/**************************************************************************** ** ** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtCore module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the Technology Preview License Agreement accompanying ** this package. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qutfcodec_p.h" #include "qlist.h" #include "qendian.h" #include "qchar.h" QT_BEGIN_NAMESPACE enum { Endian = 0, Data = 1 }; QByteArray QUtf8::convertFromUnicode(const QChar *uc, int len, QTextCodec::ConverterState *state) { uchar replacement = '?'; int rlen = 3*len; int surrogate_high = -1; if (state) { if (state->flags & QTextCodec::ConvertInvalidToNull) replacement = 0; if (!(state->flags & QTextCodec::IgnoreHeader)) rlen += 3; if (state->remainingChars) surrogate_high = state->state_data[0]; } QByteArray rstr; rstr.resize(rlen); uchar* cursor = (uchar*)rstr.data(); const QChar *ch = uc; int invalid = 0; if (state && !(state->flags & QTextCodec::IgnoreHeader)) { *cursor++ = 0xef; *cursor++ = 0xbb; *cursor++ = 0xbf; } const QChar *end = ch + len; while (ch < end) { uint u = ch->unicode(); if (surrogate_high >= 0) { if (u >= 0xdc00 && u < 0xe000) { u = (surrogate_high - 0xd800)*0x400 + (u - 0xdc00) + 0x10000; surrogate_high = -1; } else { // high surrogate without low *cursor = replacement; ++ch; ++invalid; surrogate_high = -1; continue; } } else if (u >= 0xdc00 && u < 0xe000) { // low surrogate without high *cursor = replacement; ++ch; ++invalid; continue; } else if (u >= 0xd800 && u < 0xdc00) { surrogate_high = u; ++ch; continue; } if (u < 0x80) { *cursor++ = (uchar)u; } else { if (u < 0x0800) { *cursor++ = 0xc0 | ((uchar) (u >> 6)); } else { if (u > 0xffff) { // see QString::fromUtf8() and QString::utf8() for explanations if (u > 0x10fe00 && u < 0x10ff00) { *cursor++ = (u - 0x10fe00); ++ch; continue; } else { *cursor++ = 0xf0 | ((uchar) (u >> 18)); *cursor++ = 0x80 | (((uchar) (u >> 12)) & 0x3f); } } else { *cursor++ = 0xe0 | (((uchar) (u >> 12)) & 0x3f); } *cursor++ = 0x80 | (((uchar) (u >> 6)) & 0x3f); } *cursor++ = 0x80 | ((uchar) (u&0x3f)); } ++ch; } rstr.resize(cursor - (const uchar*)rstr.constData()); if (state) { state->invalidChars += invalid; state->flags |= QTextCodec::IgnoreHeader; state->remainingChars = 0; if (surrogate_high >= 0) { state->remainingChars = 1; state->state_data[0] = surrogate_high; } } return rstr; } QString QUtf8::convertToUnicode(const char *chars, int len, QTextCodec::ConverterState *state) { bool headerdone = false; ushort replacement = QChar::ReplacementCharacter; int need = 0; int error = -1; uint uc = 0; uint min_uc = 0; if (state) { if (state->flags & QTextCodec::IgnoreHeader) headerdone = true; if (state->flags & QTextCodec::ConvertInvalidToNull) replacement = QChar::Null; need = state->remainingChars; if (need) { uc = state->state_data[0]; min_uc = state->state_data[1]; } } if (!headerdone && len > 3 && (uchar)chars[0] == 0xef && (uchar)chars[1] == 0xbb && (uchar)chars[2] == 0xbf) { // starts with a byte order mark chars += 3; len -= 3; headerdone = true; } QString result(need + len + 1, Qt::Uninitialized); // worst case ushort *qch = (ushort *)result.unicode(); uchar ch; int invalid = 0; for (int i = 0; i < len; ++i) { ch = chars[i]; if (need) { if ((ch&0xc0) == 0x80) { uc = (uc << 6) | (ch & 0x3f); --need; if (!need) { // utf-8 bom composes into 0xfeff code point if (!headerdone && uc == 0xfeff) { // dont do anything, just skip the BOM } else if (uc > 0xffff && uc < 0x110000) { // surrogate pair Q_ASSERT((qch - (ushort*)result.unicode()) + 2 < result.length()); *qch++ = QChar::highSurrogate(uc); *qch++ = QChar::lowSurrogate(uc); } else if ((uc < min_uc) || (uc >= 0xd800 && uc <= 0xdfff) || (uc >= 0xfffe)) { // error: overlong sequence, UTF16 surrogate or BOM *qch++ = replacement; ++invalid; } else { *qch++ = uc; } headerdone = true; } } else { // error i = error; *qch++ = replacement; ++invalid; need = 0; headerdone = true; } } else { if (ch < 128) { *qch++ = ushort(ch); headerdone = true; } else if ((ch & 0xe0) == 0xc0) { uc = ch & 0x1f; need = 1; error = i; min_uc = 0x80; headerdone = true; } else if ((ch & 0xf0) == 0xe0) { uc = ch & 0x0f; need = 2; error = i; min_uc = 0x800; } else if ((ch&0xf8) == 0xf0) { uc = ch & 0x07; need = 3; error = i; min_uc = 0x10000; headerdone = true; } else { // error *qch++ = replacement; ++invalid; headerdone = true; } } } if (!state && need > 0) { // unterminated UTF sequence for (int i = error; i < len; ++i) { *qch++ = replacement; ++invalid; } } result.truncate(qch - (ushort *)result.unicode()); if (state) { state->invalidChars += invalid; state->remainingChars = need; if (headerdone) state->flags |= QTextCodec::IgnoreHeader; state->state_data[0] = need ? uc : 0; state->state_data[1] = need ? min_uc : 0; } return result; } QByteArray QUtf16::convertFromUnicode(const QChar *uc, int len, QTextCodec::ConverterState *state, DataEndianness e) { DataEndianness endian = e; int length = 2*len; if (!state || (!(state->flags & QTextCodec::IgnoreHeader))) { length += 2; } if (e == DetectEndianness) { endian = (QSysInfo::ByteOrder == QSysInfo::BigEndian) ? BigEndianness : LittleEndianness; } QByteArray d; d.resize(length); char *data = d.data(); if (!state || !(state->flags & QTextCodec::IgnoreHeader)) { QChar bom(QChar::ByteOrderMark); if (endian == BigEndianness) { data[0] = bom.row(); data[1] = bom.cell(); } else { data[0] = bom.cell(); data[1] = bom.row(); } data += 2; } if (endian == BigEndianness) { for (int i = 0; i < len; ++i) { *(data++) = uc[i].row(); *(data++) = uc[i].cell(); } } else { for (int i = 0; i < len; ++i) { *(data++) = uc[i].cell(); *(data++) = uc[i].row(); } } if (state) { state->remainingChars = 0; state->flags |= QTextCodec::IgnoreHeader; } return d; } QString QUtf16::convertToUnicode(const char *chars, int len, QTextCodec::ConverterState *state, DataEndianness e) { DataEndianness endian = e; bool half = false; uchar buf = 0; bool headerdone = false; if (state) { headerdone = state->flags & QTextCodec::IgnoreHeader; if (endian == DetectEndianness) endian = (DataEndianness)state->state_data[Endian]; if (state->remainingChars) { half = true; buf = state->state_data[Data]; } } if (headerdone && endian == DetectEndianness) endian = (QSysInfo::ByteOrder == QSysInfo::BigEndian) ? BigEndianness : LittleEndianness; QString result(len, Qt::Uninitialized); // worst case QChar *qch = (QChar *)result.unicode(); while (len--) { if (half) { QChar ch; if (endian == LittleEndianness) { ch.setRow(*chars++); ch.setCell(buf); } else { ch.setRow(buf); ch.setCell(*chars++); } if (!headerdone) { if (endian == DetectEndianness) { if (ch == QChar::ByteOrderSwapped && endian != BigEndianness) { endian = LittleEndianness; } else if (ch == QChar::ByteOrderMark && endian != LittleEndianness) { // ignore BOM endian = BigEndianness; } else { if (QSysInfo::ByteOrder == QSysInfo::BigEndian) { endian = BigEndianness; } else { endian = LittleEndianness; ch = QChar((ch.unicode() >> 8) | ((ch.unicode() & 0xff) << 8)); } *qch++ = ch; } } else if (ch != QChar::ByteOrderMark) { *qch++ = ch; } headerdone = true; } else { *qch++ = ch; } half = false; } else { buf = *chars++; half = true; } } result.truncate(qch - result.unicode()); if (state) { if (headerdone) state->flags |= QTextCodec::IgnoreHeader; state->state_data[Endian] = endian; if (half) { state->remainingChars = 1; state->state_data[Data] = buf; } else { state->remainingChars = 0; state->state_data[Data] = 0; } } return result; } QByteArray QUtf32::convertFromUnicode(const QChar *uc, int len, QTextCodec::ConverterState *state, DataEndianness e) { DataEndianness endian = e; int length = 4*len; if (!state || (!(state->flags & QTextCodec::IgnoreHeader))) { length += 4; } if (e == DetectEndianness) { endian = (QSysInfo::ByteOrder == QSysInfo::BigEndian) ? BigEndianness : LittleEndianness; } QByteArray d(length, Qt::Uninitialized); char *data = d.data(); if (!state || !(state->flags & QTextCodec::IgnoreHeader)) { if (endian == BigEndianness) { data[0] = 0; data[1] = 0; data[2] = (char)0xfe; data[3] = (char)0xff; } else { data[0] = (char)0xff; data[1] = (char)0xfe; data[2] = 0; data[3] = 0; } data += 4; } if (endian == BigEndianness) { for (int i = 0; i < len; ++i) { uint cp = uc[i].unicode(); if (uc[i].isHighSurrogate() && i < len - 1) cp = QChar::surrogateToUcs4(cp, uc[++i].unicode()); *(data++) = cp >> 24; *(data++) = (cp >> 16) & 0xff; *(data++) = (cp >> 8) & 0xff; *(data++) = cp & 0xff; } } else { for (int i = 0; i < len; ++i) { uint cp = uc[i].unicode(); if (uc[i].isHighSurrogate() && i < len - 1) cp = QChar::surrogateToUcs4(cp, uc[++i].unicode()); *(data++) = cp & 0xff; *(data++) = (cp >> 8) & 0xff; *(data++) = (cp >> 16) & 0xff; *(data++) = cp >> 24; } } if (state) { state->remainingChars = 0; state->flags |= QTextCodec::IgnoreHeader; } return d; } QString QUtf32::convertToUnicode(const char *chars, int len, QTextCodec::ConverterState *state, DataEndianness e) { DataEndianness endian = e; uchar tuple[4]; int num = 0; bool headerdone = false; if (state) { headerdone = state->flags & QTextCodec::IgnoreHeader; if (endian == DetectEndianness) { endian = (DataEndianness)state->state_data[Endian]; } num = state->remainingChars; memcpy(tuple, &state->state_data[Data], 4); } if (headerdone && endian == DetectEndianness) endian = (QSysInfo::ByteOrder == QSysInfo::BigEndian) ? BigEndianness : LittleEndianness; QString result; result.resize((num + len) >> 2 << 1); // worst case QChar *qch = (QChar *)result.unicode(); const char *end = chars + len; while (chars < end) { tuple[num++] = *chars++; if (num == 4) { if (!headerdone) { if (endian == DetectEndianness) { if (endian == DetectEndianness) { if (tuple[0] == 0xff && tuple[1] == 0xfe && tuple[2] == 0 && tuple[3] == 0 && endian != BigEndianness) { endian = LittleEndianness; num = 0; continue; } else if (tuple[0] == 0 && tuple[1] == 0 && tuple[2] == 0xfe && tuple[3] == 0xff && endian != LittleEndianness) { endian = BigEndianness; num = 0; continue; } else if (QSysInfo::ByteOrder == QSysInfo::BigEndian) { endian = BigEndianness; } else { endian = LittleEndianness; } } } else if (((endian == BigEndianness) ? qFromBigEndian(tuple) : qFromLittleEndian(tuple)) == QChar::ByteOrderMark) { num = 0; continue; } } uint code = (endian == BigEndianness) ? qFromBigEndian(tuple) : qFromLittleEndian(tuple); if (code >= 0x10000) { *qch++ = QChar::highSurrogate(code); *qch++ = QChar::lowSurrogate(code); } else { *qch++ = code; } num = 0; } } result.truncate(qch - result.unicode()); if (state) { if (headerdone) state->flags |= QTextCodec::IgnoreHeader; state->state_data[Endian] = endian; state->remainingChars = num; memcpy(&state->state_data[Data], tuple, 4); } return result; } #ifndef QT_NO_TEXTCODEC QUtf8Codec::~QUtf8Codec() { } QByteArray QUtf8Codec::convertFromUnicode(const QChar *uc, int len, ConverterState *state) const { return QUtf8::convertFromUnicode(uc, len, state); } void QUtf8Codec::convertToUnicode(QString *target, const char *chars, int len, ConverterState *state) const { *target += QUtf8::convertToUnicode(chars, len, state); } QString QUtf8Codec::convertToUnicode(const char *chars, int len, ConverterState *state) const { return QUtf8::convertToUnicode(chars, len, state); } QByteArray QUtf8Codec::name() const { return "UTF-8"; } int QUtf8Codec::mibEnum() const { return 106; } QUtf16Codec::~QUtf16Codec() { } QByteArray QUtf16Codec::convertFromUnicode(const QChar *uc, int len, ConverterState *state) const { return QUtf16::convertFromUnicode(uc, len, state, e); } QString QUtf16Codec::convertToUnicode(const char *chars, int len, ConverterState *state) const { return QUtf16::convertToUnicode(chars, len, state, e); } int QUtf16Codec::mibEnum() const { return 1015; } QByteArray QUtf16Codec::name() const { return "UTF-16"; } QList QUtf16Codec::aliases() const { return QList(); } int QUtf16BECodec::mibEnum() const { return 1013; } QByteArray QUtf16BECodec::name() const { return "UTF-16BE"; } QList QUtf16BECodec::aliases() const { QList list; return list; } int QUtf16LECodec::mibEnum() const { return 1014; } QByteArray QUtf16LECodec::name() const { return "UTF-16LE"; } QList QUtf16LECodec::aliases() const { QList list; return list; } QUtf32Codec::~QUtf32Codec() { } QByteArray QUtf32Codec::convertFromUnicode(const QChar *uc, int len, ConverterState *state) const { return QUtf32::convertFromUnicode(uc, len, state, e); } QString QUtf32Codec::convertToUnicode(const char *chars, int len, ConverterState *state) const { return QUtf32::convertToUnicode(chars, len, state, e); } int QUtf32Codec::mibEnum() const { return 1017; } QByteArray QUtf32Codec::name() const { return "UTF-32"; } QList QUtf32Codec::aliases() const { QList list; return list; } int QUtf32BECodec::mibEnum() const { return 1018; } QByteArray QUtf32BECodec::name() const { return "UTF-32BE"; } QList QUtf32BECodec::aliases() const { QList list; return list; } int QUtf32LECodec::mibEnum() const { return 1019; } QByteArray QUtf32LECodec::name() const { return "UTF-32LE"; } QList QUtf32LECodec::aliases() const { QList list; return list; } #endif //QT_NO_TEXTCODEC QT_END_NAMESPACE