示例#1
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ColorLevels::LAB
ColorLevels::LABColorToLAB(
    const Magick::ColorRGB &magickLAB)
{
	return (LAB{
	    magickLAB.red() * 100,
	    (magickLAB.green() * 256) - 100, 
	    (magickLAB.blue() * 256) - 100
	});
}
示例#2
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/** \brief Checks if the given Pixel is empty (not used). It is empty, if least significant bits are all 0.
 * \param pixel const Pixel& the pixel that should be checked
 * \return bool true if pixel is not used until now, else false
 */
bool SteganoHide::isPixelEmpty(const Pixel &pixel) {
    Magick::ColorRGB pixelColor = this->steganoImage.pixelColor(pixel.x, pixel.y);

    const unsigned char redLeastSignificantBit = convert16BitTo8BitRGB(pixelColor.redQuantum()) % 10;
    const unsigned char greenLeastSignificantBit = convert16BitTo8BitRGB(pixelColor.greenQuantum()) % 10;
    const unsigned char blueLeastSignificantBit = convert16BitTo8BitRGB(pixelColor.blueQuantum()) % 10;
  //  std::cout << (int)redLeastSignificantBit << ":" << (int)greenLeastSignificantBit << ":" << (int)blueLeastSignificantBit << std::endl;

    return (redLeastSignificantBit == 5 && greenLeastSignificantBit == 5 && blueLeastSignificantBit == 5);
}
示例#3
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Image<Color> imread(const std::string& file) {
    Magick::Image image(file);
    const size_t w = image.columns();
    const size_t h = image.rows();
    Magick::PixelPacket* pixels = image.getPixels(0, 0, w, h);
    Image<Color> rtn(h, w);
    for (size_t i = 0; i < w * h; ++i) {
        Magick::ColorRGB p = Magick::ColorRGB(pixels[i]);
        rtn(i) = Color(double(p.red()), double(p.green()), double(p.blue()));
    }
    return rtn;
}
示例#4
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/** \brief Draw a finish pixel at the specified position. The finishpixel has at the least-significant bit of their rgb-value r: 3, g: 0, b: 0
 *
 * \param &pixel const Pixel a pixel-struct describing the pixel-position where the finish-pixel should be set.
 */
void SteganoHide::drawFinishPixel(const Pixel &pixel) {
    Magick::ColorRGB pixelColor = this->steganoImage.pixelColor(pixel.x, pixel.y);

    RGB pixelRGB(convert16BitTo8BitRGB(pixelColor.redQuantum()),
                 convert16BitTo8BitRGB(pixelColor.greenQuantum()),
                 convert16BitTo8BitRGB(pixelColor.blueQuantum()));

    pixelRGB.red = (pixelRGB.red - (pixelRGB.red % 10)) + 3;
    pixelRGB.green = pixelRGB.green - (pixelRGB.green % 10);
    pixelRGB.blue = pixelRGB.blue - (pixelRGB.blue % 10);

    this->steganoImage.pixelColor(pixel.x, pixel.y, Magick::ColorRGB(pixelRGB.toString()));
}
示例#5
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static void compare_colors(const Magick::ColorRGB & expected, const Magick::ColorRGB & observed, bool expected_has_alpha, bool observed_has_alpha ) {
    ASSERT_NEAR(expected.red(), observed.red(), 1.1f/(0x1<<8));
    ASSERT_NEAR(expected.green(), observed.green(), 1.1f/(0x1<<8));
    ASSERT_NEAR(expected.blue(), observed.blue(), 1.1f/(0x1<<8));
    if (expected_has_alpha) {
        ASSERT_NEAR(expected.alpha(), observed.alpha(), 1.1f / (0x1 << 8));
    }
    else if (observed_has_alpha) {
        ASSERT_NEAR(1.0f, observed.alpha(), 1.1f /(0x1 << 8));
    }
}
示例#6
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//Konverterer Magick::Image til QImage
QImage* image_wrapper::to_QImage(Magick::Image& image)
{
    qimg_ptr_helper = new QImage(image.columns(), image.rows(), QImage::Format_RGB32);
    const Magick::PixelPacket *pixels;
    Magick::ColorRGB rgb;
    for (int y = 0; y < qimg_ptr_helper->height(); y++) {
        pixels = image.getConstPixels(0, y, qimg_ptr_helper->width(), 1);
        for (int x = 0; x < qimg_ptr_helper->width(); x++) {
            rgb = (*(pixels + x));
            qimg_ptr_helper->setPixel(x, y, QColor((int) (255 * rgb.red())
                                             , (int) (255 * rgb.green())
                                             , (int) (255 * rgb.blue())).rgb());
        }
    }
    return qimg_ptr_helper;
}
示例#7
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yuv_image magick_wrapper::xyuv_to_yuv_image_444(const xyuv::conversion_matrix &conversion_matrix) const {
    // Analyse the conversion matrix to discover if any plane is not present.
    bool has[3] = {false, false, false};
    for (uint32_t i = 0; i < 9; i++) {
        has[i / 3] = has[i / 3] || (conversion_matrix.rgb_to_yuv[i] != static_cast<pixel_quantum>(0));
    }
    bool has_a = image.matte();


    yuv_image image_out = create_yuv_image_444(
            static_cast<uint32_t>(image.columns()),
            static_cast<uint32_t>(image.rows()),
            has[channel::Y],
            has[channel::U],
            has[channel::V],
            has_a);


    // Create pixels with default values.
    // Note that this hides the lack of planes.
    rgb_color rgb;
    yuv_color yuv;

    const Magick::PixelPacket *pixels = image.getConstPixels(0, 0, image.columns(), image.rows());

    for (uint32_t y = 0; y < image_out.image_h; y++) {
        for (uint32_t x = 0; x < image_out.image_w; x++) {
            // Fetch color from ImageMagick
            const Magick::ColorRGB magick_rgb = Magick::Color(pixels[y * image.columns() + x]);
            rgb.r = static_cast<float>(magick_rgb.red());
            rgb.g = static_cast<float>(magick_rgb.green());
            rgb.b = static_cast<float>(magick_rgb.blue());
            // Imagemagick stores alpha as 0.0 = opaque
            rgb.a = static_cast<float>(1.0-magick_rgb.alpha());

            // Convert to yuv.
            to_yuv(&yuv, rgb, conversion_matrix);

            // Assign pixel
            set_yuv_color(image_out, yuv, x, y);
        }
    }
    // No syncing needed.

    return image_out;
}
示例#8
0
/** \brief Normalize the loaded image.(set all least significant bits of all RGB-Values to 0).
 * This change takes effect only while editing the picture. In the exported image, all pixel have their old value (except the edited ones).
 * This is needed to differentiate between edited and not edited pixel.
 */
void SteganoHide::normalizeImage() {
    for(unsigned int xValue = 0; xValue < this->xResolution; xValue++) {
        for(unsigned int yValue = 0; yValue < this->yResolution; yValue++) {
            Magick::ColorRGB curPixelColor = this->steganoImage.pixelColor(xValue, yValue);


            RGB curPixelRGB(convert16BitTo8BitRGB(curPixelColor.redQuantum()),
                            convert16BitTo8BitRGB(curPixelColor.greenQuantum()),
                            convert16BitTo8BitRGB(curPixelColor.blueQuantum()));
            RGB curPixelRoundedRGB(curPixelRGB.red - (curPixelRGB.red % 10) + 5,
                                   curPixelRGB.green - (curPixelRGB.green % 10) + 5,
                                   curPixelRGB.blue - (curPixelRGB.blue % 10) + 5);
            this->steganoImage.pixelColor(xValue, yValue, Magick::ColorRGB(curPixelRoundedRGB.toString()));
        }
        this->doneBytes += this->yResolution;
    }
}
示例#9
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//Konverterer et QImage til Magick::Image
void image_wrapper::to_Image(QImage& qimage)
{

    img_ptr_current = new Magick::Image(Magick::Geometry(qimage.width(), qimage.height()), Magick::ColorRGB(0.5, 0.2, 0.3));

    double scale = 1 / 256.0;
    img_ptr_current->modifyImage();
    Magick::PixelPacket *pixels;
    Magick::ColorRGB mgc;
    for (int y = 0; y < qimage.height(); y++) {
        pixels = img_ptr_current->setPixels(0, y, img_ptr_current->columns(), 1);
        for (int x = 0; x < qimage.width(); x++) {
            QColor pix = qimage.pixel(x, y);

            mgc.red(scale *pix.red());
            mgc.green(scale *pix.green());
            mgc.blue(scale *pix.blue());
            *pixels++ = mgc;
        }
        img_ptr_current->syncPixels();
    }
}
示例#10
0
 // TODO: handle wrong input
bool SteganoHide::hideNumberInMagickColorRGB(const unsigned short &smallNumber, Magick::ColorRGB &color) {
    RGB pixelRGB(convert16BitTo8BitRGB(color.redQuantum()),
                 convert16BitTo8BitRGB(color.greenQuantum()),
                 convert16BitTo8BitRGB(color.blueQuantum()));

    RGB roundedRGB;
    roundedRGB.red = pixelRGB.red - (pixelRGB.red % 10);
    roundedRGB.green = pixelRGB.green - (pixelRGB.green % 10);
    roundedRGB.blue = pixelRGB.blue - (pixelRGB.blue % 10);

    unsigned char mostSignificantBit = std::floor(smallNumber / 100);
    unsigned char middleSigificantBit = std::floor(smallNumber % 100 / 10);
    unsigned char leastSignificantBit = smallNumber % 10;

   /* if(mostSignificantBit > 5 || middleSigificantBit > 5 || leastSignificantBit > 5) {
        throw hideNumber2Big;
    }*/

    // there was an overflow: eg. roundedRGB.blue = 250 and leastSignificantLetterBit = 8 => 258 => 2
    // This way to check overflow is possible, because *SignificantLetterBit >= 0
    if(roundedRGB.green + middleSigificantBit > 255) {
        return false;
    }
    if(roundedRGB.blue + leastSignificantBit > 255) {
        return false;
    }



   // std::cout << (int)roundedRGB.blue << "+" << (int)leastSignificantBit << "=";
    roundedRGB.red += mostSignificantBit;
    roundedRGB.green += middleSigificantBit;
    roundedRGB.blue += leastSignificantBit;
    //std::cout << (int)roundedRGB.blue << std::endl;

    color = Magick::ColorRGB(roundedRGB.toString());
    return true;
}
示例#11
0
// TODO: shorten this method and outsource some inner methods and add header comment
std::stringstream SteganoExpose::unhidePhrase(const std::string &password)
{
    if(!this->steganoImage.isValid())
    {
        throw SteganoException::UnhideFileNotSpecified();
    }

    this->exposeFinished = false;
    Chunk hiddenChunk("vaPh");
    std::cout << this->steganoImage.baseFilename() << std::endl;
    PrivateChunk privChunk(this->steganoImage.baseFilename(), "./omg.png");
    char *chunkData = new char[privChunk.getChunkSize(hiddenChunk)];
    privChunk.readChunk(hiddenChunk, chunkData);
    commentReaderStream.str(chunkData);
    calculateNextShift();

    Pixel curPixel(0, 0);
    std::stringstream returnPhrase;
    for(unsigned int runCounter = 0; ; runCounter++)
    {
        curPixel.x = 0;
        curPixel.y = 0;
        int_least64_t steps = quadraticSondation(runCounter, this->xResolution * this->yResolution);
        //   std::cout << "Push by" << steps << std::endl;
        pushPixelBy(curPixel, steps);
        //  std::cout << curPixel.x << ":" << curPixel.y << std::endl;

        if(runCounter == shiftIndex)
        {
            pushPixelBy(curPixel, shiftAmount);
            calculateNextShift();
        }
        // std::cout << curPixel.x << "::" << curPixel.y << std::endl;
        Magick::ColorRGB curPixelColor = this->steganoImage.pixelColor(curPixel.x, curPixel.y);

        unsigned char redLeastSignificantBit = convert16BitTo8BitRGB(curPixelColor.redQuantum()) % 10;
        unsigned char greenLeastSignificantBit = convert16BitTo8BitRGB(curPixelColor.greenQuantum()) % 10;
        unsigned char blueLeastSignificantBit = convert16BitTo8BitRGB(curPixelColor.blueQuantum()) % 10;

        // there was an overflow at the pixel color. we need to handle it special.
        unsigned char decryptedChar = 0;
        if(redLeastSignificantBit == 4)
        {
            decryptedChar += greenLeastSignificantBit * 10;
            decryptedChar += blueLeastSignificantBit;
            incrementPixel(curPixel);

            curPixelColor = this->steganoImage.pixelColor(curPixel.x, curPixel.y);
            redLeastSignificantBit = convert16BitTo8BitRGB(curPixelColor.redQuantum()) % 10;
            greenLeastSignificantBit = convert16BitTo8BitRGB(curPixelColor.greenQuantum()) % 10;
            blueLeastSignificantBit = convert16BitTo8BitRGB(curPixelColor.blueQuantum()) % 10;
            decryptedChar += redLeastSignificantBit * 100;
            decryptedChar += greenLeastSignificantBit * 10;
            decryptedChar += blueLeastSignificantBit;
        }
        else
        {
            decryptedChar = redLeastSignificantBit * 100;
            decryptedChar += greenLeastSignificantBit * 10;
            decryptedChar += blueLeastSignificantBit;
        }
        if(isFinishPixel(curPixel))
        {
            break;
        }
        returnPhrase << decryptedChar;
    }
    this->exposeFinished = true;
    return returnPhrase;
}