/* Copyright (C) 1999 Lars Knoll (knoll@mpi-hd.mpg.de) Copyright (C) 2003, 2004, 2005, 2006, 2007, 2008 Apple Inc. All rights reserved. Copyright (C) 2005, 2006, 2007 Alexey Proskuryakov (ap@nypop.com) 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 "TextResourceDecoder.h" #include "DOMImplementation.h" #include "HTMLNames.h" #include "TextCodec.h" #include <wtf/ASCIICType.h> #include <wtf/StringExtras.h> using namespace WTF; namespace WebCore { using namespace HTMLNames; // You might think we should put these find functions elsewhere, perhaps with the // similar functions that operate on UChar, but arguably only the decoder has // a reason to process strings of char rather than UChar. static int find(const char* subject, size_t subjectLength, const char* target) { size_t targetLength = strlen(target); if (targetLength > subjectLength) return -1; for (size_t i = 0; i <= subjectLength - targetLength; ++i) { bool match = true; for (size_t j = 0; j < targetLength; ++j) { if (subject[i + j] != target[j]) { match = false; break; } } if (match) return i; } return -1; } static int findIgnoringCase(const char* subject, size_t subjectLength, const char* target) { size_t targetLength = strlen(target); if (targetLength > subjectLength) return -1; #ifndef NDEBUG for (size_t i = 0; i < targetLength; ++i) ASSERT(isASCIILower(target[i])); #endif for (size_t i = 0; i <= subjectLength - targetLength; ++i) { bool match = true; for (size_t j = 0; j < targetLength; ++j) { if (toASCIILower(subject[i + j]) != target[j]) { match = false; break; } } if (match) return i; } return -1; } static TextEncoding findTextEncoding(const char* encodingName, int length) { Vector<char, 64> buffer(length + 1); memcpy(buffer.data(), encodingName, length); buffer[length] = '\0'; return buffer.data(); } class KanjiCode { public: enum Type { ASCII, JIS, EUC, SJIS, UTF16, UTF8 }; static enum Type judge(const char* str, int length); static const int ESC = 0x1b; static const unsigned char sjisMap[256]; static int ISkanji(int code) { if (code >= 0x100) return 0; return sjisMap[code & 0xff] & 1; } static int ISkana(int code) { if (code >= 0x100) return 0; return sjisMap[code & 0xff] & 2; } }; const unsigned char KanjiCode::sjisMap[256] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0 }; /* * EUC-JP is * [0xa1 - 0xfe][0xa1 - 0xfe] * 0x8e[0xa1 - 0xfe](SS2) * 0x8f[0xa1 - 0xfe][0xa1 - 0xfe](SS3) * * Shift_Jis is * [0x81 - 0x9f, 0xe0 - 0xef(0xfe?)][0x40 - 0x7e, 0x80 - 0xfc] * * Shift_Jis Hankaku Kana is * [0xa1 - 0xdf] */ /* * KanjiCode::judge() is based on judge_jcode() from jvim * http://hp.vector.co.jp/authors/VA003457/vim/ * * Special Thanks to Kenichi Tsuchida */ enum KanjiCode::Type KanjiCode::judge(const char* str, int size) { enum Type code; int i; int bfr = false; /* Kana Moji */ int bfk = 0; /* EUC Kana */ int sjis = 0; int euc = 0; const unsigned char* ptr = reinterpret_cast<const unsigned char*>(str); code = ASCII; i = 0; while (i < size) { if (ptr[i] == ESC && (size - i >= 3)) { if ((ptr[i + 1] == '$' && ptr[i + 2] == 'B') || (ptr[i + 1] == '(' && ptr[i + 2] == 'B')) { code = JIS; goto breakBreak; } else if ((ptr[i + 1] == '$' && ptr[i + 2] == '@') || (ptr[i + 1] == '(' && ptr[i + 2] == 'J')) { code = JIS; goto breakBreak; } else if (ptr[i + 1] == '(' && ptr[i + 2] == 'I') { code = JIS; i += 3; } else if (ptr[i + 1] == ')' && ptr[i + 2] == 'I') { code = JIS; i += 3; } else { i++; } bfr = false; bfk = 0; } else { if (ptr[i] < 0x20) { bfr = false; bfk = 0; /* ?? check kudokuten ?? && ?? hiragana ?? */ if ((i >= 2) && (ptr[i - 2] == 0x81) && (0x41 <= ptr[i - 1] && ptr[i - 1] <= 0x49)) { code = SJIS; sjis += 100; /* kudokuten */ } else if ((i >= 2) && (ptr[i - 2] == 0xa1) && (0xa2 <= ptr[i - 1] && ptr[i - 1] <= 0xaa)) { code = EUC; euc += 100; /* kudokuten */ } else if ((i >= 2) && (ptr[i - 2] == 0x82) && (0xa0 <= ptr[i - 1])) { sjis += 40; /* hiragana */ } else if ((i >= 2) && (ptr[i - 2] == 0xa4) && (0xa0 <= ptr[i - 1])) { euc += 40; /* hiragana */ } } else { /* ?? check hiragana or katana ?? */ if ((size - i > 1) && (ptr[i] == 0x82) && (0xa0 <= ptr[i + 1])) { sjis++; /* hiragana */ } else if ((size - i > 1) && (ptr[i] == 0x83) && (0x40 <= ptr[i + 1] && ptr[i + 1] <= 0x9f)) { sjis++; /* katakana */ } else if ((size - i > 1) && (ptr[i] == 0xa4) && (0xa0 <= ptr[i + 1])) { euc++; /* hiragana */ } else if ((size - i > 1) && (ptr[i] == 0xa5) && (0xa0 <= ptr[i + 1])) { euc++; /* katakana */ } if (bfr) { if ((i >= 1) && (0x40 <= ptr[i] && ptr[i] <= 0xa0) && ISkanji(ptr[i - 1])) { code = SJIS; goto breakBreak; } else if ((i >= 1) && (0x81 <= ptr[i - 1] && ptr[i - 1] <= 0x9f) && ((0x40 <= ptr[i] && ptr[i] < 0x7e) || (0x7e < ptr[i] && ptr[i] <= 0xfc))) { code = SJIS; goto breakBreak; } else if ((i >= 1) && (0xfd <= ptr[i] && ptr[i] <= 0xfe) && (0xa1 <= ptr[i - 1] && ptr[i - 1] <= 0xfe)) { code = EUC; goto breakBreak; } else if ((i >= 1) && (0xfd <= ptr[i - 1] && ptr[i - 1] <= 0xfe) && (0xa1 <= ptr[i] && ptr[i] <= 0xfe)) { code = EUC; goto breakBreak; } else if ((i >= 1) && (ptr[i] < 0xa0 || 0xdf < ptr[i]) && (0x8e == ptr[i - 1])) { code = SJIS; goto breakBreak; } else if (ptr[i] <= 0x7f) { code = SJIS; goto breakBreak; } else { if (0xa1 <= ptr[i] && ptr[i] <= 0xa6) { euc++; /* sjis hankaku kana kigo */ } else if (0xa1 <= ptr[i] && ptr[i] <= 0xdf) { ; /* sjis hankaku kana */ } else if (0xa1 <= ptr[i] && ptr[i] <= 0xfe) { euc++; } else if (0x8e == ptr[i]) { euc++; } else if (0x20 <= ptr[i] && ptr[i] <= 0x7f) { sjis++; } bfr = false; bfk = 0; } } else if (0x8e == ptr[i]) { if (size - i <= 1) { ; } else if (0xa1 <= ptr[i + 1] && ptr[i + 1] <= 0xdf) { /* EUC KANA or SJIS KANJI */ if (bfk == 1) { euc += 100; } bfk++; i++; } else { /* SJIS only */ code = SJIS; goto breakBreak; } } else if (0x81 <= ptr[i] && ptr[i] <= 0x9f) { /* SJIS only */ code = SJIS; if ((size - i >= 1) && ((0x40 <= ptr[i + 1] && ptr[i + 1] <= 0x7e) || (0x80 <= ptr[i + 1] && ptr[i + 1] <= 0xfc))) { goto breakBreak; } } else if (0xfd <= ptr[i] && ptr[i] <= 0xfe) { /* EUC only */ code = EUC; if ((size - i >= 1) && (0xa1 <= ptr[i + 1] && ptr[i + 1] <= 0xfe)) { goto breakBreak; } } else if (ptr[i] <= 0x7f) { ; } else { bfr = true; bfk = 0; } } i++; } } if (code == ASCII) { if (sjis > euc) { code = SJIS; } else if (sjis < euc) { code = EUC; } } breakBreak: return (code); } TextResourceDecoder::ContentType TextResourceDecoder::determineContentType(const String& mimeType) { if (equalIgnoringCase(mimeType, "text/css")) return CSS; if (equalIgnoringCase(mimeType, "text/html")) return HTML; if (DOMImplementation::isXMLMIMEType(mimeType)) return XML; return PlainText; } const TextEncoding& TextResourceDecoder::defaultEncoding(ContentType contentType, const TextEncoding& specifiedDefaultEncoding) { // Despite 8.5 "Text/xml with Omitted Charset" of RFC 3023, we assume UTF-8 instead of US-ASCII // for text/xml. This matches Firefox. if (contentType == XML) return UTF8Encoding(); if (!specifiedDefaultEncoding.isValid()) return Latin1Encoding(); return specifiedDefaultEncoding; } TextResourceDecoder::TextResourceDecoder(const String& mimeType, const TextEncoding& specifiedDefaultEncoding) : m_contentType(determineContentType(mimeType)) , m_decoder(defaultEncoding(m_contentType, specifiedDefaultEncoding)) , m_source(DefaultEncoding) , m_checkedForBOM(false) , m_checkedForCSSCharset(false) , m_checkedForHeadCharset(false) , m_sawError(false) { } TextResourceDecoder::~TextResourceDecoder() { } void TextResourceDecoder::setEncoding(const TextEncoding& encoding, EncodingSource source) { // In case the encoding didn't exist, we keep the old one (helps some sites specifying invalid encodings). if (!encoding.isValid()) return; // When encoding comes from meta tag (i.e. it cannot be XML files sent via XHR), // treat x-user-defined as windows-1252 (bug 18270) if (source == EncodingFromMetaTag && strcasecmp(encoding.name(), "x-user-defined") == 0) m_decoder.reset("windows-1252"); else if (source == EncodingFromMetaTag || source == EncodingFromXMLHeader || source == EncodingFromCSSCharset) m_decoder.reset(encoding.closestByteBasedEquivalent()); else m_decoder.reset(encoding); m_source = source; } // Returns the position of the encoding string. static int findXMLEncoding(const char* str, int len, int& encodingLength) { int pos = find(str, len, "encoding"); if (pos == -1) return -1; pos += 8; // Skip spaces and stray control characters. while (pos < len && str[pos] <= ' ') ++pos; // Skip equals sign. if (pos >= len || str[pos] != '=') return -1; ++pos; // Skip spaces and stray control characters. while (pos < len && str[pos] <= ' ') ++pos; // Skip quotation mark. if (pos >= len) return - 1; char quoteMark = str[pos]; if (quoteMark != '"' && quoteMark != '\'') return -1; ++pos; // Find the trailing quotation mark. int end = pos; while (end < len && str[end] != quoteMark) ++end; if (end >= len) return -1; encodingLength = end - pos; return pos; } // true if there is more to parse static inline bool skipWhitespace(const char*& pos, const char* dataEnd) { while (pos < dataEnd && (*pos == '\t' || *pos == ' ')) ++pos; return pos != dataEnd; } void TextResourceDecoder::checkForBOM(const char* data, size_t len) { // Check for UTF-16/32 or UTF-8 BOM mark at the beginning, which is a sure sign of a Unicode encoding. if (m_source == UserChosenEncoding) { // FIXME: Maybe a BOM should override even a user-chosen encoding. m_checkedForBOM = true; return; } // Check if we have enough data. size_t bufferLength = m_buffer.size(); if (bufferLength + len < 4) return; m_checkedForBOM = true; // Extract the first four bytes. // Handle the case where some of bytes are already in the buffer. // The last byte is always guaranteed to not be in the buffer. const unsigned char* udata = reinterpret_cast<const unsigned char*>(data); unsigned char c1 = bufferLength >= 1 ? m_buffer[0] : *udata++; unsigned char c2 = bufferLength >= 2 ? m_buffer[1] : *udata++; unsigned char c3 = bufferLength >= 3 ? m_buffer[2] : *udata++; ASSERT(bufferLength < 4); unsigned char c4 = *udata; // Check for the BOM. if (c1 == 0xFF && c2 == 0xFE) { if (c3 !=0 || c4 != 0) setEncoding(UTF16LittleEndianEncoding(), AutoDetectedEncoding); else setEncoding(UTF32LittleEndianEncoding(), AutoDetectedEncoding); } else if (c1 == 0xEF && c2 == 0xBB && c3 == 0xBF) setEncoding(UTF8Encoding(), AutoDetectedEncoding); else if (c1 == 0xFE && c2 == 0xFF) setEncoding(UTF16BigEndianEncoding(), AutoDetectedEncoding); else if (c1 == 0 && c2 == 0 && c3 == 0xFE && c4 == 0xFF) setEncoding(UTF32BigEndianEncoding(), AutoDetectedEncoding); } bool TextResourceDecoder::checkForCSSCharset(const char* data, size_t len, bool& movedDataToBuffer) { if (m_source != DefaultEncoding) { m_checkedForCSSCharset = true; return true; } size_t oldSize = m_buffer.size(); m_buffer.grow(oldSize + len); memcpy(m_buffer.data() + oldSize, data, len); movedDataToBuffer = true; if (m_buffer.size() > 8) { // strlen("@charset") == 8 const char* dataStart = m_buffer.data(); const char* dataEnd = dataStart + m_buffer.size(); if (dataStart[0] == '@' && dataStart[1] == 'c' && dataStart[2] == 'h' && dataStart[3] == 'a' && dataStart[4] == 'r' && dataStart[5] == 's' && dataStart[6] == 'e' && dataStart[7] == 't') { dataStart += 8; const char* pos = dataStart; if (!skipWhitespace(pos, dataEnd)) return false; if (*pos == '"' || *pos == '\'') { char quotationMark = *pos; ++pos; dataStart = pos; while (pos < dataEnd && *pos != quotationMark) ++pos; if (pos == dataEnd) return false; int encodingNameLength = pos - dataStart + 1; ++pos; if (!skipWhitespace(pos, dataEnd)) return false; if (*pos == ';') setEncoding(findTextEncoding(dataStart, encodingNameLength), EncodingFromCSSCharset); } } m_checkedForCSSCharset = true; return true; } return false; } // Other browsers allow comments in the head section, so we need to also. // It's important not to look for tags inside the comments. static inline void skipComment(const char*& ptr, const char* pEnd) { const char* p = ptr; // Allow <!-->; other browsers do. if (*p == '>') { p++; } else { while (p != pEnd) { if (*p == '-') { // This is the real end of comment, "-->". if (p[1] == '-' && p[2] == '>') { p += 3; break; } // This is the incorrect end of comment that other browsers allow, "--!>". if (p[1] == '-' && p[2] == '!' && p[3] == '>') { p += 4; break; } } p++; } } ptr = p; } const int bytesToCheckUnconditionally = 1024; // That many input bytes will be checked for meta charset even if <head> section is over. bool TextResourceDecoder::checkForHeadCharset(const char* data, size_t len, bool& movedDataToBuffer) { if (m_source != DefaultEncoding) { m_checkedForHeadCharset = true; return true; } // This is not completely efficient, since the function might go // through the HTML head several times. size_t oldSize = m_buffer.size(); m_buffer.grow(oldSize + len); memcpy(m_buffer.data() + oldSize, data, len); movedDataToBuffer = true; const char* ptr = m_buffer.data(); const char* pEnd = ptr + m_buffer.size(); // Is there enough data available to check for XML declaration? if (m_buffer.size() < 8) return false; // Handle XML declaration, which can have encoding in it. This encoding is honored even for HTML documents. // It is an error for an XML declaration not to be at the start of an XML document, and it is ignored in HTML documents in such case. if (ptr[0] == '<' && ptr[1] == '?' && ptr[2] == 'x' && ptr[3] == 'm' && ptr[4] == 'l') { const char* xmlDeclarationEnd = ptr; while (xmlDeclarationEnd != pEnd && *xmlDeclarationEnd != '>') ++xmlDeclarationEnd; if (xmlDeclarationEnd == pEnd) return false; // No need for +1, because we have an extra "?" to lose at the end of XML declaration. int len; int pos = findXMLEncoding(ptr, xmlDeclarationEnd - ptr, len); if (pos != -1) setEncoding(findTextEncoding(ptr + pos, len), EncodingFromXMLHeader); // continue looking for a charset - it may be specified in an HTTP-Equiv meta } else if (ptr[0] == '<' && ptr[1] == 0 && ptr[2] == '?' && ptr[3] == 0 && ptr[4] == 'x' && ptr[5] == 0) { setEncoding(UTF16LittleEndianEncoding(), AutoDetectedEncoding); return true; } else if (ptr[0] == 0 && ptr[1] == '<' && ptr[2] == 0 && ptr[3] == '?' && ptr[4] == 0 && ptr[5] == 'x') { setEncoding(UTF16BigEndianEncoding(), AutoDetectedEncoding); return true; } else if (ptr[0] == '<' && ptr[1] == 0 && ptr[2] == 0 && ptr[3] == 0 && ptr[4] == '?' && ptr[5] == 0 && ptr[6] == 0 && ptr[7] == 0) { setEncoding(UTF32LittleEndianEncoding(), AutoDetectedEncoding); return true; } else if (ptr[0] == 0 && ptr[1] == 0 && ptr[2] == 0 && ptr[3] == '<' && ptr[4] == 0 && ptr[5] == 0 && ptr[6] == 0 && ptr[7] == '?') { setEncoding(UTF32BigEndianEncoding(), AutoDetectedEncoding); return true; } // we still don't have an encoding, and are in the head // the following tags are allowed in <head>: // SCRIPT|STYLE|META|LINK|OBJECT|TITLE|BASE // We stop scanning when a tag that is not permitted in <head> // is seen, rather when </head> is seen, because that more closely // matches behavior in other browsers; more details in // <http://bugs.webkit.org/show_bug.cgi?id=3590>. // Additionally, we ignore things that looks like tags in <title>, <script> and <noscript>; see // <http://bugs.webkit.org/show_bug.cgi?id=4560>, <http://bugs.webkit.org/show_bug.cgi?id=12165> // and <http://bugs.webkit.org/show_bug.cgi?id=12389>. // Since many sites have charset declarations after <body> or other tags that are disallowed in <head>, // we don't bail out until we've checked at least bytesToCheckUnconditionally bytes of input. AtomicStringImpl* enclosingTagName = 0; bool inHeadSection = true; // Becomes false when </head> or any tag not allowed in head is encountered. // the HTTP-EQUIV meta has no effect on XHTML if (m_contentType == XML) return true; while (ptr + 3 < pEnd) { // +3 guarantees that "<!--" fits in the buffer - and certainly we aren't going to lose any "charset" that way. if (*ptr == '<') { bool end = false; ptr++; // Handle comments. if (ptr[0] == '!' && ptr[1] == '-' && ptr[2] == '-') { ptr += 3; skipComment(ptr, pEnd); if (ptr - m_buffer.data() >= bytesToCheckUnconditionally && !inHeadSection) { // Some pages that test bandwidth from within the browser do it by having // huge comments and measuring the time they take to load. Repeatedly scanning // these comments can take a lot of CPU time. m_checkedForHeadCharset = true; return true; } continue; } if (*ptr == '/') { ++ptr; end = true; } // Grab the tag name, but mostly ignore namespaces. bool sawNamespace = false; char tagBuffer[20]; int len = 0; while (len < 19) { if (ptr == pEnd) return false; char c = *ptr; if (c == ':') { len = 0; sawNamespace = true; ptr++; continue; } if (c >= 'a' && c <= 'z' || c >= '0' && c <= '9') ; else if (c >= 'A' && c <= 'Z') c += 'a' - 'A'; else break; tagBuffer[len++] = c; ptr++; } tagBuffer[len] = 0; AtomicString tag(tagBuffer); if (enclosingTagName) { if (end && tag.impl() == enclosingTagName) enclosingTagName = 0; } else { if (tag == titleTag) enclosingTagName = titleTag.localName().impl(); else if (tag == scriptTag) enclosingTagName = scriptTag.localName().impl(); else if (tag == noscriptTag) enclosingTagName = noscriptTag.localName().impl(); } // Find where the opening tag ends. const char* tagContentStart = ptr; if (!end) { while (ptr != pEnd && *ptr != '>') { if (*ptr == '\'' || *ptr == '"') { char quoteMark = *ptr; ++ptr; while (ptr != pEnd && *ptr != quoteMark) ++ptr; if (ptr == pEnd) return false; } ++ptr; } if (ptr == pEnd) return false; ++ptr; } if (!end && tag == metaTag && !sawNamespace) { const char* str = tagContentStart; int length = ptr - tagContentStart; int pos = 0; while (pos < length) { int charsetPos = findIgnoringCase(str + pos, length - pos, "charset"); if (charsetPos == -1) break; pos += charsetPos + 7; // skip whitespace while (pos < length && str[pos] <= ' ') pos++; if (pos == length) break; if (str[pos++] != '=') continue; while (pos < length && (str[pos] <= ' ') || str[pos] == '=' || str[pos] == '"' || str[pos] == '\'') pos++; // end ? if (pos == length) break; int end = pos; while (end < length && str[end] != ' ' && str[end] != '"' && str[end] != '\'' && str[end] != ';' && str[end] != '>') end++; setEncoding(findTextEncoding(str + pos, end - pos), EncodingFromMetaTag); if (m_source == EncodingFromMetaTag) return true; if (end >= length || str[end] == '/' || str[end] == '>') break; pos = end + 1; } } else { if (!enclosingTagName && tag != scriptTag && tag != noscriptTag && tag != styleTag && tag != linkTag && tag != metaTag && tag != objectTag && tag != titleTag && tag != baseTag && (end || tag != htmlTag) && (end || tag != headTag) && isASCIIAlpha(tagBuffer[0])) { inHeadSection = false; } if (ptr - m_buffer.data() >= bytesToCheckUnconditionally && !inHeadSection) { m_checkedForHeadCharset = true; return true; } } } else ++ptr; } return false; } void TextResourceDecoder::detectJapaneseEncoding(const char* data, size_t len) { switch (KanjiCode::judge(data, len)) { case KanjiCode::JIS: setEncoding("ISO-2022-JP", AutoDetectedEncoding); break; case KanjiCode::EUC: setEncoding("EUC-JP", AutoDetectedEncoding); break; case KanjiCode::SJIS: setEncoding("Shift_JIS", AutoDetectedEncoding); break; case KanjiCode::ASCII: case KanjiCode::UTF16: case KanjiCode::UTF8: break; } } String TextResourceDecoder::decode(const char* data, size_t len) { if (!m_checkedForBOM) checkForBOM(data, len); bool movedDataToBuffer = false; if (m_contentType == CSS && !m_checkedForCSSCharset) if (!checkForCSSCharset(data, len, movedDataToBuffer)) return ""; if ((m_contentType == HTML || m_contentType == XML) && !m_checkedForHeadCharset) // HTML and XML if (!checkForHeadCharset(data, len, movedDataToBuffer)) return ""; // Do the auto-detect if our default encoding is one of the Japanese ones. // FIXME: It seems wrong to change our encoding downstream after we have already done some decoding. if (m_source != UserChosenEncoding && m_source != AutoDetectedEncoding && encoding().isJapanese()) detectJapaneseEncoding(data, len); ASSERT(encoding().isValid()); if (m_buffer.isEmpty()) return m_decoder.decode(data, len, false, m_contentType == XML, m_sawError); if (!movedDataToBuffer) { size_t oldSize = m_buffer.size(); m_buffer.grow(oldSize + len); memcpy(m_buffer.data() + oldSize, data, len); } String result = m_decoder.decode(m_buffer.data(), m_buffer.size(), false, m_contentType == XML, m_sawError); m_buffer.clear(); return result; } String TextResourceDecoder::flush() { String result = m_decoder.decode(m_buffer.data(), m_buffer.size(), true, m_contentType == XML, m_sawError); m_buffer.clear(); m_decoder.reset(m_decoder.encoding()); return result; } }