/* ============================================================ * * This file is a part of digiKam project * http://www.digikam.org * * Date : 2005-06-14 * Description : digiKam 8/16 bits image management API * * Copyright (C) 2005 by Renchi Raju * Copyright (C) 2005-2007 by Gilles Caulier * Copyright (C) 2006-2007 by Marcel Wiesweg * * This program is free software; you can redistribute it * and/or modify it under the terms of the GNU General * Public License as published by the Free Software Foundation; * either version 2, or (at your option) * any later version. * * This program 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 General Public License for more details. * * ============================================================ */ // C ANSI includes. extern "C" { #if !defined(__STDC_LIMIT_MACROS) #define __STDC_LIMIT_MACROS #endif #include } // C++ includes. #include // TQt includes. #include #include #include // LibKDcraw includes. #include #include #if KDCRAW_VERSION < 0x000106 #include #endif // Local includes. #include "pngloader.h" #include "jpegloader.h" #include "tiffloader.h" #include "ppmloader.h" #include "rawloader.h" #include "jp2kloader.h" #include "qimageloader.h" #include "icctransform.h" #include "exposurecontainer.h" #include "ddebug.h" #include "dimgprivate.h" #include "dimgloaderobserver.h" #include "dimg.h" typedef uint64_t ullong; typedef int64_t llong; namespace Digikam { DImg::DImg() : m_priv(new DImgPrivate) { } DImg::DImg(const TQCString& filePath, DImgLoaderObserver *observer, DRawDecoding rawDecodingSettings) : m_priv(new DImgPrivate) { load(filePath, observer, rawDecodingSettings); } DImg::DImg(const TQString& filePath, DImgLoaderObserver *observer, DRawDecoding rawDecodingSettings) : m_priv(new DImgPrivate) { load(filePath, observer, rawDecodingSettings); } DImg::DImg(const DImg& image) { m_priv = image.m_priv; m_priv->ref(); } DImg::DImg(uint width, uint height, bool sixteenBit, bool alpha, uchar* data, bool copyData) : m_priv(new DImgPrivate) { putImageData(width, height, sixteenBit, alpha, data, copyData); } DImg::DImg(const DImg &image, int w, int h) : m_priv(new DImgPrivate) { // This private constructor creates a copy of everything except the data. // The image size is set to the given values and a buffer corresponding to these values is allocated. // This is used by copy and scale. copyImageData(image.m_priv); copyMetaData(image.m_priv); setImageDimension(w, h); allocateData(); } DImg::DImg(const TQImage& image) : m_priv(new DImgPrivate) { if (!image.isNull()) { TQImage target = image.convertDepth(32); uint w = target.width(); uint h = target.height(); uchar* data = new uchar[w*h*4]; uint* sptr = (uint*)target.bits(); uchar* dptr = data; for (uint i = 0 ; i < w*h ; i++) { dptr[0] = tqBlue(*sptr); dptr[1] = tqGreen(*sptr); dptr[2] = tqRed(*sptr); dptr[3] = tqAlpha(*sptr); dptr += 4; sptr++; } putImageData(w, h, false, image.hasAlphaBuffer(), data, false); } } DImg::~DImg() { if (m_priv->deref()) delete m_priv; } //--------------------------------------------------------------------------------------------------- // data management DImg& DImg::operator=(const DImg& image) { if (m_priv == image.m_priv) return *this; if (m_priv->deref()) { delete m_priv; m_priv = 0; } m_priv = image.m_priv; m_priv->ref(); return *this; } bool DImg::operator==(const DImg& image) const { return m_priv == image.m_priv; } void DImg::reset(void) { if (m_priv->deref()) delete m_priv; m_priv = new DImgPrivate; } void DImg::detach() { // are we being shared? if (m_priv->count <= 1) { return; } DImgPrivate* old = m_priv; m_priv = new DImgPrivate; copyImageData(old); copyMetaData(old); if (old->data) { int size = allocateData(); memcpy(m_priv->data, old->data, size); } old->deref(); } void DImg::putImageData(uint width, uint height, bool sixteenBit, bool alpha, uchar *data, bool copyData) { // set image data, metadata is untouched bool null = (width == 0) || (height == 0); // allocateData, or code below will set null to false setImageData(true, width, height, sixteenBit, alpha); // replace data delete [] m_priv->data; if (null) { // image is null - no data m_priv->data = 0; } else if (copyData) { int size = allocateData(); if (data) memcpy(m_priv->data, data, size); } else { if (data) { m_priv->data = data; m_priv->null = false; } else allocateData(); } } void DImg::putImageData(uchar *data, bool copyData) { if (!data) { delete [] m_priv->data; m_priv->data = 0; m_priv->null = true; } else if (copyData) { memcpy(m_priv->data, data, numBytes()); } else { m_priv->data = data; } } void DImg::resetMetaData() { m_priv->attributes.clear(); m_priv->embeddedText.clear(); m_priv->metaData.clear(); } uchar *DImg::stripImageData() { uchar *data = m_priv->data; m_priv->data = 0; m_priv->null = true; return data; } void DImg::copyMetaData(const DImgPrivate *src) { m_priv->isReadOnly = src->isReadOnly; m_priv->attributes = src->attributes; m_priv->embeddedText = src->embeddedText; // since qbytearrays are explicitly shared, we need to make sure that they are // detached from any shared references for (TQMap::const_iterator it = src->metaData.begin(); it != src->metaData.end(); ++it) { m_priv->metaData.insert(it.key(), it.data().copy()); } } void DImg::copyImageData(const DImgPrivate *src) { setImageData(src->null, src->width, src->height, src->sixteenBit, src->alpha); } int DImg::allocateData() { int size = m_priv->width * m_priv->height * (m_priv->sixteenBit ? 8 : 4); m_priv->data = new uchar[size]; m_priv->null = false; return size; } void DImg::setImageDimension(uint width, uint height) { m_priv->width = width; m_priv->height = height; } void DImg::setImageData(bool null, uint width, uint height, bool sixteenBit, bool alpha) { m_priv->null = null; m_priv->width = width; m_priv->height = height; m_priv->alpha = alpha; m_priv->sixteenBit = sixteenBit; } //--------------------------------------------------------------------------------------------------- // load and save bool DImg::load(const TQString& filePath, DImgLoaderObserver *observer, DRawDecoding rawDecodingSettings) { FORMAT format = fileFormat(filePath); switch (format) { case(NONE): { DDebug() << filePath << " : Unknown image format !!!" << endl; return false; break; } case(JPEG): { DDebug() << filePath << " : JPEG file identified" << endl; JPEGLoader loader(this); if (loader.load(filePath, observer)) { m_priv->null = false; m_priv->alpha = loader.hasAlpha(); m_priv->sixteenBit = loader.sixteenBit(); m_priv->isReadOnly = loader.isReadOnly(); return true; } break; } case(TIFF): { DDebug() << filePath << " : TIFF file identified" << endl; TIFFLoader loader(this); if (loader.load(filePath, observer)) { m_priv->null = false; m_priv->alpha = loader.hasAlpha(); m_priv->sixteenBit = loader.sixteenBit(); m_priv->isReadOnly = loader.isReadOnly(); return true; } break; } case(PNG): { DDebug() << filePath << " : PNG file identified" << endl; PNGLoader loader(this); if (loader.load(filePath, observer)) { m_priv->null = false; m_priv->alpha = loader.hasAlpha(); m_priv->sixteenBit = loader.sixteenBit(); m_priv->isReadOnly = loader.isReadOnly(); return true; } break; } case(PPM): { DDebug() << filePath << " : PPM file identified" << endl; PPMLoader loader(this); if (loader.load(filePath, observer)) { m_priv->null = false; m_priv->alpha = loader.hasAlpha(); m_priv->sixteenBit = loader.sixteenBit(); m_priv->isReadOnly = loader.isReadOnly(); return true; } break; } case(RAW): { DDebug() << filePath << " : RAW file identified" << endl; RAWLoader loader(this, rawDecodingSettings); if (loader.load(filePath, observer)) { m_priv->null = false; m_priv->alpha = loader.hasAlpha(); m_priv->sixteenBit = loader.sixteenBit(); m_priv->isReadOnly = loader.isReadOnly(); return true; } break; } case(JP2K): { DDebug() << filePath << " : JPEG2000 file identified" << endl; JP2KLoader loader(this); if (loader.load(filePath, observer)) { m_priv->null = false; m_priv->alpha = loader.hasAlpha(); m_priv->sixteenBit = loader.sixteenBit(); m_priv->isReadOnly = loader.isReadOnly(); return true; } break; } default: { DDebug() << filePath << " : TQIMAGE file identified" << endl; TQImageLoader loader(this); if (loader.load(filePath, observer)) { m_priv->null = false; m_priv->alpha = loader.hasAlpha(); m_priv->sixteenBit = loader.sixteenBit(); m_priv->isReadOnly = loader.isReadOnly(); return true; } break; } } return false; } bool DImg::save(const TQString& filePath, const TQString& format, DImgLoaderObserver *observer) { if (isNull()) return false; if (format.isEmpty()) return false; TQString frm = format.upper(); if (frm == "JPEG" || frm == "JPG" || frm == "JPE") { JPEGLoader loader(this); return loader.save(filePath, observer); } else if (frm == "PNG") { PNGLoader loader(this); return loader.save(filePath, observer); } else if (frm == "TIFF" || frm == "TIF") { TIFFLoader loader(this); return loader.save(filePath, observer); } else if (frm == "PPM") { PPMLoader loader(this); return loader.save(filePath, observer); } if (frm == "JP2" || frm == "JPX" || frm == "JPC" || frm == "PGX") { JP2KLoader loader(this); return loader.save(filePath, observer); } else { setAttribute("format", format); TQImageLoader loader(this); return loader.save(filePath, observer); } return false; } DImg::FORMAT DImg::fileFormat(const TQString& filePath) { if ( filePath.isNull() ) return NONE; // In first we trying to check the file extension. This is mandatory because // some tiff files are detected like RAW files by dcraw::identify method. TQFileInfo fileInfo(filePath); if (!fileInfo.exists()) { DDebug() << k_funcinfo << "File \"" << filePath << "\" does not exist" << endl; return NONE; } #if KDCRAW_VERSION < 0x000106 TQString rawFilesExt(KDcrawIface::DcrawBinary::instance()->rawFiles()); #else TQString rawFilesExt(KDcrawIface::KDcraw::rawFiles()); #endif TQString ext = fileInfo.extension(false).upper(); if (!ext.isEmpty()) { if (ext == TQString("JPEG") || ext == TQString("JPG") || ext == TQString("JPE")) return JPEG; else if (ext == TQString("PNG")) return PNG; else if (ext == TQString("TIFF") || ext == TQString("TIF")) return TIFF; else if (rawFilesExt.upper().contains(ext)) return RAW; if (ext == TQString("JP2") || ext == TQString("JPX") || // JPEG2000 file format ext == TQString("JPC") || // JPEG2000 code stream ext == TQString("PGX")) // JPEG2000 WM format return JP2K; } // In second, we trying to parse file header. FILE* f = fopen(TQFile::encodeName(filePath), "rb"); if (!f) { DDebug() << k_funcinfo << "Failed to open file \"" << filePath << "\"" << endl; return NONE; } const int headerLen = 9; unsigned char header[headerLen]; if (fread(&header, headerLen, 1, f) != 1) { DDebug() << k_funcinfo << "Failed to read header of file \"" << filePath << "\"" << endl; fclose(f); return NONE; } fclose(f); KDcrawIface::DcrawInfoContainer dcrawIdentify; KDcrawIface::KDcraw::rawFileIdentify(dcrawIdentify, filePath); uchar jpegID[2] = { 0xFF, 0xD8 }; uchar tiffBigID[2] = { 0x4D, 0x4D }; uchar tiffLilID[2] = { 0x49, 0x49 }; uchar pngID[8] = { 0x89, 0x50, 0x4E, 0x47, 0x0D, 0x0A, 0x1A, 0x0A }; uchar jp2ID[5] = { 0x6A, 0x50, 0x20, 0x20, 0x0D, }; uchar jpcID[2] = { 0xFF, 0x4F }; if (memcmp(&header, &jpegID, 2) == 0) // JPEG file ? { return JPEG; } else if (memcmp(&header, &pngID, 8) == 0) // PNG file ? { return PNG; } else if (memcmp(&header[0], "P", 1) == 0 && memcmp(&header[2], "\n", 1) == 0) // PPM 16 bits file ? { int width, height, rgbmax; char nl; FILE *file = fopen(TQFile::encodeName(filePath), "rb"); if (fscanf (file, "P6 %d %d %d%c", &width, &height, &rgbmax, &nl) == 4) { if (rgbmax > 255) { pclose (file); return PPM; } } pclose (file); } else if (dcrawIdentify.isDecodable) { // RAW File test using dcraw::identify method. // Need to test it before TIFF because any RAW file // formats using TIFF header. return RAW; } else if (memcmp(&header, &tiffBigID, 2) == 0 || // TIFF file ? memcmp(&header, &tiffLilID, 2) == 0) { return TIFF; } else if (memcmp(&header[4], &jp2ID, 5) == 0 || // JPEG2000 file ? memcmp(&header, &jpcID, 2) == 0) { return JP2K; } // In others cases, TQImage will be used to try to open file. return TQIMAGE; } //--------------------------------------------------------------------------------------------------- // accessing properties bool DImg::isNull() const { return m_priv->null; } uint DImg::width() const { return m_priv->width; } uint DImg::height() const { return m_priv->height; } TQSize DImg::size() const { return TQSize(m_priv->width, m_priv->height); } uchar* DImg::bits() const { return m_priv->data; } uchar* DImg::scanLine(uint i) const { if ( i >= height() ) return 0; uchar *data = bits() + (width() * bytesDepth() * i); return data; } bool DImg::hasAlpha() const { return m_priv->alpha; } bool DImg::sixteenBit() const { return m_priv->sixteenBit; } bool DImg::isReadOnly() const { return m_priv->isReadOnly; } bool DImg::getICCProfilFromFile(const TQString& filePath) { TQFile file(filePath); if ( !file.open(IO_ReadOnly) ) return false; TQByteArray data(file.size()); TQDataStream stream( &file ); stream.readRawBytes(data.data(), data.size()); setICCProfil(data); file.close(); return true; } bool DImg::setICCProfilToFile(const TQString& filePath) { TQFile file(filePath); if ( !file.open(IO_WriteOnly) ) return false; TQByteArray data(getICCProfil()); TQDataStream stream( &file ); stream.writeRawBytes(data.data(), data.size()); file.close(); return true; } TQByteArray DImg::getComments() const { return metadata(COM); } TQByteArray DImg::getExif() const { return metadata(EXIF); } TQByteArray DImg::getIptc() const { return metadata(IPTC); } TQByteArray DImg::getICCProfil() const { return metadata(ICC); } void DImg::setComments(const TQByteArray& commentsData) { m_priv->metaData.replace(COM, commentsData); } void DImg::setExif(const TQByteArray& exifData) { m_priv->metaData.replace(EXIF, exifData); } void DImg::setIptc(const TQByteArray& iptcData) { m_priv->metaData.replace(IPTC, iptcData); } void DImg::setICCProfil(const TQByteArray& profile) { m_priv->metaData.replace(ICC, profile); } TQByteArray DImg::metadata(DImg::METADATA key) const { typedef TQMap MetaDataMap; for (MetaDataMap::iterator it = m_priv->metaData.begin(); it != m_priv->metaData.end(); ++it) { if (it.key() == key) return it.data(); } return TQByteArray(); } uint DImg::numBytes() const { return (width() * height() * bytesDepth()); } uint DImg::numPixels() const { return (width() * height()); } int DImg::bytesDepth() const { if (sixteenBit()) return 8; return 4; } int DImg::bitsDepth() const { if (sixteenBit()) return 16; return 8; } void DImg::setAttribute(const TQString& key, const TQVariant& value) { m_priv->attributes.insert(key, value); } TQVariant DImg::attribute(const TQString& key) const { if (m_priv->attributes.contains(key)) return m_priv->attributes[key]; return TQVariant(); } void DImg::setEmbeddedText(const TQString& key, const TQString& text) { m_priv->embeddedText.insert(key, text); } TQString DImg::embeddedText(const TQString& key) const { if (m_priv->embeddedText.contains(key)) return m_priv->embeddedText[key]; return TQString(); } DColor DImg::getPixelColor(uint x, uint y) const { if (isNull() || x > width() || y > height()) { DDebug() << k_funcinfo << " : wrong pixel position!" << endl; return DColor(); } uchar *data = bits() + x*bytesDepth() + (width()*y*bytesDepth()); return( DColor(data, sixteenBit()) ); } void DImg::setPixelColor(uint x, uint y, DColor color) { if (isNull() || x > width() || y > height()) { DDebug() << k_funcinfo << " : wrong pixel position!" << endl; return; } if (color.sixteenBit() != sixteenBit()) { DDebug() << k_funcinfo << " : wrong color depth!" << endl; return; } uchar *data = bits() + x*bytesDepth() + (width()*y*bytesDepth()); color.setPixel(data); } //--------------------------------------------------------------------------------------------------- // copying operations DImg DImg::copy() { DImg img(*this); img.detach(); return img; } DImg DImg::copyImageData() { DImg img(width(), height(), sixteenBit(), hasAlpha(), bits(), true); return img; } DImg DImg::copyMetaData() { DImg img; // copy width, height, alpha, sixteenBit, null img.copyImageData(m_priv); // deeply copy metadata img.copyMetaData(m_priv); // set image to null img.m_priv->null = true; return img; } DImg DImg::copy(TQRect rect) { return copy(rect.x(), rect.y(), rect.width(), rect.height()); } DImg DImg::copy(int x, int y, int w, int h) { if ( isNull() || w <= 0 || h <= 0) { DDebug() << k_funcinfo << " : return null image!" << endl; return DImg(); } DImg image(*this, w, h); image.bitBltImage(this, x, y, w, h, 0, 0); return image; } //--------------------------------------------------------------------------------------------------- // bitwise operations void DImg::bitBltImage(const DImg* src, int dx, int dy) { bitBltImage(src, 0, 0, src->width(), src->height(), dx, dy); } void DImg::bitBltImage(const DImg* src, int sx, int sy, int dx, int dy) { bitBltImage(src, sx, sy, src->width() - sx, src->height() - sy, dx, dy); } void DImg::bitBltImage(const DImg* src, int sx, int sy, int w, int h, int dx, int dy) { if (isNull()) return; if (src->sixteenBit() != sixteenBit()) { DWarning() << "Blitting from 8-bit to 16-bit or vice versa is not supported" << endl; return; } if (w == -1 && h == -1) { w = src->width(); h = src->height(); } bitBlt(src->bits(), bits(), sx, sy, w, h, dx, dy, src->width(), src->height(), width(), height(), sixteenBit(), src->bytesDepth(), bytesDepth()); } void DImg::bitBltImage(const uchar* src, int sx, int sy, int w, int h, int dx, int dy, uint swidth, uint sheight, int sdepth) { if (isNull()) return; if (bytesDepth() != sdepth) { DWarning() << "Blitting from 8-bit to 16-bit or vice versa is not supported" << endl; return; } if (w == -1 && h == -1) { w = swidth; h = sheight; } bitBlt(src, bits(), sx, sy, w, h, dx, dy, swidth, sheight, width(), height(), sixteenBit(), sdepth, bytesDepth()); } bool DImg::normalizeRegionArguments(int &sx, int &sy, int &w, int &h, int &dx, int &dy, uint swidth, uint sheight, uint dwidth, uint dheight) { if (sx < 0) { // sx is negative, so + is - and - is + dx -= sx; w += sx; sx = 0; } if (sy < 0) { dy -= sy; h += sy; sy = 0; } if (dx < 0) { sx -= dx; w += dx; dx = 0; } if (dy < 0) { sy -= dy; h += dy; dy = 0; } if (sx + w > (int)swidth) { w = swidth - sx; } if (sy + h > (int)sheight) { h = sheight - sy; } if (dx + w > (int)dwidth) { w = dwidth - dx; } if (dy + h > (int)dheight) { h = dheight - dy; } // Nothing left to copy if (w <= 0 || h <= 0) return false; return true; } void DImg::bitBlt (const uchar *src, uchar *dest, int sx, int sy, int w, int h, int dx, int dy, uint swidth, uint sheight, uint dwidth, uint dheight, bool /*sixteenBit*/, int sdepth, int ddepth) { // Normalize if (!normalizeRegionArguments(sx, sy, w, h, dx, dy, swidth, sheight, dwidth, dheight)) return; // Same pixels if (src == dest && dx==sx && dy==sy) return; const uchar *sptr; uchar *dptr; uint slinelength = swidth * sdepth; uint dlinelength = dwidth * ddepth; int scurY = sy; int dcurY = dy; for (int j = 0 ; j < h ; j++, scurY++, dcurY++) { sptr = &src [ scurY * slinelength ] + sx * sdepth; dptr = &dest[ dcurY * dlinelength ] + dx * ddepth; // plain and simple bitBlt for (int i = 0; i < w * sdepth ; i++, sptr++, dptr++) { *dptr = *sptr; } } } void DImg::bitBlendImage(DColorComposer *composer, const DImg* src, int sx, int sy, int w, int h, int dx, int dy, DColorComposer::MultiplicationFlags multiplicationFlags) { if (isNull()) return; if (src->sixteenBit() != sixteenBit()) { DWarning() << "Blending from 8-bit to 16-bit or vice versa is not supported" << endl; return; } bitBlend(composer, src->bits(), bits(), sx, sy, w, h, dx, dy, src->width(), src->height(), width(), height(), sixteenBit(), src->bytesDepth(), bytesDepth(), multiplicationFlags); } void DImg::bitBlend (DColorComposer *composer, const uchar *src, uchar *dest, int sx, int sy, int w, int h, int dx, int dy, uint swidth, uint sheight, uint dwidth, uint dheight, bool sixteenBit, int sdepth, int ddepth, DColorComposer::MultiplicationFlags multiplicationFlags) { // Normalize if (!normalizeRegionArguments(sx, sy, w, h, dx, dy, swidth, sheight, dwidth, dheight)) return; const uchar *sptr; uchar *dptr; uint slinelength = swidth * sdepth; uint dlinelength = dwidth * ddepth; int scurY = sy; int dcurY = dy; for (int j = 0 ; j < h ; j++, scurY++, dcurY++) { sptr = &src [ scurY * slinelength ] + sx * sdepth; dptr = &dest[ dcurY * dlinelength ] + dx * ddepth; // blend src and destination for (int i = 0 ; i < w ; i++, sptr+=sdepth, dptr+=ddepth) { DColor src(sptr, sixteenBit); DColor dst(dptr, sixteenBit); // blend colors composer->compose(dst, src, multiplicationFlags); dst.setPixel(dptr); } } } //--------------------------------------------------------------------------------------------------- // TQImage / TQPixmap access TQImage DImg::copyTQImage() { if (isNull()) return TQImage(); if (sixteenBit()) { DImg img(*this); img.detach(); img.convertDepth(32); return img.copyTQImage(); } TQImage img(width(), height(), 32); uchar* sptr = bits(); uint* dptr = (uint*)img.bits(); for (uint i=0; i < width()*height(); i++) { *dptr++ = tqRgba(sptr[2], sptr[1], sptr[0], sptr[3]); sptr += 4; } if (hasAlpha()) { img.setAlphaBuffer(true); } return img; } TQImage DImg::copyTQImage(TQRect rect) { return (copyTQImage(rect.x(), rect.y(), rect.width(), rect.height())); } TQImage DImg::copyTQImage(int x, int y, int w, int h) { if (isNull()) return TQImage(); DImg img = copy(x, y, w, h); if (img.sixteenBit()) img.convertDepth(32); return img.copyTQImage(); } TQPixmap DImg::convertToPixmap() { if (isNull()) return TQPixmap(); if (sixteenBit()) { // make fastaaaa.. return TQPixmap(copyTQImage(0, 0, width(), height())); } if (TQImage::systemByteOrder() == TQImage::BigEndian) { TQImage img(width(), height(), 32); uchar* sptr = bits(); uint* dptr = (uint*)img.bits(); for (uint i=0; ihasOutputProfile()) { DDebug() << k_funcinfo << " : no monitor ICC profile available!" << endl; return convertToPixmap(); } DImg img = copy(); // Without embedded profile if (img.getICCProfil().isNull()) { TQByteArray fakeProfile; monitorICCtrans->apply(img, fakeProfile, monitorICCtrans->getRenderingIntent(), monitorICCtrans->getUseBPC(), false, monitorICCtrans->inputProfile().isNull()); } // With embedded profile. else { monitorICCtrans->getEmbeddedProfile( img ); monitorICCtrans->apply( img ); } return (img.convertToPixmap()); } TQImage DImg::pureColorMask(ExposureSettingsContainer *expoSettings) { if (isNull() || (!expoSettings->underExposureIndicator && !expoSettings->overExposureIndicator)) return TQImage(); TQImage img(size(), 32); img.fill(0x00000000); // Full transparent. img.setAlphaBuffer(true); uchar *bits = img.bits(); int max = sixteenBit() ? 65535 : 255; int index; DColor pix; for (uint x=0 ; x < width() ; x++) { for (uint y=0 ; yunderExposureIndicator && pix.red() == 0 && pix.green() == 0 && pix.blue() == 0) { bits[index ] = expoSettings->underExposureColor.blue(); bits[index + 1] = expoSettings->underExposureColor.green(); bits[index + 2] = expoSettings->underExposureColor.red(); bits[index + 3] = 0xFF; } if (expoSettings->overExposureIndicator && pix.red() == max && pix.green() == max && pix.blue() == max) { bits[index ] = expoSettings->overExposureColor.blue(); bits[index + 1] = expoSettings->overExposureColor.green(); bits[index + 2] = expoSettings->overExposureColor.red(); bits[index + 3] = 0xFF; } } } return img; } //--------------------------------------------------------------------------------------------------- // basic imaging operations void DImg::crop(TQRect rect) { crop(rect.x(), rect.y(), rect.width(), rect.height()); } void DImg::crop(int x, int y, int w, int h) { if ( isNull() || w <= 0 || h <= 0) return; uint oldw = width(); uint oldh = height(); uchar *old = stripImageData(); // set new image data, bits(), width(), height() change setImageDimension(w, h); allocateData(); // copy image region (x|y), wxh, from old data to point (0|0) of new data bitBlt(old, bits(), x, y, w, h, 0, 0, oldw, oldh, width(), height(), sixteenBit(), bytesDepth(), bytesDepth()); delete [] old; } void DImg::resize(int w, int h) { if ( w <= 0 || h <= 0) return; DImg image = smoothScale(w, h); delete [] m_priv->data; m_priv->data = image.stripImageData(); setImageDimension(w, h); } void DImg::rotate(ANGLE angle) { if (isNull()) return; switch (angle) { case(ROT90): { uint w = height(); uint h = width(); if (sixteenBit()) { ullong* newData = new ullong[w*h]; ullong *from = (ullong*) m_priv->data; ullong *to; for (int y = w-1; y >=0; y--) { to = newData + y; for (uint x=0; x < h; x++) { *to = *from++; to += w; } } setImageDimension(w, h); delete [] m_priv->data; m_priv->data = (uchar*)newData; } else { uint* newData = new uint[w*h]; uint *from = (uint*) m_priv->data; uint *to; for (int y = w-1; y >=0; y--) { to = newData + y; for (uint x=0; x < h; x++) { *to = *from++; to += w; } } setImageDimension(w, h); delete [] m_priv->data; m_priv->data = (uchar*)newData; } break; } case(ROT180): { uint w = width(); uint h = height(); int middle_line = -1; if (h % 2) middle_line = h / 2; if (sixteenBit()) { ullong *line1; ullong *line2; ullong* data = (ullong*) bits(); ullong tmp; // can be done inplace for (uint y = 0; y < (h+1)/2; y++) { line1 = data + y * w; line2 = data + (h-y) * w; for (uint x=0; x < w; x++) { tmp = *line1; *line1 = *line2; *line2 = tmp; line1++; line2--; if ((int)y == middle_line && x * 2 >= w) break; } } } else { uint *line1; uint *line2; uint* data = (uint*) bits(); uint tmp; // can be done inplace for (uint y = 0; y < (h+1)/2; y++) { line1 = data + y * w; line2 = data + (h-y) * w; for (uint x=0; x < w; x++) { tmp = *line1; *line1 = *line2; *line2 = tmp; line1++; line2--; if ((int)y == middle_line && x * 2 >= w) break; } } } break; } case(ROT270): { uint w = height(); uint h = width(); if (sixteenBit()) { ullong* newData = new ullong[w*h]; ullong *from = (ullong*) m_priv->data; ullong *to; for (uint y = 0; y < w; y++) { to = newData + y + w*(h-1); for (uint x=0; x < h; x++) { *to = *from++; to -= w; } } setImageDimension(w, h); delete [] m_priv->data; m_priv->data = (uchar*)newData; } else { uint* newData = new uint[w*h]; uint *from = (uint*) m_priv->data; uint *to; for (uint y = 0; y < w; y++) { to = newData + y + w*(h-1); for (uint x=0; x < h; x++) { *to = *from++; to -= w; } } setImageDimension(w, h); delete [] m_priv->data; m_priv->data = (uchar*)newData; } break; } default: break; } } // 15-11-2005: This method have been tested indeep with valgrind by Gilles. void DImg::flip(FLIP direction) { if (isNull()) return; switch (direction) { case(HORIZONTAL): { uint w = width(); uint h = height(); if (sixteenBit()) { unsigned short tmp[4]; unsigned short *beg; unsigned short *end; unsigned short * data = (unsigned short *)bits(); // can be done inplace for (uint y = 0 ; y < h ; y++) { beg = data + y * w * 4; end = beg + (w-1) * 4; for (uint x=0 ; x < (w/2) ; x++) { memcpy(&tmp, beg, 8); memcpy(beg, end, 8); memcpy(end, &tmp, 8); beg+=4; end-=4; } } } else { uchar tmp[4]; uchar *beg; uchar *end; uchar* data = bits(); // can be done inplace for (uint y = 0 ; y < h ; y++) { beg = data + y * w * 4; end = beg + (w-1) * 4; for (uint x=0 ; x < (w/2) ; x++) { memcpy(&tmp, beg, 4); memcpy(beg, end, 4); memcpy(end, &tmp, 4); beg+=4; end-=4; } } } break; } case(VERTICAL): { uint w = width(); uint h = height(); if (sixteenBit()) { unsigned short tmp[4]; unsigned short *line1; unsigned short *line2; unsigned short* data = (unsigned short*) bits(); // can be done inplace for (uint y = 0 ; y < (h/2) ; y++) { line1 = data + y * w * 4; line2 = data + (h-y-1) * w * 4; for (uint x=0 ; x < w ; x++) { memcpy(&tmp, line1, 8); memcpy(line1, line2, 8); memcpy(line2, &tmp, 8); line1+=4; line2+=4; } } } else { uchar tmp[4]; uchar *line1; uchar *line2; uchar* data = bits(); // can be done inplace for (uint y = 0 ; y < (h/2) ; y++) { line1 = data + y * w * 4; line2 = data + (h-y-1) * w * 4; for (uint x=0 ; x < w ; x++) { memcpy(&tmp, line1, 4); memcpy(line1, line2, 4); memcpy(line2, &tmp, 4); line1+=4; line2+=4; } } } break; } default: break; } } void DImg::convertToSixteenBit() { convertDepth(64); } void DImg::convertToEightBit() { convertDepth(32); } void DImg::convertToDepthOfImage(const DImg *otherImage) { if (otherImage->sixteenBit()) convertToSixteenBit(); else convertToEightBit(); } void DImg::convertDepth(int depth) { if (isNull()) return; if (depth != 32 && depth != 64) { DDebug() << k_funcinfo << " : wrong color depth!" << endl; return; } if (((depth == 32) && !sixteenBit()) || ((depth == 64) && sixteenBit())) return; if (depth == 32) { // downgrading from 16 bit to 8 bit uchar* data = new uchar[width()*height()*4]; uchar* dptr = data; ushort* sptr = (ushort*)bits(); for (uint i=0; idata; m_priv->data = data; m_priv->sixteenBit = false; } else if (depth == 64) { // upgrading from 8 bit to 16 bit uchar* data = new uchar[width()*height()*8]; ushort* dptr = (ushort*)data; uchar* sptr = bits(); for (uint i=0; idata; m_priv->data = data; m_priv->sixteenBit = true; } } void DImg::fill(DColor color) { if (sixteenBit()) { unsigned short *imgData16 = (unsigned short *)m_priv->data; for (uint i = 0 ; i < width()*height()*4 ; i+=4) { imgData16[ i ] = (unsigned short)color.blue(); imgData16[i+1] = (unsigned short)color.green(); imgData16[i+2] = (unsigned short)color.red(); imgData16[i+3] = (unsigned short)color.alpha(); } } else { uchar *imgData = m_priv->data; for (uint i = 0 ; i < width()*height()*4 ; i+=4) { imgData[ i ] = (uchar)color.blue(); imgData[i+1] = (uchar)color.green(); imgData[i+2] = (uchar)color.red(); imgData[i+3] = (uchar)color.alpha(); } } } } // NameSpace Digikam