/* * This file is part of the KDE libraries * Copyright (C) 1999-2000 Harri Porten (porten@kde.org) * * 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. * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include "value.h" #include "object.h" #include "types.h" #include "interpreter.h" #include "nodes.h" #include "lexer.h" #include "identifier.h" #include "lookup.h" #include "internal.h" #include "dtoa.h" // we can't specify the namespace in yacc's C output, so do it here using namespace KJS; static Lexer *currLexer = 0; #ifndef KDE_USE_FINAL #include "grammar.h" #endif #include "lexer.lut.h" extern YYLTYPE yylloc; // global bison variable holding token info // a bridge for yacc from the C world to C++ int kjsyylex() { return Lexer::curr()->lex(); } Lexer::Lexer() : yylineno(1), size8(128), size16(128), restrKeyword(false), convertNextIdentifier(false), stackToken(-1), lastToken(-1), pos(0), code(0), length(0), #ifndef KJS_PURE_ECMA bol(true), #endif current(0), next1(0), next2(0), next3(0), strings(0), numStrings(0), stringsCapacity(0), identifiers(0), numIdentifiers(0), identifiersCapacity(0) { // allocate space for read buffers buffer8 = new char[size8]; buffer16 = new UChar[size16]; currLexer = this; } Lexer::~Lexer() { delete [] buffer8; delete [] buffer16; } Lexer *Lexer::curr() { if (!currLexer) { // create singleton instance currLexer = new Lexer(); } return currLexer; } #ifdef KJS_DEBUG_MEM void Lexer::globalClear() { delete currLexer; currLexer = 0L; } #endif void Lexer::setCode(const UChar *c, unsigned int len) { yylineno = 1; restrKeyword = false; delimited = false; convertNextIdentifier = false; stackToken = -1; lastToken = -1; foundBad = false; pos = 0; code = c; length = len; skipLF = false; skipCR = false; #ifndef KJS_PURE_ECMA bol = true; #endif // read first characters current = (length > 0) ? code[0].uc : -1; next1 = (length > 1) ? code[1].uc : -1; next2 = (length > 2) ? code[2].uc : -1; next3 = (length > 3) ? code[3].uc : -1; } void Lexer::shift(unsigned int p) { while (p--) { pos++; current = next1; next1 = next2; next2 = next3; next3 = (pos + 3 < length) ? code[pos+3].uc : -1; } } // called on each new line void Lexer::nextLine() { yylineno++; #ifndef KJS_PURE_ECMA bol = true; #endif } void Lexer::setDone(State s) { state = s; done = true; } int Lexer::lex() { int token = 0; state = Start; unsigned short stringType = 0; // either single or double quotes pos8 = pos16 = 0; done = false; terminator = false; skipLF = false; skipCR = false; // did we push a token on the stack previously ? // (after an automatic semicolon insertion) if (stackToken >= 0) { setDone(Other); token = stackToken; stackToken = 0; } while (!done) { if (skipLF && current != '\n') // found \r but not \n afterwards skipLF = false; if (skipCR && current != '\r') // found \n but not \r afterwards skipCR = false; if (skipLF || skipCR) // found \r\n or \n\r -> eat the second one { skipLF = false; skipCR = false; shift(1); } bool cr = (current == '\r'); bool lf = (current == '\n'); if (cr) skipLF = true; else if (lf) skipCR = true; bool isLineTerminator = cr || lf; switch (state) { case Start: if (isWhiteSpace(current)) { // do nothing } else if (current == '/' && next1 == '/') { shift(1); state = InSingleLineComment; } else if (current == '/' && next1 == '*') { shift(1); state = InMultiLineComment; } else if (current == -1) { if (!terminator && !delimited) { // automatic semicolon insertion if program incomplete token = ';'; stackToken = 0; setDone(Other); } else setDone(Eof); } else if (isLineTerminator) { nextLine(); terminator = true; if (restrKeyword) { token = ';'; setDone(Other); } } else if (current == '"' || current == '\'') { state = InString; stringType = current; } else if (isIdentLetter(current)) { record16(current); state = InIdentifierOrKeyword; } else if (current == '\\') { state = InIdentifierUnicodeEscapeStart; } else if (current == '0') { record8(current); state = InNum0; } else if (isDecimalDigit(current)) { record8(current); state = InNum; } else if (current == '.' && isDecimalDigit(next1)) { record8(current); state = InDecimal; #ifndef KJS_PURE_ECMA // } else if (bol && current == '-' && next1 == '-' && next2 == '>') { shift(2); state = InSingleLineComment; #endif } else { token = matchPunctuator(current, next1, next2, next3); if (token != -1) { setDone(Other); } else { // cerr << "encountered unknown character" << endl; setDone(Bad); } } break; case InString: if (current == stringType) { shift(1); setDone(String); } else if (current == -1 || isLineTerminator) { setDone(Bad); } else if (current == '\\') { state = InEscapeSequence; } else { record16(current); } break; // Escape Sequences inside of strings case InEscapeSequence: if (isOctalDigit(current)) { if (current >= '0' && current <= '3' && isOctalDigit(next1) && isOctalDigit(next2)) { record16(convertOctal(current, next1, next2)); shift(2); state = InString; } else if (isOctalDigit(current) && isOctalDigit(next1)) { record16(convertOctal('0', current, next1)); shift(1); state = InString; } else if (isOctalDigit(current)) { record16(convertOctal('0', '0', current)); state = InString; } else { setDone(Bad); } } else if (current == 'x') state = InHexEscape; else if (current == 'u') state = InUnicodeEscape; else { if (isLineTerminator) nextLine(); record16(singleEscape(current)); state = InString; } break; case InHexEscape: if (isHexDigit(current) && isHexDigit(next1)) { state = InString; record16(convertHex(current, next1)); shift(1); } else if (current == stringType) { record16('x'); shift(1); setDone(String); } else { record16('x'); record16(current); state = InString; } break; case InUnicodeEscape: if (isHexDigit(current) && isHexDigit(next1) && isHexDigit(next2) && isHexDigit(next3)) { record16(convertUnicode(current, next1, next2, next3)); shift(3); state = InString; } else if (current == stringType) { record16('u'); shift(1); setDone(String); } else { setDone(Bad); } break; case InSingleLineComment: if (isLineTerminator) { nextLine(); terminator = true; if (restrKeyword) { token = ';'; setDone(Other); } else state = Start; } else if (current == -1) { setDone(Eof); } break; case InMultiLineComment: if (current == -1) { setDone(Bad); } else if (isLineTerminator) { nextLine(); } else if (current == '*' && next1 == '/') { state = Start; shift(1); } break; case InIdentifierOrKeyword: case InIdentifier: if (isIdentLetter(current) || isDecimalDigit(current)) record16(current); else if (current == '\\') state = InIdentifierUnicodeEscapeStart; else setDone(state == InIdentifierOrKeyword ? IdentifierOrKeyword : Identifier); break; case InNum0: if (current == 'x' || current == 'X') { record8(current); state = InHex; } else if (current == '.') { record8(current); state = InDecimal; } else if (current == 'e' || current == 'E') { record8(current); state = InExponentIndicator; } else if (isOctalDigit(current)) { record8(current); state = InOctal; } else if (isDecimalDigit(current)) { record8(current); state = InDecimal; } else { setDone(Number); } break; case InHex: if (isHexDigit(current)) { record8(current); } else { setDone(Hex); } break; case InOctal: if (isOctalDigit(current)) { record8(current); } else if (isDecimalDigit(current)) { record8(current); state = InDecimal; } else setDone(Octal); break; case InNum: if (isDecimalDigit(current)) { record8(current); } else if (current == '.') { record8(current); state = InDecimal; } else if (current == 'e' || current == 'E') { record8(current); state = InExponentIndicator; } else setDone(Number); break; case InDecimal: if (isDecimalDigit(current)) { record8(current); } else if (current == 'e' || current == 'E') { record8(current); state = InExponentIndicator; } else setDone(Number); break; case InExponentIndicator: if (current == '+' || current == '-') { record8(current); } else if (isDecimalDigit(current)) { record8(current); state = InExponent; } else setDone(Bad); break; case InExponent: if (isDecimalDigit(current)) { record8(current); } else setDone(Number); break; case InIdentifierUnicodeEscapeStart: if (current == 'u') state = InIdentifierUnicodeEscape; else setDone(Bad); break; case InIdentifierUnicodeEscape: if (isHexDigit(current) && isHexDigit(next1) && isHexDigit(next2) && isHexDigit(next3)) { record16(convertUnicode(current, next1, next2, next3)); shift(3); state = InIdentifier; } else { setDone(Bad); } break; default: assert(!"Unhandled state in switch statement"); } // move on to the next character if (!done) shift(1); #ifndef KJS_PURE_ECMA if (state != Start && state != InSingleLineComment) bol = false; #endif } // no identifiers allowed directly after numeric literal, e.g. "3in" is bad if ((state == Number || state == Octal || state == Hex) && isIdentLetter(current)) state = Bad; // terminate string buffer8[pos8] = '\0'; #ifdef KJS_DEBUG_LEX fprintf(stderr, "line: %d ", lineNo()); fprintf(stderr, "yytext (%x): ", buffer8[0]); fprintf(stderr, "%s ", buffer8); #endif long double dval = 0; if (state == Number) { dval = kjs_strtod(buffer8, 0L); } else if (state == Hex) { // scan hex numbers dval = 0; if (buffer8[0] == '0' && (buffer8[1] == 'x' || buffer8[1] == 'X')) { for (const char *p = buffer8+2; *p; p++) { if (!isHexDigit(*p)) { dval = 0; break; } dval = dval * 16 + convertHex(*p); } } state = Number; } else if (state == Octal) { // scan octal number dval = 0; if (buffer8[0] == '0') { for (const char *p = buffer8+1; *p; p++) { if (*p < '0' || *p > '7') { dval = 0; break; } dval = dval * 8 + *p - '0'; } } state = Number; } #ifdef KJS_DEBUG_LEX switch (state) { case Eof: printf("(EOF)\n"); break; case Other: printf("(Other)\n"); break; case Identifier: case IdentifierOrKeyword: printf("(Identifier)/(Keyword)\n"); break; case String: printf("(String)\n"); break; case Number: printf("(Number)\n"); break; default: printf("(unknown)"); } #endif if (state != Identifier && state != IdentifierOrKeyword && convertNextIdentifier) convertNextIdentifier = false; restrKeyword = false; delimited = false; kjsyylloc.first_line = yylineno; // ??? kjsyylloc.last_line = yylineno; switch (state) { case Eof: token = 0; break; case Other: if(token == '}' || token == ';') { delimited = true; } break; case IdentifierOrKeyword: if ((token = Lookup::find(&mainTable, buffer16, pos16)) < 0) { case Identifier: // Lookup for keyword failed, means this is an identifier // Apply anonymous-function hack below (convert the identifier) if (convertNextIdentifier) { convertNextIdentifier = false; #ifdef KJS_VERBOSE UString debugstr(buffer16, pos16); fprintf(stderr,"Anonymous function hack: eating identifier %s\n",debugstr.ascii()); #endif token = FUNCEXPRIDENT; } else { token = IDENT; } /* TODO: close leak on parse error. same holds true for String */ kjsyylval.ident = makeIdentifier(buffer16, pos16); break; } convertNextIdentifier = false; // Hack for "f = function somename() { ... }", too hard to get into the grammar // Same for building an array with function pointers ( 'name', func1, 'name2', func2 ) // There are lots of other uses, we really have to get this into the grammar if ( token == FUNCTION && ( lastToken == '=' || lastToken == ',' || lastToken == '(' || lastToken == ':' || lastToken == RETURN ) ) convertNextIdentifier = true; if (token == CONTINUE || token == BREAK || token == RETURN || token == THROW) restrKeyword = true; break; case String: kjsyylval.ustr = makeUString(buffer16, pos16); token = STRING; break; case Number: kjsyylval.dval = dval; token = NUMBER; break; case Bad: foundBad = true; return -1; default: assert(!"unhandled numeration value in switch"); return -1; } lastToken = token; return token; } bool Lexer::isWhiteSpace(unsigned short c) { return (c == ' ' || c == '\t' || c == 0x0b || c == 0x0c || c == 0xa0); } bool Lexer::isIdentLetter(unsigned short c) { // Allow any character in the Unicode categories // Uppercase letter (Lu), Lowercase letter (Ll), // Titlecase letter (Lt)", Modifier letter (Lm), // Other letter (Lo), or Letter number (Nl). // Also see: http://www.unicode.org/Public/UNIDATA/UnicodeData.txt */ return (c >= 'a' && c <= 'z' || c >= 'A' && c <= 'Z' || // A with grave - O with diaeresis c >= 0x00c0 && c <= 0x00d6 || // O with stroke - o with diaeresis c >= 0x00d8 && c <= 0x00f6 || // o with stroke - turned h with fishook and tail c >= 0x00f8 && c <= 0x02af || // Greek etc. TODO: not precise c >= 0x0388 && c <= 0x1ffc || c == '$' || c == '_'); /* TODO: use complete category table */ } bool Lexer::isDecimalDigit(unsigned short c) { return (c >= '0' && c <= '9'); } bool Lexer::isHexDigit(unsigned short c) { return (c >= '0' && c <= '9' || c >= 'a' && c <= 'f' || c >= 'A' && c <= 'F'); } bool Lexer::isOctalDigit(unsigned short c) { return (c >= '0' && c <= '7'); } int Lexer::matchPunctuator(unsigned short c1, unsigned short c2, unsigned short c3, unsigned short c4) { if (c1 == '>' && c2 == '>' && c3 == '>' && c4 == '=') { shift(4); return URSHIFTEQUAL; } else if (c1 == '=' && c2 == '=' && c3 == '=') { shift(3); return STREQ; } else if (c1 == '!' && c2 == '=' && c3 == '=') { shift(3); return STRNEQ; } else if (c1 == '>' && c2 == '>' && c3 == '>') { shift(3); return URSHIFT; } else if (c1 == '<' && c2 == '<' && c3 == '=') { shift(3); return LSHIFTEQUAL; } else if (c1 == '>' && c2 == '>' && c3 == '=') { shift(3); return RSHIFTEQUAL; } else if (c1 == '<' && c2 == '=') { shift(2); return LE; } else if (c1 == '>' && c2 == '=') { shift(2); return GE; } else if (c1 == '!' && c2 == '=') { shift(2); return NE; } else if (c1 == '+' && c2 == '+') { shift(2); if (terminator) return AUTOPLUSPLUS; else return PLUSPLUS; } else if (c1 == '-' && c2 == '-') { shift(2); if (terminator) return AUTOMINUSMINUS; else return MINUSMINUS; } else if (c1 == '=' && c2 == '=') { shift(2); return EQEQ; } else if (c1 == '+' && c2 == '=') { shift(2); return PLUSEQUAL; } else if (c1 == '-' && c2 == '=') { shift(2); return MINUSEQUAL; } else if (c1 == '*' && c2 == '=') { shift(2); return MULTEQUAL; } else if (c1 == '/' && c2 == '=') { shift(2); return DIVEQUAL; } else if (c1 == '&' && c2 == '=') { shift(2); return ANDEQUAL; } else if (c1 == '^' && c2 == '=') { shift(2); return XOREQUAL; } else if (c1 == '%' && c2 == '=') { shift(2); return MODEQUAL; } else if (c1 == '|' && c2 == '=') { shift(2); return OREQUAL; } else if (c1 == '<' && c2 == '<') { shift(2); return LSHIFT; } else if (c1 == '>' && c2 == '>') { shift(2); return RSHIFT; } else if (c1 == '&' && c2 == '&') { shift(2); return AND; } else if (c1 == '|' && c2 == '|') { shift(2); return OR; } switch(c1) { case '=': case '>': case '<': case ',': case '!': case '~': case '?': case ':': case '.': case '+': case '-': case '*': case '/': case '&': case '|': case '^': case '%': case '(': case ')': case '{': case '}': case '[': case ']': case ';': shift(1); return static_cast(c1); default: return -1; } } unsigned short Lexer::singleEscape(unsigned short c) const { switch(c) { case 'b': return 0x08; case 't': return 0x09; case 'n': return 0x0A; case 'v': return 0x0B; case 'f': return 0x0C; case 'r': return 0x0D; case '"': return 0x22; case '\'': return 0x27; case '\\': return 0x5C; default: return c; } } unsigned short Lexer::convertOctal(unsigned short c1, unsigned short c2, unsigned short c3) const { return ((c1 - '0') * 64 + (c2 - '0') * 8 + c3 - '0'); } unsigned char Lexer::convertHex(unsigned short c) { if (c >= '0' && c <= '9') return (c - '0'); else if (c >= 'a' && c <= 'f') return (c - 'a' + 10); else return (c - 'A' + 10); } unsigned char Lexer::convertHex(unsigned short c1, unsigned short c2) { return ((convertHex(c1) << 4) + convertHex(c2)); } UChar Lexer::convertUnicode(unsigned short c1, unsigned short c2, unsigned short c3, unsigned short c4) { return UChar((convertHex(c1) << 4) + convertHex(c2), (convertHex(c3) << 4) + convertHex(c4)); } void Lexer::record8(unsigned short c) { assert(c <= 0xff); // enlarge buffer if full if (pos8 >= size8 - 1) { char *tmp = new char[2 * size8]; memcpy(tmp, buffer8, size8 * sizeof(char)); delete [] buffer8; buffer8 = tmp; size8 *= 2; } buffer8[pos8++] = (char) c; } void Lexer::record16(int c) { assert(c >= 0); //assert(c <= USHRT_MAX); record16(UChar(static_cast(c))); } void Lexer::record16(UChar c) { // enlarge buffer if full if (pos16 >= size16 - 1) { UChar *tmp = new UChar[2 * size16]; memcpy(tmp, buffer16, size16 * sizeof(UChar)); delete [] buffer16; buffer16 = tmp; size16 *= 2; } buffer16[pos16++] = c; } bool Lexer::scanRegExp() { pos16 = 0; bool lastWasEscape = false; bool inBrackets = false; while (1) { if (current == '\r' || current == '\n' || current == -1) return false; else if (current != '/' || lastWasEscape == true || inBrackets == true) { // keep track of '[' and ']' if ( !lastWasEscape ) { if ( current == '[' && !inBrackets ) inBrackets = true; if ( current == ']' && inBrackets ) inBrackets = false; } record16(current); lastWasEscape = !lastWasEscape && (current == '\\'); } else { // end of regexp pattern = UString(buffer16, pos16); pos16 = 0; shift(1); break; } shift(1); } while (isIdentLetter(current)) { record16(current); shift(1); } flags = UString(buffer16, pos16); return true; } void Lexer::doneParsing() { for (unsigned i = 0; i < numIdentifiers; i++) { delete identifiers[i]; } free(identifiers); identifiers = 0; numIdentifiers = 0; identifiersCapacity = 0; for (unsigned i = 0; i < numStrings; i++) { delete strings[i]; } free(strings); strings = 0; numStrings = 0; stringsCapacity = 0; } const int initialCapacity = 64; const int growthFactor = 2; Identifier *Lexer::makeIdentifier(UChar *buffer, unsigned int pos) { if (numIdentifiers == identifiersCapacity) { identifiersCapacity = (identifiersCapacity == 0) ? initialCapacity : identifiersCapacity *growthFactor; identifiers = (KJS::Identifier **)realloc(identifiers, sizeof(KJS::Identifier *) * identifiersCapacity); } KJS::Identifier *identifier = new KJS::Identifier(buffer, pos); identifiers[numIdentifiers++] = identifier; return identifier; } UString *Lexer::makeUString(UChar *buffer, unsigned int pos) { if (numStrings == stringsCapacity) { stringsCapacity = (stringsCapacity == 0) ? initialCapacity : stringsCapacity *growthFactor; strings = (UString **)realloc(strings, sizeof(UString *) * stringsCapacity); } UString *string = new UString(buffer, pos); strings[numStrings++] = string; return string; }