/**************************************************************************** ** ** Copyright (C) 2013 Digia Plc and/or its subsidiary(-ies). ** Contact: http://www.qt-project.org/legal ** ** This file is part of the QtGui module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and Digia. For licensing terms and ** conditions see http://qt.digia.com/licensing. For further information ** use the contact form at http://qt.digia.com/contact-us. ** ** 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, Digia gives you certain additional ** rights. These rights are described in the Digia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 3.0 as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU General Public License version 3.0 requirements will be ** met: http://www.gnu.org/copyleft/gpl.html. ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "private/qbmphandler_p.h" #ifndef QT_NO_IMAGEFORMAT_BMP #include #include #include QT_BEGIN_NAMESPACE static void swapPixel01(QImage *image) // 1-bpp: swap 0 and 1 pixels { int i; if (image->depth() == 1 && image->colorCount() == 2) { register uint *p = (uint *)image->bits(); int nbytes = image->byteCount(); for (i=0; icolor(0); // swap color 0 and 1 image->setColor(0, image->color(1)); image->setColor(1, t); } } /* QImageIO::defineIOHandler("BMP", "^BM", 0, read_bmp_image, write_bmp_image); */ /***************************************************************************** BMP (DIB) image read/write functions *****************************************************************************/ const int BMP_FILEHDR_SIZE = 14; // size of BMP_FILEHDR data static QDataStream &operator>>(QDataStream &s, BMP_FILEHDR &bf) { // read file header s.readRawData(bf.bfType, 2); s >> bf.bfSize >> bf.bfReserved1 >> bf.bfReserved2 >> bf.bfOffBits; return s; } static QDataStream &operator<<(QDataStream &s, const BMP_FILEHDR &bf) { // write file header s.writeRawData(bf.bfType, 2); s << bf.bfSize << bf.bfReserved1 << bf.bfReserved2 << bf.bfOffBits; return s; } const int BMP_OLD = 12; // old Windows/OS2 BMP size const int BMP_WIN = 40; // Windows BMP v3 size const int BMP_OS2 = 64; // new OS/2 BMP size const int BMP_WIN4 = 108; // Windows BMP v4 size const int BMP_WIN5 = 124; // Windows BMP v5 size const int BMP_RGB = 0; // no compression const int BMP_RLE8 = 1; // run-length encoded, 8 bits const int BMP_RLE4 = 2; // run-length encoded, 4 bits const int BMP_BITFIELDS = 3; // RGB values encoded in data as bit-fields static QDataStream &operator>>(QDataStream &s, BMP_INFOHDR &bi) { s >> bi.biSize; if (bi.biSize == BMP_WIN || bi.biSize == BMP_OS2 || bi.biSize == BMP_WIN4 || bi.biSize == BMP_WIN5) { s >> bi.biWidth >> bi.biHeight >> bi.biPlanes >> bi.biBitCount; s >> bi.biCompression >> bi.biSizeImage; s >> bi.biXPelsPerMeter >> bi.biYPelsPerMeter; s >> bi.biClrUsed >> bi.biClrImportant; } else { // probably old Windows format qint16 w, h; s >> w >> h >> bi.biPlanes >> bi.biBitCount; bi.biWidth = w; bi.biHeight = h; bi.biCompression = BMP_RGB; // no compression bi.biSizeImage = 0; bi.biXPelsPerMeter = bi.biYPelsPerMeter = 0; bi.biClrUsed = bi.biClrImportant = 0; } return s; } static QDataStream &operator<<(QDataStream &s, const BMP_INFOHDR &bi) { s << bi.biSize; s << bi.biWidth << bi.biHeight; s << bi.biPlanes; s << bi.biBitCount; s << bi.biCompression; s << bi.biSizeImage; s << bi.biXPelsPerMeter << bi.biYPelsPerMeter; s << bi.biClrUsed << bi.biClrImportant; return s; } static int calc_shift(uint mask) { int result = 0; while (mask && !(mask & 1)) { result++; mask >>= 1; } return result; } static bool read_dib_fileheader(QDataStream &s, BMP_FILEHDR &bf) { // read BMP file header s >> bf; if (s.status() != QDataStream::Ok) return false; // check header if (qstrncmp(bf.bfType,"BM",2) != 0) return false; return true; } static bool read_dib_infoheader(QDataStream &s, BMP_INFOHDR &bi) { s >> bi; // read BMP info header if (s.status() != QDataStream::Ok) return false; int nbits = bi.biBitCount; int comp = bi.biCompression; if (!(nbits == 1 || nbits == 4 || nbits == 8 || nbits == 16 || nbits == 24 || nbits == 32) || bi.biPlanes != 1 || comp > BMP_BITFIELDS) return false; // weird BMP image if (!(comp == BMP_RGB || (nbits == 4 && comp == BMP_RLE4) || (nbits == 8 && comp == BMP_RLE8) || ((nbits == 16 || nbits == 32) && comp == BMP_BITFIELDS))) return false; // weird compression type return true; } static bool read_dib_body(QDataStream &s, const BMP_INFOHDR &bi, int offset, int startpos, QImage &image) { QIODevice* d = s.device(); if (d->atEnd()) // end of stream/file return false; #if 0 qDebug("offset...........%d", offset); qDebug("startpos.........%d", startpos); qDebug("biSize...........%d", bi.biSize); qDebug("biWidth..........%d", bi.biWidth); qDebug("biHeight.........%d", bi.biHeight); qDebug("biPlanes.........%d", bi.biPlanes); qDebug("biBitCount.......%d", bi.biBitCount); qDebug("biCompression....%d", bi.biCompression); qDebug("biSizeImage......%d", bi.biSizeImage); qDebug("biXPelsPerMeter..%d", bi.biXPelsPerMeter); qDebug("biYPelsPerMeter..%d", bi.biYPelsPerMeter); qDebug("biClrUsed........%d", bi.biClrUsed); qDebug("biClrImportant...%d", bi.biClrImportant); #endif int w = bi.biWidth, h = bi.biHeight, nbits = bi.biBitCount; int t = bi.biSize, comp = bi.biCompression; uint red_mask = 0; uint green_mask = 0; uint blue_mask = 0; int red_shift = 0; int green_shift = 0; int blue_shift = 0; int red_scale = 0; int green_scale = 0; int blue_scale = 0; int ncols = 0; int depth = 0; QImage::Format format; switch (nbits) { case 32: case 24: case 16: depth = 32; format = QImage::Format_RGB32; break; case 8: case 4: depth = 8; format = QImage::Format_Indexed8; break; default: depth = 1; format = QImage::Format_Mono; } if (bi.biHeight < 0) h = -h; // support images with negative height if (image.size() != QSize(w, h) || image.format() != format) { image = QImage(w, h, format); if (image.isNull()) // could not create image return false; } if (depth != 32) { ncols = bi.biClrUsed ? bi.biClrUsed : 1 << nbits; if (ncols > 256) // sanity check - don't run out of mem if color table is broken return false; image.setColorCount(ncols); } image.setDotsPerMeterX(bi.biXPelsPerMeter); image.setDotsPerMeterY(bi.biYPelsPerMeter); if (!d->isSequential()) d->seek(startpos + BMP_FILEHDR_SIZE + (bi.biSize >= BMP_WIN4? BMP_WIN : bi.biSize)); // goto start of colormap if (bi.biSize >= BMP_WIN4 || (comp == BMP_BITFIELDS && (nbits == 16 || nbits == 32))) { if (d->read((char *)&red_mask, sizeof(red_mask)) != sizeof(red_mask)) return false; if (d->read((char *)&green_mask, sizeof(green_mask)) != sizeof(green_mask)) return false; if (d->read((char *)&blue_mask, sizeof(blue_mask)) != sizeof(blue_mask)) return false; // Read BMP v4+ header if (bi.biSize >= BMP_WIN4) { int alpha_mask = 0; int CSType = 0; int gamma_red = 0; int gamma_green = 0; int gamma_blue = 0; int endpoints[9]; if (d->read((char *)&alpha_mask, sizeof(alpha_mask)) != sizeof(alpha_mask)) return false; if (d->read((char *)&CSType, sizeof(CSType)) != sizeof(CSType)) return false; if (d->read((char *)&endpoints, sizeof(endpoints)) != sizeof(endpoints)) return false; if (d->read((char *)&gamma_red, sizeof(gamma_red)) != sizeof(gamma_red)) return false; if (d->read((char *)&gamma_green, sizeof(gamma_green)) != sizeof(gamma_green)) return false; if (d->read((char *)&gamma_blue, sizeof(gamma_blue)) != sizeof(gamma_blue)) return false; if (bi.biSize == BMP_WIN5) { qint32 intent = 0; qint32 profileData = 0; qint32 profileSize = 0; qint32 reserved = 0; if (d->read((char *)&intent, sizeof(intent)) != sizeof(intent)) return false; if (d->read((char *)&profileData, sizeof(profileData)) != sizeof(profileData)) return false; if (d->read((char *)&profileSize, sizeof(profileSize)) != sizeof(profileSize)) return false; if (d->read((char *)&reserved, sizeof(reserved)) != sizeof(reserved) || reserved != 0) return false; } } } if (ncols > 0) { // read color table uchar rgb[4]; int rgb_len = t == BMP_OLD ? 3 : 4; for (int i=0; iread((char *)rgb, rgb_len) != rgb_len) return false; image.setColor(i, qRgb(rgb[2],rgb[1],rgb[0])); if (d->atEnd()) // truncated file return false; } } else if (comp == BMP_BITFIELDS && (nbits == 16 || nbits == 32)) { red_shift = calc_shift(red_mask); red_scale = 256 / ((red_mask >> red_shift) + 1); green_shift = calc_shift(green_mask); green_scale = 256 / ((green_mask >> green_shift) + 1); blue_shift = calc_shift(blue_mask); blue_scale = 256 / ((blue_mask >> blue_shift) + 1); } else if (comp == BMP_RGB && (nbits == 24 || nbits == 32)) { blue_mask = 0x000000ff; green_mask = 0x0000ff00; red_mask = 0x00ff0000; blue_shift = 0; green_shift = 8; red_shift = 16; blue_scale = green_scale = red_scale = 1; } else if (comp == BMP_RGB && nbits == 16) { blue_mask = 0x001f; green_mask = 0x03e0; red_mask = 0x7c00; blue_shift = 0; green_shift = 2; red_shift = 7; red_scale = 1; green_scale = 1; blue_scale = 8; } // offset can be bogus, be careful if (offset>=0 && startpos + offset > d->pos()) { if (!d->isSequential()) d->seek(startpos + offset); // start of image data } int bpl = image.bytesPerLine(); uchar *data = image.bits(); if (nbits == 1) { // 1 bit BMP image while (--h >= 0) { if (d->read((char*)(data + h*bpl), bpl) != bpl) break; } if (ncols == 2 && qGray(image.color(0)) < qGray(image.color(1))) swapPixel01(&image); // pixel 0 is white! } else if (nbits == 4) { // 4 bit BMP image int buflen = ((w+7)/8)*4; uchar *buf = new uchar[buflen]; if (comp == BMP_RLE4) { // run length compression int x=0, y=0, c, i; quint8 b; register uchar *p = data + (h-1)*bpl; const uchar *endp = p + w; while (y < h) { if (!d->getChar((char *)&b)) break; if (b == 0) { // escape code if (!d->getChar((char *)&b) || b == 1) { y = h; // exit loop } else switch (b) { case 0: // end of line x = 0; y++; p = data + (h-y-1)*bpl; break; case 2: // delta (jump) { quint8 tmp; d->getChar((char *)&tmp); x += tmp; d->getChar((char *)&tmp); y += tmp; } // Protection if ((uint)x >= (uint)w) x = w-1; if ((uint)y >= (uint)h) y = h-1; p = data + (h-y-1)*bpl + x; break; default: // absolute mode // Protection if (p + b > endp) b = endp-p; i = (c = b)/2; while (i--) { d->getChar((char *)&b); *p++ = b >> 4; *p++ = b & 0x0f; } if (c & 1) { unsigned char tmp; d->getChar((char *)&tmp); *p++ = tmp >> 4; } if ((((c & 3) + 1) & 2) == 2) d->getChar(0); // align on word boundary x += c; } } else { // encoded mode // Protection if (p + b > endp) b = endp-p; i = (c = b)/2; d->getChar((char *)&b); // 2 pixels to be repeated while (i--) { *p++ = b >> 4; *p++ = b & 0x0f; } if (c & 1) *p++ = b >> 4; x += c; } } } else if (comp == BMP_RGB) { // no compression memset(data, 0, h*bpl); while (--h >= 0) { if (d->read((char*)buf,buflen) != buflen) break; register uchar *p = data + h*bpl; uchar *b = buf; for (int i=0; i> 4; *p++ = *b++ & 0x0f; } if (w & 1) // the last nibble *p = *b >> 4; } } delete [] buf; } else if (nbits == 8) { // 8 bit BMP image if (comp == BMP_RLE8) { // run length compression int x=0, y=0; quint8 b; register uchar *p = data + (h-1)*bpl; const uchar *endp = p + w; while (y < h) { if (!d->getChar((char *)&b)) break; if (b == 0) { // escape code if (!d->getChar((char *)&b) || b == 1) { y = h; // exit loop } else switch (b) { case 0: // end of line x = 0; y++; p = data + (h-y-1)*bpl; break; case 2: // delta (jump) // Protection if ((uint)x >= (uint)w) x = w-1; if ((uint)y >= (uint)h) y = h-1; { quint8 tmp; d->getChar((char *)&tmp); x += tmp; d->getChar((char *)&tmp); y += tmp; } p = data + (h-y-1)*bpl + x; break; default: // absolute mode // Protection if (p + b > endp) b = endp-p; if (d->read((char *)p, b) != b) return false; if ((b & 1) == 1) d->getChar(0); // align on word boundary x += b; p += b; } } else { // encoded mode // Protection if (p + b > endp) b = endp-p; char tmp; d->getChar(&tmp); memset(p, tmp, b); // repeat pixel x += b; p += b; } } } else if (comp == BMP_RGB) { // uncompressed while (--h >= 0) { if (d->read((char *)data + h*bpl, bpl) != bpl) break; } } } else if (nbits == 16 || nbits == 24 || nbits == 32) { // 16,24,32 bit BMP image register QRgb *p; QRgb *end; uchar *buf24 = new uchar[bpl]; int bpl24 = ((w*nbits+31)/32)*4; uchar *b; int c; while (--h >= 0) { p = (QRgb *)(data + h*bpl); end = p + w; if (d->read((char *)buf24,bpl24) != bpl24) break; b = buf24; while (p < end) { c = *(uchar*)b | (*(uchar*)(b+1)<<8); if (nbits != 16) c |= *(uchar*)(b+2)<<16; *p++ = qRgb(((c & red_mask) >> red_shift) * red_scale, ((c & green_mask) >> green_shift) * green_scale, ((c & blue_mask) >> blue_shift) * blue_scale); b += nbits/8; } } delete[] buf24; } if (bi.biHeight < 0) { // Flip the image uchar *buf = new uchar[bpl]; h = -bi.biHeight; for (int y = 0; y < h/2; ++y) { memcpy(buf, data + y*bpl, bpl); memcpy(data + y*bpl, data + (h-y-1)*bpl, bpl); memcpy(data + (h-y-1)*bpl, buf, bpl); } delete [] buf; } return true; } // this is also used in qmime_win.cpp bool qt_write_dib(QDataStream &s, QImage image) { int nbits; int bpl_bmp; int bpl = image.bytesPerLine(); QIODevice* d = s.device(); if (!d->isWritable()) return false; if (image.depth() == 8 && image.colorCount() <= 16) { bpl_bmp = (((bpl+1)/2+3)/4)*4; nbits = 4; } else if (image.depth() == 32) { bpl_bmp = ((image.width()*24+31)/32)*4; nbits = 24; #ifdef Q_WS_QWS } else if (image.depth() == 1 || image.depth() == 8) { // Qt for Embedded Linux doesn't word align. bpl_bmp = ((image.width()*image.depth()+31)/32)*4; nbits = image.depth(); #endif } else { bpl_bmp = bpl; nbits = image.depth(); } BMP_INFOHDR bi; bi.biSize = BMP_WIN; // build info header bi.biWidth = image.width(); bi.biHeight = image.height(); bi.biPlanes = 1; bi.biBitCount = nbits; bi.biCompression = BMP_RGB; bi.biSizeImage = bpl_bmp*image.height(); bi.biXPelsPerMeter = image.dotsPerMeterX() ? image.dotsPerMeterX() : 2834; // 72 dpi default bi.biYPelsPerMeter = image.dotsPerMeterY() ? image.dotsPerMeterY() : 2834; bi.biClrUsed = image.colorCount(); bi.biClrImportant = image.colorCount(); s << bi; // write info header if (s.status() != QDataStream::Ok) return false; if (image.depth() != 32) { // write color table uchar *color_table = new uchar[4*image.colorCount()]; uchar *rgb = color_table; QVector c = image.colorTable(); for (int i=0; iwrite((char *)color_table, 4*image.colorCount()) == -1) { delete [] color_table; return false; } delete [] color_table; } if (image.format() == QImage::Format_MonoLSB) image = image.convertToFormat(QImage::Format_Mono); int y; if (nbits == 1 || nbits == 8) { // direct output #ifdef Q_WS_QWS // Qt for Embedded Linux doesn't word align. int pad = bpl_bmp - bpl; char padding[4]; #endif for (y=image.height()-1; y>=0; y--) { if (d->write((char*)image.scanLine(y), bpl) == -1) return false; #ifdef Q_WS_QWS if (d->write(padding, pad) == -1) return false; #endif } return true; } uchar *buf = new uchar[bpl_bmp]; uchar *b, *end; register uchar *p; memset(buf, 0, bpl_bmp); for (y=image.height()-1; y>=0; y--) { // write the image bits if (nbits == 4) { // convert 8 -> 4 bits p = image.scanLine(y); b = buf; end = b + image.width()/2; while (b < end) { *b++ = (*p << 4) | (*(p+1) & 0x0f); p += 2; } if (image.width() & 1) *b = *p << 4; } else { // 32 bits QRgb *p = (QRgb *)image.scanLine(y); QRgb *end = p + image.width(); b = buf; while (p < end) { *b++ = qBlue(*p); *b++ = qGreen(*p); *b++ = qRed(*p); p++; } } if (bpl_bmp != d->write((char*)buf, bpl_bmp)) { delete[] buf; return false; } } delete[] buf; return true; } // this is also used in qmime_win.cpp bool qt_read_dib(QDataStream &s, QImage &image) { BMP_INFOHDR bi; if (!read_dib_infoheader(s, bi)) return false; return read_dib_body(s, bi, -1, -BMP_FILEHDR_SIZE, image); } QBmpHandler::QBmpHandler() : state(Ready) { } bool QBmpHandler::readHeader() { state = Error; QIODevice *d = device(); QDataStream s(d); startpos = d->pos(); // Intel byte order s.setByteOrder(QDataStream::LittleEndian); // read BMP file header if (!read_dib_fileheader(s, fileHeader)) return false; // read BMP info header if (!read_dib_infoheader(s, infoHeader)) return false; state = ReadHeader; return true; } bool QBmpHandler::canRead() const { if (state == Ready && !canRead(device())) return false; if (state != Error) { setFormat("bmp"); return true; } return false; } bool QBmpHandler::canRead(QIODevice *device) { if (!device) { qWarning("QBmpHandler::canRead() called with 0 pointer"); return false; } char head[2]; if (device->peek(head, sizeof(head)) != sizeof(head)) return false; return (qstrncmp(head, "BM", 2) == 0); } bool QBmpHandler::read(QImage *image) { if (state == Error) return false; if (!image) { qWarning("QBmpHandler::read: cannot read into null pointer"); return false; } if (state == Ready && !readHeader()) { state = Error; return false; } QIODevice *d = device(); QDataStream s(d); // Intel byte order s.setByteOrder(QDataStream::LittleEndian); // read image if (!read_dib_body(s, infoHeader, fileHeader.bfOffBits, startpos, *image)) return false; state = Ready; return true; } bool QBmpHandler::write(const QImage &img) { QImage image; switch (img.format()) { case QImage::Format_ARGB8565_Premultiplied: case QImage::Format_ARGB8555_Premultiplied: case QImage::Format_ARGB6666_Premultiplied: case QImage::Format_ARGB4444_Premultiplied: image = img.convertToFormat(QImage::Format_ARGB32); break; case QImage::Format_RGB16: case QImage::Format_RGB888: case QImage::Format_RGB666: case QImage::Format_RGB555: case QImage::Format_RGB444: image = img.convertToFormat(QImage::Format_RGB32); break; default: image = img; } QIODevice *d = device(); QDataStream s(d); BMP_FILEHDR bf; int bpl_bmp; int bpl = image.bytesPerLine(); // Code partially repeated in qt_write_dib if (image.depth() == 8 && image.colorCount() <= 16) { bpl_bmp = (((bpl+1)/2+3)/4)*4; } else if (image.depth() == 32) { bpl_bmp = ((image.width()*24+31)/32)*4; } else { bpl_bmp = bpl; } // Intel byte order s.setByteOrder(QDataStream::LittleEndian); // build file header memcpy(bf.bfType, "BM", 2); // write file header bf.bfReserved1 = 0; bf.bfReserved2 = 0; bf.bfOffBits = BMP_FILEHDR_SIZE + BMP_WIN + image.colorCount() * 4; bf.bfSize = bf.bfOffBits + bpl_bmp*image.height(); s << bf; // write image return qt_write_dib(s, image); } bool QBmpHandler::supportsOption(ImageOption option) const { return option == Size || option == ImageFormat; } QVariant QBmpHandler::option(ImageOption option) const { if (option == Size) { if (state == Error) return QVariant(); if (state == Ready && !const_cast(this)->readHeader()) return QVariant(); return QSize(infoHeader.biWidth, infoHeader.biHeight); } else if (option == ImageFormat) { if (state == Error) return QVariant(); if (state == Ready && !const_cast(this)->readHeader()) return QVariant(); QImage::Format format; switch (infoHeader.biBitCount) { case 32: case 24: case 16: format = QImage::Format_RGB32; break; case 8: case 4: format = QImage::Format_Indexed8; break; default: format = QImage::Format_Mono; } return format; } return QVariant(); } void QBmpHandler::setOption(ImageOption option, const QVariant &value) { Q_UNUSED(option); Q_UNUSED(value); } QByteArray QBmpHandler::name() const { return "bmp"; } QT_END_NAMESPACE #endif // QT_NO_IMAGEFORMAT_BMP