/* * Copyright (C) 1999-2002 Harri Porten (porten@kde.org) * Copyright (C) 2001 Peter Kelly (pmk@post.com) * Copyright (C) 2003, 2004, 2005, 2006, 2007, 2008, 2009 Apple Inc. All rights reserved. * Copyright (C) 2007 Cameron Zwarich (cwzwarich@uwaterloo.ca) * Copyright (C) 2007 Maks Orlovich * * 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 "JSGlobalObjectFunctions.h" #include "CallFrame.h" #include "Interpreter.h" #include "JSGlobalObject.h" #include "JSString.h" #include "JSStringBuilder.h" #include "Lexer.h" #include "LiteralParser.h" #include "Nodes.h" #include "Parser.h" #include "UStringBuilder.h" #include "dtoa.h" #include <stdio.h> #include <stdlib.h> #include <wtf/ASCIICType.h> #include <wtf/Assertions.h> #include <wtf/MathExtras.h> #include <wtf/StringExtras.h> #include <wtf/unicode/UTF8.h> using namespace WTF; using namespace Unicode; namespace JSC { static JSValue encode(ExecState* exec, const char* doNotEscape) { UString str = exec->argument(0).toString(exec); CString cstr = str.utf8(true); if (!cstr.data()) return throwError(exec, createURIError(exec, "String contained an illegal UTF-16 sequence.")); JSStringBuilder builder; const char* p = cstr.data(); for (size_t k = 0; k < cstr.length(); k++, p++) { char c = *p; if (c && strchr(doNotEscape, c)) builder.append(c); else { char tmp[4]; snprintf(tmp, sizeof(tmp), "%%%02X", static_cast<unsigned char>(c)); builder.append(tmp); } } return builder.build(exec); } static JSValue decode(ExecState* exec, const char* doNotUnescape, bool strict) { JSStringBuilder builder; UString str = exec->argument(0).toString(exec); int k = 0; int len = str.length(); const UChar* d = str.characters(); UChar u = 0; while (k < len) { const UChar* p = d + k; UChar c = *p; if (c == '%') { int charLen = 0; if (k <= len - 3 && isASCIIHexDigit(p[1]) && isASCIIHexDigit(p[2])) { const char b0 = Lexer::convertHex(p[1], p[2]); const int sequenceLen = UTF8SequenceLength(b0); if (sequenceLen != 0 && k <= len - sequenceLen * 3) { charLen = sequenceLen * 3; char sequence[5]; sequence[0] = b0; for (int i = 1; i < sequenceLen; ++i) { const UChar* q = p + i * 3; if (q[0] == '%' && isASCIIHexDigit(q[1]) && isASCIIHexDigit(q[2])) sequence[i] = Lexer::convertHex(q[1], q[2]); else { charLen = 0; break; } } if (charLen != 0) { sequence[sequenceLen] = 0; const int character = decodeUTF8Sequence(sequence); if (character < 0 || character >= 0x110000) charLen = 0; else if (character >= 0x10000) { // Convert to surrogate pair. builder.append(static_cast<UChar>(0xD800 | ((character - 0x10000) >> 10))); u = static_cast<UChar>(0xDC00 | ((character - 0x10000) & 0x3FF)); } else u = static_cast<UChar>(character); } } } if (charLen == 0) { if (strict) return throwError(exec, createURIError(exec, "URI error")); // The only case where we don't use "strict" mode is the "unescape" function. // For that, it's good to support the wonky "%u" syntax for compatibility with WinIE. if (k <= len - 6 && p[1] == 'u' && isASCIIHexDigit(p[2]) && isASCIIHexDigit(p[3]) && isASCIIHexDigit(p[4]) && isASCIIHexDigit(p[5])) { charLen = 6; u = Lexer::convertUnicode(p[2], p[3], p[4], p[5]); } } if (charLen && (u == 0 || u >= 128 || !strchr(doNotUnescape, u))) { c = u; k += charLen - 1; } } k++; builder.append(c); } return builder.build(exec); } bool isStrWhiteSpace(UChar c) { switch (c) { // ECMA-262-5th 7.2 & 7.3 case 0x0009: case 0x000A: case 0x000B: case 0x000C: case 0x000D: case 0x0020: case 0x00A0: case 0x2028: case 0x2029: case 0xFEFF: return true; default: return c > 0xff && isSeparatorSpace(c); } } static int parseDigit(unsigned short c, int radix) { int digit = -1; if (c >= '0' && c <= '9') digit = c - '0'; else if (c >= 'A' && c <= 'Z') digit = c - 'A' + 10; else if (c >= 'a' && c <= 'z') digit = c - 'a' + 10; if (digit >= radix) return -1; return digit; } double parseIntOverflow(const char* s, int length, int radix) { double number = 0.0; double radixMultiplier = 1.0; for (const char* p = s + length - 1; p >= s; p--) { if (radixMultiplier == Inf) { if (*p != '0') { number = Inf; break; } } else { int digit = parseDigit(*p, radix); number += digit * radixMultiplier; } radixMultiplier *= radix; } return number; } double parseIntOverflow(const UChar* s, int length, int radix) { double number = 0.0; double radixMultiplier = 1.0; for (const UChar* p = s + length - 1; p >= s; p--) { if (radixMultiplier == Inf) { if (*p != '0') { number = Inf; break; } } else { int digit = parseDigit(*p, radix); number += digit * radixMultiplier; } radixMultiplier *= radix; } return number; } static double parseInt(const UString& s, int radix) { int length = s.length(); const UChar* data = s.characters(); int p = 0; while (p < length && isStrWhiteSpace(data[p])) ++p; double sign = 1; if (p < length) { if (data[p] == '+') ++p; else if (data[p] == '-') { sign = -1; ++p; } } if ((radix == 0 || radix == 16) && length - p >= 2 && data[p] == '0' && (data[p + 1] == 'x' || data[p + 1] == 'X')) { radix = 16; p += 2; } else if (radix == 0) { if (p < length && data[p] == '0') radix = 8; else radix = 10; } if (radix < 2 || radix > 36) return NaN; int firstDigitPosition = p; bool sawDigit = false; double number = 0; while (p < length) { int digit = parseDigit(data[p], radix); if (digit == -1) break; sawDigit = true; number *= radix; number += digit; ++p; } if (number >= mantissaOverflowLowerBound) { if (radix == 10) number = WTF::strtod(s.substringSharingImpl(firstDigitPosition, p - firstDigitPosition).utf8().data(), 0); else if (radix == 2 || radix == 4 || radix == 8 || radix == 16 || radix == 32) number = parseIntOverflow(s.substringSharingImpl(firstDigitPosition, p - firstDigitPosition).utf8().data(), p - firstDigitPosition, radix); } if (!sawDigit) return NaN; return sign * number; } static const int SizeOfInfinity = 8; static bool isInfinity(const UChar* data, const UChar* end) { return (end - data) >= SizeOfInfinity && data[0] == 'I' && data[1] == 'n' && data[2] == 'f' && data[3] == 'i' && data[4] == 'n' && data[5] == 'i' && data[6] == 't' && data[7] == 'y'; } // See ecma-262 9.3.1 static double jsHexIntegerLiteral(const UChar*& data, const UChar* end) { // Hex number. data += 2; const UChar* firstDigitPosition = data; double number = 0; while (true) { number = number * 16 + toASCIIHexValue(*data); ++data; if (data == end) break; if (!isASCIIHexDigit(*data)) break; } if (number >= mantissaOverflowLowerBound) number = parseIntOverflow(firstDigitPosition, data - firstDigitPosition, 16); return number; } // See ecma-262 9.3.1 static double jsStrDecimalLiteral(const UChar*& data, const UChar* end) { ASSERT(data < end); // Copy the sting into a null-terminated byte buffer, and call strtod. Vector<char, 32> byteBuffer; for (const UChar* characters = data; characters < end; ++characters) { UChar character = *characters; byteBuffer.append(isASCII(character) ? character : 0); } byteBuffer.append(0); char* endOfNumber; double number = WTF::strtod(byteBuffer.data(), &endOfNumber); // Check if strtod found a number; if so return it. ptrdiff_t consumed = endOfNumber - byteBuffer.data(); if (consumed) { data += consumed; return number; } // Check for [+-]?Infinity switch (*data) { case 'I': if (isInfinity(data, end)) { data += SizeOfInfinity; return Inf; } break; case '+': if (isInfinity(data + 1, end)) { data += SizeOfInfinity + 1; return Inf; } break; case '-': if (isInfinity(data + 1, end)) { data += SizeOfInfinity + 1; return -Inf; } break; } // Not a number. return NaN; } // See ecma-262 9.3.1 double jsToNumber(const UString& s) { unsigned size = s.length(); if (size == 1) { UChar c = s.characters()[0]; if (isASCIIDigit(c)) return c - '0'; if (isStrWhiteSpace(c)) return 0; return NaN; } const UChar* data = s.characters(); const UChar* end = data + size; // Skip leading white space. for (; data < end; ++data) { if (!isStrWhiteSpace(*data)) break; } // Empty string. if (data == end) return 0.0; double number; if (data[0] == '0' && data + 2 < end && (data[1] | 0x20) == 'x' && isASCIIHexDigit(data[2])) number = jsHexIntegerLiteral(data, end); else number = jsStrDecimalLiteral(data, end); // Allow trailing white space. for (; data < end; ++data) { if (!isStrWhiteSpace(*data)) break; } if (data != end) return NaN; return number; } static double parseFloat(const UString& s) { unsigned size = s.length(); if (size == 1) { UChar c = s.characters()[0]; if (isASCIIDigit(c)) return c - '0'; return NaN; } const UChar* data = s.characters(); const UChar* end = data + size; // Skip leading white space. for (; data < end; ++data) { if (!isStrWhiteSpace(*data)) break; } // Empty string. if (data == end) return NaN; return jsStrDecimalLiteral(data, end); } EncodedJSValue JSC_HOST_CALL globalFuncEval(ExecState* exec) { JSObject* thisObject = exec->hostThisValue().toThisObject(exec); JSObject* unwrappedObject = thisObject->unwrappedObject(); if (!unwrappedObject->isGlobalObject() || static_cast<JSGlobalObject*>(unwrappedObject)->evalFunction() != exec->callee()) return throwVMError(exec, createEvalError(exec, "The \"this\" value passed to eval must be the global object from which eval originated")); JSValue x = exec->argument(0); if (!x.isString()) return JSValue::encode(x); UString s = x.toString(exec); LiteralParser preparser(exec, s, LiteralParser::NonStrictJSON); if (JSValue parsedObject = preparser.tryLiteralParse()) return JSValue::encode(parsedObject); EvalExecutable* eval = EvalExecutable::create(exec, makeSource(s), false); JSObject* error = eval->compile(exec, static_cast<JSGlobalObject*>(unwrappedObject)->globalScopeChain()); if (error) return throwVMError(exec, error); return JSValue::encode(exec->interpreter()->execute(eval, exec, thisObject, static_cast<JSGlobalObject*>(unwrappedObject)->globalScopeChain())); } EncodedJSValue JSC_HOST_CALL globalFuncParseInt(ExecState* exec) { JSValue value = exec->argument(0); int32_t radix = exec->argument(1).toInt32(exec); if (radix != 0 && radix != 10) return JSValue::encode(jsNumber(parseInt(value.toString(exec), radix))); if (value.isInt32()) return JSValue::encode(value); if (value.isDouble()) { double d = value.asDouble(); if (isfinite(d)) return JSValue::encode(jsNumber((d > 0) ? floor(d) : ceil(d))); if (isnan(d) || isinf(d)) return JSValue::encode(jsNaN()); return JSValue::encode(jsNumber(0)); } return JSValue::encode(jsNumber(parseInt(value.toString(exec), radix))); } EncodedJSValue JSC_HOST_CALL globalFuncParseFloat(ExecState* exec) { return JSValue::encode(jsNumber(parseFloat(exec->argument(0).toString(exec)))); } EncodedJSValue JSC_HOST_CALL globalFuncIsNaN(ExecState* exec) { return JSValue::encode(jsBoolean(isnan(exec->argument(0).toNumber(exec)))); } EncodedJSValue JSC_HOST_CALL globalFuncIsFinite(ExecState* exec) { double n = exec->argument(0).toNumber(exec); return JSValue::encode(jsBoolean(!isnan(n) && !isinf(n))); } EncodedJSValue JSC_HOST_CALL globalFuncDecodeURI(ExecState* exec) { static const char do_not_unescape_when_decoding_URI[] = "#$&+,/:;=?@"; return JSValue::encode(decode(exec, do_not_unescape_when_decoding_URI, true)); } EncodedJSValue JSC_HOST_CALL globalFuncDecodeURIComponent(ExecState* exec) { return JSValue::encode(decode(exec, "", true)); } EncodedJSValue JSC_HOST_CALL globalFuncEncodeURI(ExecState* exec) { static const char do_not_escape_when_encoding_URI[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" "abcdefghijklmnopqrstuvwxyz" "0123456789" "!#$&'()*+,-./:;=?@_~"; return JSValue::encode(encode(exec, do_not_escape_when_encoding_URI)); } EncodedJSValue JSC_HOST_CALL globalFuncEncodeURIComponent(ExecState* exec) { static const char do_not_escape_when_encoding_URI_component[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" "abcdefghijklmnopqrstuvwxyz" "0123456789" "!'()*-._~"; return JSValue::encode(encode(exec, do_not_escape_when_encoding_URI_component)); } EncodedJSValue JSC_HOST_CALL globalFuncEscape(ExecState* exec) { static const char do_not_escape[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" "abcdefghijklmnopqrstuvwxyz" "0123456789" "*+-./@_"; JSStringBuilder builder; UString str = exec->argument(0).toString(exec); const UChar* c = str.characters(); for (unsigned k = 0; k < str.length(); k++, c++) { int u = c[0]; if (u > 255) { char tmp[7]; snprintf(tmp, sizeof(tmp), "%%u%04X", u); builder.append(tmp); } else if (u != 0 && strchr(do_not_escape, static_cast<char>(u))) builder.append(c, 1); else { char tmp[4]; snprintf(tmp, sizeof(tmp), "%%%02X", u); builder.append(tmp); } } return JSValue::encode(builder.build(exec)); } EncodedJSValue JSC_HOST_CALL globalFuncUnescape(ExecState* exec) { UStringBuilder builder; UString str = exec->argument(0).toString(exec); int k = 0; int len = str.length(); while (k < len) { const UChar* c = str.characters() + k; UChar u; if (c[0] == '%' && k <= len - 6 && c[1] == 'u') { if (isASCIIHexDigit(c[2]) && isASCIIHexDigit(c[3]) && isASCIIHexDigit(c[4]) && isASCIIHexDigit(c[5])) { u = Lexer::convertUnicode(c[2], c[3], c[4], c[5]); c = &u; k += 5; } } else if (c[0] == '%' && k <= len - 3 && isASCIIHexDigit(c[1]) && isASCIIHexDigit(c[2])) { u = UChar(Lexer::convertHex(c[1], c[2])); c = &u; k += 2; } k++; builder.append(*c); } return JSValue::encode(jsString(exec, builder.toUString())); } #ifndef NDEBUG EncodedJSValue JSC_HOST_CALL globalFuncJSCPrint(ExecState* exec) { CString string = exec->argument(0).toString(exec).utf8(); puts(string.data()); return JSValue::encode(jsUndefined()); } #endif } // namespace JSC