentPosition(); CharacterType type; if (LIKELY(isLatin1(m_current))) type = static_cast(typesOfLatin1Characters[m_current]); else if (isNonLatin1IdentStart(m_current)) type = CharacterIdentifierStart; else if (isLineTerminator(m_current)) type = CharacterLineTerminator; else type = CharacterInvalid; switch (type) { case CharacterGreater: shift(); if (m_current == '>') { shift(); if (m_current == '>') { shift(); if (m_current == '=') { shift(); token = URSHIFTEQUAL; break; } token = URSHIFT; break; } if (m_current == '=') { shift(); token = RSHIFTEQUAL; break; } token = RSHIFT; break; } if (m_current == '=') { shift(); token = GE; break; } token = GT; break; case CharacterEqual: { if (peek(1) == '>') { token = ARROWFUNCTION; tokenData->line = lineNumber(); tokenData->offset = currentOffset(); tokenData->lineStartOffset = currentLineStartOffset(); ASSERT(tokenData->offset >= tokenData->lineStartOffset); shift(); shift(); break; } shift(); if (m_current == '=') { shift(); if (m_current == '=') { shift(); token = STREQ; break; } token = EQEQ; break; } token = EQUAL; break; } case CharacterLess: shift(); if (m_current == '!' && peek(1) == '-' && peek(2) == '-') { //