Java Code Examples for java.awt.image.BufferedImage#getTransparency()

public cfData execute( cfSession _session, cfArgStructData argStruct ) throws cfmRunTimeException{
	cfImageData im	= getImage( _session, argStruct );
	
	int thickness	= getNamedIntParam(argStruct, "thickness", 0 );
	if ( thickness == 0 )
		throwException(_session, "please specify a thickness greater than zero (0)" );
	
	String bordertype = getNamedStringParam(argStruct, "type", "constant" ).trim();
	if ( !bordertype.equals("constant") && !bordertype.equals("zero") )	{
		throwException(_session, "type must be 'constant' or 'zero'" );
	}
	
	Color color;
	if ( bordertype.equals("zero") ){
		color = Color.black;
	}else{
		color	= colour.getColor( getNamedStringParam(argStruct, "color", "black") );
	}
	
	int targetWidth		= im.getWidth() + ( thickness*2 );
	int targetHeight	= im.getHeight() + ( thickness*2 );
	
	BufferedImage	img = im.getImage();
	int type = (img.getTransparency() == Transparency.OPAQUE) ? BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB;
	BufferedImage tmp = new BufferedImage(targetWidth, targetHeight, type);
	Graphics2D g2 = tmp.createGraphics();
	
	g2.setBackground(color);
	g2.clearRect(0, 0, targetWidth, targetHeight );
	g2.translate(thickness, thickness);
	g2.drawRenderedImage(img, null);
	g2.dispose();

	im.setImage( tmp );
	
	return cfBooleanData.TRUE;
}
 

public static BufferedImage cloneImageRegion(BufferedImage srcImg, int x, int y, int width, int height) {
    int imgType = (srcImg.getTransparency() == Transparency.OPAQUE)
            ? BufferedImage.TYPE_INT_RGB
            : BufferedImage.TYPE_INT_ARGB;
    BufferedImage newImage = new BufferedImage(width, height, imgType);
    Graphics2D g2 = newImage.createGraphics();
    g2.drawImage(srcImg.getSubimage(x, y, width, height), 0, 0, null);
    g2.dispose();

    return newImage;
}
 

/**
 * Used to copy a {@link BufferedImage} from a non-optimal type into a new
 * {@link BufferedImage} instance of an optimal type (RGB or ARGB). If
 * <code>src</code> is already of an optimal type, then it is returned
 * unmodified.
 * <p/>
 * This method is meant to be used by any calling code (imgscalr's or
 * otherwise) to convert any inbound image from a poorly supported image
 * type into the 2 most well-supported image types in Java2D (
 * {@link BufferedImage#TYPE_INT_RGB} or {@link BufferedImage#TYPE_INT_ARGB}
 * ) in order to ensure all subsequent graphics operations are performed as
 * efficiently and correctly as possible.
 * <p/>
 * When using Java2D to work with image types that are not well supported,
 * the results can be anything from exceptions bubbling up from the depths
 * of Java2D to images being completely corrupted and just returned as solid
 * black.
 *
 * @param src
 *        The image to copy (if necessary) into an optimally typed
 *        {@link BufferedImage}.
 *
 * @return a representation of the <code>src</code> image in an optimally
 *         typed {@link BufferedImage}, otherwise <code>src</code> if it was
 *         already of an optimal type.
 *
 * @throws IllegalArgumentException
 *         if <code>src</code> is <code>null</code>.
 */
protected static BufferedImage copyToOptimalImage(BufferedImage src) throws IllegalArgumentException {
  if (src == null)
    throw new IllegalArgumentException("src cannot be null");

  // Calculate the type depending on the presence of alpha.
  int type =
      (src.getTransparency() == Transparency.OPAQUE ? BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB);
  BufferedImage result = new BufferedImage(src.getWidth(), src.getHeight(), type);

  // Render the src image into our new optimal source.
  Graphics g = result.getGraphics();
  g.drawImage(src, 0, 0, null);
  g.dispose();

  return result;
}
 

/**
 * Convenience method that returns a scaled instance of the provided
 * {@code BufferedImage}.
 * https://today.java.net/pub/a/today/2007/04/03/perils-of-image-getscaledinstance.html
 *
 * @param img the original image to be scaled
 * @param targetWidth the desired width of the scaled instance, in pixels
 * @param targetHeight the desired height of the scaled instance, in pixels
 * @param hint one of the rendering hints that corresponds to
 * {@code RenderingHints.KEY_INTERPOLATION} (e.g.
 * {@code RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR},
 * {@code RenderingHints.VALUE_INTERPOLATION_BILINEAR},
 * {@code RenderingHints.VALUE_INTERPOLATION_BICUBIC})
 * @param higherQuality if true, this method will use a multi-step scaling
 * technique that provides higher quality than the usual one-step technique
 * (only useful in downscaling cases, where {@code targetWidth} or
 * {@code targetHeight} is smaller than the original dimensions, and
 * generally only when the {@code BILINEAR} hint is specified)
 * @return a scaled version of the original {@code BufferedImage}
 */
public static BufferedImage getScaledInstance(BufferedImage img,
        int targetWidth,
        int targetHeight,
        Object hint,
        boolean higherQuality) {
    int type = (img.getTransparency() == Transparency.OPAQUE)
            ? BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB;
    BufferedImage ret = (BufferedImage) img;
    int w, h;
    if (higherQuality /*&& (img.getWidth() > targetWidth || img.getHeight() > targetHeight)*/) {
        // Use multi-step technique: start with original size, then
        // scale down in multiple passes with drawImage()
        // until the target size is reached
        w = img.getWidth();
        h = img.getHeight();
    } else {
        // Use one-step technique: scale directly from original
        // size to target size with a single drawImage() call
        w = targetWidth;
        h = targetHeight;
    }

    do {
        if (higherQuality) {
            if (w > targetWidth) {
                w /= 2;
                if (w < targetWidth) {
                    w = targetWidth;
                }
            } else {
                w *= 2;
                if (w > targetWidth) {
                    w = targetWidth;
                }
            }

            if (h > targetHeight) {
                h /= 2;
                if (h < targetHeight) {
                    h = targetHeight;
                }
            } else {
                h *= 2;
                if (h > targetHeight) {
                    h = targetHeight;
                }
            }
        }
        BufferedImage tmp = new BufferedImage(w, h, type);
        Graphics2D g2 = tmp.createGraphics();
        g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION, hint);
        g2.drawImage(ret, 0, 0, w, h, null);
        g2.dispose();

        ret = tmp;
    } while (w != targetWidth || h != targetHeight);

    return ret;
}
 

private static PDImageXObject createFromRGBImage(BufferedImage image) throws IOException
{
    int height = image.getHeight();
    int width = image.getWidth();
    int[] rgbLineBuffer = new int[width];
    int bpc = 8;
    PDDeviceColorSpace deviceColorSpace = PDDeviceRGB.INSTANCE;
    byte[] imageData = new byte[width * height * 3];
    int byteIdx = 0;
    int alphaByteIdx = 0;
    int alphaBitPos = 7;
    int transparency = image.getTransparency();
    int apbc = transparency == Transparency.BITMASK ? 1 : 8;
    byte[] alphaImageData;
    if (transparency != Transparency.OPAQUE)
    {
        alphaImageData = new byte[((width * apbc / 8) + (width * apbc % 8 != 0 ? 1 : 0))
                * height];
    }
    else
    {
        alphaImageData = new byte[0];
    }
    for (int y = 0; y < height; ++y)
    {
        for (int pixel : image.getRGB(0, y, width, 1, rgbLineBuffer, 0, width))
        {
            imageData[byteIdx++] = (byte) ((pixel >> 16) & 0xFF);
            imageData[byteIdx++] = (byte) ((pixel >> 8) & 0xFF);
            imageData[byteIdx++] = (byte) (pixel & 0xFF);
            if (transparency != Transparency.OPAQUE)
            {
                // we have the alpha right here, so no need to do it separately
                // as done prior April 2018
                if (transparency == Transparency.BITMASK)
                {
                    // write a bit
                    alphaImageData[alphaByteIdx] |= ((pixel >> 24) & 1) << alphaBitPos;
                    if (--alphaBitPos < 0)
                    {
                        alphaBitPos = 7;
                        ++alphaByteIdx;
                    }
                }
                else
                {
                    // write a byte
                    alphaImageData[alphaByteIdx++] = (byte) ((pixel >> 24) & 0xFF);
                }
            }
        }

        // skip boundary if needed
        if (transparency == Transparency.BITMASK && alphaBitPos != 7)
        {
            alphaBitPos = 7;
            ++alphaByteIdx;
        }
    }
    PDImageXObject pdImage = prepareImageXObject(imageData, image.getWidth(), image.getHeight(),
            bpc, deviceColorSpace);
    if (transparency != Transparency.OPAQUE)
    {
        PDImageXObject pdMask = prepareImageXObject(alphaImageData, image.getWidth(),
                image.getHeight(), apbc, PDDeviceGray.INSTANCE);
        pdImage.getCOSObject().setItem(COSName.SMASK, pdMask);
    }
    return pdImage;
}
 

/**
 * This method returns a scaled instance of the provided {@code BufferedImage}. The image is scaled to a
 * maximum of {@link #targetSize} pixels in total by keeping the aspect ratio.
 * 
 * @param img
 *            the original image to be scaled
 * @return a scaled version of the original {@code BufferedImage} or the original image if no scaling was
 *         applied
 */
public BufferedImage maxPixelsScaling(BufferedImage img) {
	int type = (img.getTransparency() == Transparency.OPAQUE) ? BufferedImage.TYPE_INT_RGB
			: BufferedImage.TYPE_INT_ARGB;
	// get dimensions of original image
	int originalWidth = img.getWidth();
	int originalHeight = img.getHeight();
	long originalSize = originalWidth * originalHeight;
	if (originalSize <= targetSize) {
		return img;
	}
	double scalingRatio = (double) targetSize / originalSize;
	// scaling ratio per dimension
	scalingRatio = Math.sqrt(scalingRatio);
	int targetWidth = (int) (originalWidth * scalingRatio);
	int targetHeight = (int) (originalHeight * scalingRatio);

	BufferedImage ret = (BufferedImage) img;

	int w, h;
	if (higherQuality) {
		// Use multi-step technique: start with original size, then
		// scale down in multiple passes with drawImage()
		// until the target size is reached
		w = img.getWidth();
		h = img.getHeight();
	} else {
		// Use one-step technique: scale directly from original
		// size to target size with a single drawImage() call
		w = targetWidth;
		h = targetHeight;
	}

	do {
		if (higherQuality && w > targetWidth) {
			w /= 2;
			if (w < targetWidth) {
				w = targetWidth;
			}
		}

		if (higherQuality && h > targetHeight) {
			h /= 2;
			if (h < targetHeight) {
				h = targetHeight;
			}
		}
		// long start = System.currentTimeMillis();
		BufferedImage tmp = new BufferedImage(w, h, type);
		Graphics2D g2 = tmp.createGraphics();
		g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION, hint);
		g2.drawImage(ret, 0, 0, w, h, null);
		// long end = System.currentTimeMillis();
		g2.dispose();
		// System.out.println(end - start);

		ret = tmp;
	} while (w != targetWidth || h != targetHeight);

	return ret;
}
 

/**
 * Convenience method that returns a scaled instance of the
 * provided {@code BufferedImage}. NEEDS WORK.
 * Alternate option is getScaledInstance off of the BufferedImage object.
 *
 * @param srcImage The image to be scaled.
 * @param targetWidth the desired width of the scaled instance,
 *    in pixels
 * @param targetHeight the desired height of the scaled instance,
 *    in pixels
 * @param hint one of the rendering hints that corresponds to
 *    {@code RenderingHints.KEY_INTERPOLATION} (e.g.
 *    {@code RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR},
 *    {@code RenderingHints.VALUE_INTERPOLATION_BILINEAR},
 *    {@code RenderingHints.VALUE_INTERPOLATION_BICUBIC})
 * @param higherQuality if true, this method will use a multi-step
 *    scaling technique that provides higher quality than the usual
 *    one-step technique (only useful in downscaling cases, where
 *    {@code targetWidth} or {@code targetHeight} is
 *    smaller than the original dimensions, and generally only when
 *    the {@code BILINEAR} hint is specified). NEEDS WORK.
 * @param keepProportion Don't stretch the original image to fit into the
 * target height/width.
 * @return a scaled version of the original {@code BufferedImage}
 * 
 */
public static BufferedImage getScaledInstance(BufferedImage srcImage,
                                       int targetWidth,
                                       int targetHeight,
                                       Object hint,
                                       boolean higherQuality,
                                       boolean keepProportion)
{
    int type = (srcImage.getTransparency() == Transparency.OPAQUE) ?
        BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB;
    BufferedImage ret = (BufferedImage)srcImage;
    int w, h;

    //keep things proportioned///////////
    double ratio = 0;
    double SrcW = srcImage.getWidth();
    double SrcH = srcImage.getHeight();
    double tW = targetWidth;
    double tH = targetHeight;

    if(keepProportion)
    {
        ratio = Math.min((tH / SrcH), (tW / SrcW));
        //ratio = (SrcW / tW);
        targetWidth = (int)((SrcW) * ratio);
        targetHeight = (int)((SrcH) * ratio);
    }///////////////////////////////////

    if (higherQuality)
    {
        // Use multi-step technique: start with original size, then
        // scale down in multiple passes with drawImage()
        // until the target size is reached
        w = srcImage.getWidth();
        h = srcImage.getHeight();
    }
    else
    {
        // Use one-step technique: scale directly from original
        // size to target size with a single drawImage() call
        w = targetWidth;
        h = targetHeight;
    }

    do
    {
        if (higherQuality && w > targetWidth)
        {
            w /= 2;
            if (w < targetWidth)
            {
                w = targetWidth;
            }
        }

        if (higherQuality && h > targetHeight)
        {
            h /= 2;
            if (h < targetHeight)
            {
                h = targetHeight;
            }
        }


        BufferedImage tmp = new BufferedImage(w, h, type);
        Graphics2D g2 = tmp.createGraphics();
        g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION, hint);
        g2.drawImage(ret, 0, 0, w, h, null);
        g2.dispose();

        ret = tmp;
    } while (w != targetWidth || h != targetHeight);

    return ret;
}
 

/**
 * Used to copy a {@link BufferedImage} from a non-optimal type into a new
 * {@link BufferedImage} instance of an optimal type (RGB or ARGB). If
 * <code>src</code> is already of an optimal type, then it is returned
 * unmodified.
 * <p/>
 * This method is meant to be used by any calling code (imgscalr's or
 * otherwise) to convert any inbound image from a poorly supported image
 * type into the 2 most well-supported image types in Java2D (
 * {@link BufferedImage#TYPE_INT_RGB} or {@link BufferedImage#TYPE_INT_ARGB}
 * ) in order to ensure all subsequent graphics operations are performed as
 * efficiently and correctly as possible.
 * <p/>
 * When using Java2D to work with image types that are not well supported,
 * the results can be anything from exceptions bubbling up from the depths
 * of Java2D to images being completely corrupted and just returned as solid
 * black.
 * 
 * @param src
 *            The image to copy (if necessary) into an optimally typed
 *            {@link BufferedImage}.
 * 
 * @return a representation of the <code>src</code> image in an optimally
 *         typed {@link BufferedImage}, otherwise <code>src</code> if it was
 *         already of an optimal type.
 * 
 * @throws IllegalArgumentException
 *             if <code>src</code> is <code>null</code>.
 */
protected static BufferedImage copyToOptimalImage(BufferedImage src)
		throws IllegalArgumentException {
	if (src == null)
		throw new IllegalArgumentException("src cannot be null");

	// Calculate the type depending on the presence of alpha.
	int type = (src.getTransparency() == Transparency.OPAQUE ? BufferedImage.TYPE_INT_RGB
			: BufferedImage.TYPE_INT_ARGB);
	BufferedImage result = new BufferedImage(src.getWidth(),
			src.getHeight(), type);

	// Render the src image into our new optimal source.
	Graphics g = result.getGraphics();
	g.drawImage(src, 0, 0, null);
	g.dispose();

	return result;
}
 

/**
 * <p>Returns a thumbnail of a source image.</p>
 * <p>This method offers a good trade-off between speed and quality.
 * The result looks better than
 * {@link #createThumbnailFast(java.awt.image.BufferedImage, int)} when
 * the new size is less than half the longest dimension of the source
 * image, yet the rendering speed is almost similar.</p>
 *
 * @see #createThumbnailFast(java.awt.image.BufferedImage, int)
 * @see #createThumbnailFast(java.awt.image.BufferedImage, int, int)
 * @see #createThumbnail(java.awt.image.BufferedImage, int)
 * @param image the source image
 * @param newWidth the width of the thumbnail
 * @param newHeight the height of the thumbnail
 * @return a new compatible <code>BufferedImage</code> containing a
 *   thumbnail of <code>image</code>
 * @throws IllegalArgumentException if <code>newWidth</code> is larger than
 *   the width of <code>image</code> or if code>newHeight</code> is larger
 *   than the height of <code>image or if one the dimensions is not &gt; 0</code>
 */
public static BufferedImage createThumbnail(BufferedImage image,
                                            int newWidth, int newHeight) {
  int width = image.getWidth();
  int height = image.getHeight();

  boolean isTranslucent = image.getTransparency() != Transparency.OPAQUE;

  if (newWidth >= width || newHeight >= height) {
    throw new IllegalArgumentException("newWidth and newHeight cannot" +
                                       " be greater than the image" +
                                       " dimensions");
  } else if (newWidth <= 0 || newHeight <= 0) {
    throw new IllegalArgumentException("newWidth and newHeight must" +
                                       " be greater than 0");
  }

  BufferedImage thumb = image;
  BufferedImage temp = null;

  Graphics2D g2 = null;

  try {
    int previousWidth = width;
    int previousHeight = height;

    do {
      if (width > newWidth) {
        width /= 2;
        if (width < newWidth) {
          width = newWidth;
        }
      }

      if (height > newHeight) {
        height /= 2;
        if (height < newHeight) {
          height = newHeight;
        }
      }

      if (temp == null || isTranslucent) {
        if (g2 != null) {
          //do not need to wrap with finally
          //outer finally block will ensure
          //that resources are properly reclaimed
          g2.dispose();
        }
        temp = createCompatibleImage(image, width, height);
        g2 = temp.createGraphics();
        g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION,
                            RenderingHints.VALUE_INTERPOLATION_BILINEAR);
      }
      g2.drawImage(thumb, 0, 0, width, height,
                   0, 0, previousWidth, previousHeight, null);

      previousWidth = width;
      previousHeight = height;

      thumb = temp;
    } while (width != newWidth || height != newHeight);
  } finally {
    g2.dispose();
  }

  if (width != thumb.getWidth() || height != thumb.getHeight()) {
    temp = createCompatibleImage(image, width, height);
    g2 = temp.createGraphics();

    try {
      g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION,
                          RenderingHints.VALUE_INTERPOLATION_BILINEAR);
      g2.drawImage(thumb, 0, 0, width, height, 0, 0, width, height, null);
    } finally {
      g2.dispose();
    }

    thumb = temp;
  }

  return thumb;
}
 

/**
 * Used to copy a {@link BufferedImage} from a non-optimal type into a new
 * {@link BufferedImage} instance of an optimal type (RGB or ARGB). If
 * <code>src</code> is already of an optimal type, then it is returned
 * unmodified.
 * <p>
 * This method is meant to be used by any calling code (imgscalr's or
 * otherwise) to convert any inbound image from a poorly supported image
 * type into the 2 most well-supported image types in Java2D (
 * {@link BufferedImage#TYPE_INT_RGB} or {@link BufferedImage#TYPE_INT_ARGB}
 * ) in order to ensure all subsequent graphics operations are performed as
 * efficiently and correctly as possible.
 * <p>
 * When using Java2D to work with image types that are not well supported,
 * the results can be anything from exceptions bubbling up from the depths
 * of Java2D to images being completely corrupted and just returned as solid
 * black.
 *
 * @param src The image to copy (if necessary) into an optimally typed
 *            {@link BufferedImage}.
 * @return a representation of the <code>src</code> image in an optimally
 * typed {@link BufferedImage}, otherwise <code>src</code> if it was
 * already of an optimal type.
 * @throws IllegalArgumentException if <code>src</code> is <code>null</code>.
 */
protected static BufferedImage copyToOptimalImage(BufferedImage src)
        throws IllegalArgumentException {
    if (src == null)
        throw new IllegalArgumentException("src cannot be null");

    // Calculate the type depending on the presence of alpha.
    int type = (src.getTransparency() == Transparency.OPAQUE ? BufferedImage.TYPE_INT_RGB
            : BufferedImage.TYPE_INT_ARGB);
    BufferedImage result = new BufferedImage(src.getWidth(),
            src.getHeight(), type);

    // Render the src image into our new optimal source.
    Graphics g = result.getGraphics();
    g.drawImage(src, 0, 0, null);
    g.dispose();

    return result;
}
 

/**
 * Convenience method that returns a scaled instance of the
 * provided {@code BufferedImage}.
 *
 * @param img the original image to be scaled
 * @param targetWidth the desired width of the scaled instance,
 *    in pixels
 * @param targetHeight the desired height of the scaled instance,
 *    in pixels
 * @param hint one of the rendering hints that corresponds to
 *    {@code RenderingHints.KEY_INTERPOLATION} (e.g.
 *    {@code RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR},
 *    {@code RenderingHints.VALUE_INTERPOLATION_BILINEAR},
 *    {@code RenderingHints.VALUE_INTERPOLATION_BICUBIC})
 * @param higherQuality if true, this method will use a multi-step
 *    scaling technique that provides higher quality than the usual
 *    one-step technique (only useful in down scaling cases, where
 *    {@code targetWidth} or {@code targetHeight} is
 *    smaller than the original dimensions, and generally only when
 *    the {@code BILINEAR} hint is specified)
 * @return a scaled version of the original {@code BufferedImage}
 */
public BufferedImage getScaledInstance(BufferedImage img, int targetWidth, int targetHeight, Object hint,
	boolean higherQuality)
{
	int type = (img.getTransparency() == Transparency.OPAQUE) ? BufferedImage.TYPE_INT_RGB
		: BufferedImage.TYPE_INT_ARGB;
	BufferedImage ret = img;
	int w;
	int h;
	if (higherQuality)
	{
		// Use multi-step technique: start with original size, then
		// scale down in multiple passes with drawImage()
		// until the target size is reached
		w = img.getWidth();
		h = img.getHeight();
	}
	else
	{
		// Use one-step technique: scale directly from original
		// size to target size with a single drawImage() call
		w = targetWidth;
		h = targetHeight;
	}

	// If we are scaling up, just do the one pass.
	if (w < targetWidth || h < targetWidth)
	{
		// Use one-step technique: scale directly from original
		// size to target size with a single drawImage() call
		w = targetWidth;
		h = targetHeight;
	}

	do
	{
		if (higherQuality && w > targetWidth)
		{
			w /= 2;
			if (w < targetWidth)
			{
				w = targetWidth;
			}
		}

		if (higherQuality && h > targetHeight)
		{
			h /= 2;
			if (h < targetHeight)
			{
				h = targetHeight;
			}
		}

		BufferedImage tmp = new BufferedImage(w, h, type);
		Graphics2D g2 = tmp.createGraphics();
		g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION, hint);
		g2.drawImage(ret, 0, 0, w, h, null);
		g2.dispose();

		ret = tmp;
	}
	while (w != targetWidth || h != targetHeight);

	return ret;
}
 

private BufferedImage scaleToSize(BufferedImage img, int targetWidth, int targetHeight, Object interpolation) {
	if (targetWidth == img.getWidth() && targetHeight == img.getHeight()) {
		return img;
	}
	
   boolean higherQuality = (
		// Set flag to use multi-step technique only if the
     // target size is less than 50% of the original size
		// and the interpolation mode is bilinear or bicubic
     (targetWidth < (int)(img.getWidth() * 0.5)) &&
     (
       (interpolation == RenderingHints.VALUE_INTERPOLATION_BILINEAR) ||
       (interpolation == RenderingHints.VALUE_INTERPOLATION_BICUBIC)
     )
   );
   
	int type = (img.getTransparency() == Transparency.OPAQUE) ? BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB;
	BufferedImage ret = (BufferedImage) img;
	int w, h;
	if (higherQuality) {
		// Use multi-step technique: start with original size, then
		// scale down in multiple passes with drawImage()
		// until the target size is reached
		w = img.getWidth();
		h = img.getHeight();
	} else {
		// Use one-step technique: scale directly from original
		// size to target size with a single drawImage() call
		w = targetWidth;
		h = targetHeight;
	}

	do {
		if (higherQuality && w > targetWidth) {
			w /= 2;
			if (w < targetWidth) {
				w = targetWidth;
			}
		}

		if (higherQuality && h > targetHeight) {
			h /= 2;
			if (h < targetHeight) {
				h = targetHeight;
			}
		}

		BufferedImage tmp = new BufferedImage(w, h, type);
		Graphics2D g2 = tmp.createGraphics();
		g2.setRenderingHint( RenderingHints.KEY_INTERPOLATION, interpolation );
 		g2.setRenderingHint( RenderingHints.KEY_RENDERING, RenderingHints.VALUE_RENDER_QUALITY );
  	g2.setRenderingHint( RenderingHints.KEY_ANTIALIASING, RenderingHints.VALUE_ANTIALIAS_ON );
		g2.drawImage(ret, 0, 0, w, h, null);
		g2.dispose();
		ret = tmp;
	} while (w != targetWidth || h != targetHeight);

	return ret;
}
 

private static PDImageXObject createFromRGBImage(BufferedImage image, PDDocument document) throws IOException
{
    int height = image.getHeight();
    int width = image.getWidth();
    int[] rgbLineBuffer = new int[width];
    int bpc = 8;
    PDDeviceColorSpace deviceColorSpace = PDDeviceRGB.INSTANCE;
    byte[] imageData = new byte[width * height * 3];
    int byteIdx = 0;
    int alphaByteIdx = 0;
    int alphaBitPos = 7;
    int transparency = image.getTransparency();
    int apbc = transparency == Transparency.BITMASK ? 1 : 8;
    byte[] alphaImageData;
    if (transparency != Transparency.OPAQUE)
    {
        alphaImageData = new byte[((width * apbc / 8) + (width * apbc % 8 != 0 ? 1 : 0)) * height];
    }
    else
    {
        alphaImageData = new byte[0];
    }
    for (int y = 0; y < height; ++y)
    {
        for (int pixel : image.getRGB(0, y, width, 1, rgbLineBuffer, 0, width))
        {
            imageData[byteIdx++] = (byte) ((pixel >> 16) & 0xFF);
            imageData[byteIdx++] = (byte) ((pixel >> 8) & 0xFF);
            imageData[byteIdx++] = (byte) (pixel & 0xFF);
            if (transparency != Transparency.OPAQUE)
            {
                // we have the alpha right here, so no need to do it separately
                // as done prior April 2018
                if (transparency == Transparency.BITMASK)
                {
                    // write a bit
                    alphaImageData[alphaByteIdx] |= ((pixel >> 24) & 1) << alphaBitPos;
                    if (--alphaBitPos < 0)
                    {
                        alphaBitPos = 7;
                        ++alphaByteIdx;
                    }
                }
                else
                {
                    // write a byte
                    alphaImageData[alphaByteIdx++] = (byte) ((pixel >> 24) & 0xFF);
                }
            }
        }

        // skip boundary if needed
        if (transparency == Transparency.BITMASK && alphaBitPos != 7)
        {
            alphaBitPos = 7;
            ++alphaByteIdx;
        }
    }
    PDImageXObject pdImage = prepareImageXObject(document, imageData,
            image.getWidth(), image.getHeight(), bpc, deviceColorSpace);      
    if (transparency != Transparency.OPAQUE)
    {
        PDImageXObject pdMask = prepareImageXObject(document, alphaImageData,
                image.getWidth(), image.getHeight(), apbc, PDDeviceGray.INSTANCE);
        pdImage.getCOSObject().setItem(COSName.SMASK, pdMask);
    }
    return pdImage;
}
 

/**
    * Used to copy a {@link BufferedImage} from a non-optimal type into a new
    * {@link BufferedImage} instance of an optimal type (RGB or ARGB). If
    * <code>src</code> is already of an optimal type, then it is returned
    * unmodified.
    * <p/>
    * This method is meant to be used by any calling code (imgscalr's or
    * otherwise) to convert any inbound image from a poorly supported image
    * type into the 2 most well-supported image types in Java2D (
    * {@link BufferedImage#TYPE_INT_RGB} or {@link BufferedImage#TYPE_INT_ARGB}
    * ) in order to ensure all subsequent graphics operations are performed as
    * efficiently and correctly as possible.
    * <p/>
    * When using Java2D to work with image types that are not well supported,
    * the results can be anything from exceptions bubbling up from the depths
    * of Java2D to images being completely corrupted and just returned as solid
    * black.
    * 
    * @param src
    *            The image to copy (if necessary) into an optimally typed
    *            {@link BufferedImage}.
    * 
    * @return a representation of the <code>src</code> image in an optimally
    *         typed {@link BufferedImage}, otherwise <code>src</code> if it was
    *         already of an optimal type.
    * 
    * @throws IllegalArgumentException
    *             if <code>src</code> is <code>null</code>.
    */
   protected static BufferedImage copyToOptimalImage(BufferedImage src) throws IllegalArgumentException {
if (src == null)
    throw new IllegalArgumentException("src cannot be null");

// Calculate the type depending on the presence of alpha.
int type = (src.getTransparency() == Transparency.OPAQUE ? BufferedImage.TYPE_INT_RGB
	: BufferedImage.TYPE_INT_ARGB);
BufferedImage result = new BufferedImage(src.getWidth(), src.getHeight(), type);

// Render the src image into our new optimal source.
Graphics g = result.getGraphics();
g.drawImage(src, 0, 0, null);
g.dispose();

return result;
   }
 

private static BufferedImage scaleToSize(BufferedImage img, int targetWidth, int targetHeight, boolean higherQuality) {
	if (targetWidth == img.getWidth() && targetHeight == img.getHeight()) {
		return img;
	}
	
	int type = (img.getTransparency() == Transparency.OPAQUE) ? BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB;
	BufferedImage ret = (BufferedImage) img;
	int w, h;
	if (higherQuality) {
		// Use multi-step technique: start with original size, then
		// scale down in multiple passes with drawImage()
		// until the target size is reached
		w = img.getWidth();
		h = img.getHeight();
	} else {
		// Use one-step technique: scale directly from original
		// size to target size with a single drawImage() call
		w = targetWidth;
		h = targetHeight;
	}

	do {
		if (higherQuality && w > targetWidth) {
			w /= 2;
			if (w < targetWidth) {
				w = targetWidth;
			}
		}

		if (higherQuality && h > targetHeight) {
			h /= 2;
			if (h < targetHeight) {
				h = targetHeight;
			}
		}

		BufferedImage tmp = new BufferedImage(w, h, type);
		Graphics2D g2 = tmp.createGraphics();
		g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION, RenderingHints.VALUE_INTERPOLATION_BICUBIC);
		g2.drawImage(ret, 0, 0, w, h, null);
		g2.dispose();

		ret = tmp;
	} while (w != targetWidth || h != targetHeight);

	return ret;
}
 

/**
* Convenience method that returns a scaled instance of the
   * provided {@code BufferedImage}.
   *
   * @param img the original image to be scaled
   * @param targetWidth the desired width of the scaled instance,
   *    in pixels
   * @param targetHeight the desired height of the scaled instance,
   *    in pixels
   * @param hint one of the rendering hints that corresponds to
   *    {@code RenderingHints.KEY_INTERPOLATION} (e.g.
   *    {@code RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR},
   *    {@code RenderingHints.VALUE_INTERPOLATION_BILINEAR},
   *    {@code RenderingHints.VALUE_INTERPOLATION_BICUBIC})
   * @param higherQuality if true, this method will use a multi-step
   *    scaling technique that provides higher quality than the usual
   *    one-step technique (only useful in down-scaling cases, where
   *    {@code targetWidth} or {@code targetHeight} is
   *    smaller than the original dimensions, and generally only when
   *    the {@code BILINEAR} hint is specified)
   * @return a scaled version of the original {@code BufferedImage}
   */
// From https://today.java.net/article/2007/03/30/perils-imagegetscaledinstance
  public static BufferedImage getScaledInstance(BufferedImage img,
                                                int targetWidth,
                                                int targetHeight,
                                                Object hint,
                                                boolean higherQuality)
  {
      int type = (img.getTransparency() == Transparency.OPAQUE) ?
          BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB;
      BufferedImage ret = img;        
      int w = img.getWidth(), h = img.getHeight();
      
      // Use one-step technique: scale directly from original
      // size to target size with a single drawImage() call
      if(w < targetWidth || h < targetHeight || !higherQuality)
          return scaleImage(ret, type, hint, targetWidth, targetHeight);
     
      // Use multi-step technique: start with original size, then
      // scale down in multiple passes with drawImage()
      // until the target size is reached    
      do {
          if (w > targetWidth) {
              w /= 2;
              if (w < targetWidth) {
                  w = targetWidth;
              }
          }

          if (h > targetHeight) {
              h /= 2;
              if (h < targetHeight) {
                  h = targetHeight;
              }
          }

          ret = scaleImage(ret, type, hint, w, h);
          
      } while (w != targetWidth || h != targetHeight);

      return ret;
  }
 

/**
 * Adapted from http://stackoverflow.com/questions/7951290/re-sizing-an-image-without-losing-quality
 * @param img The Image to scale
 * @param targetWidth target width
 * @param targetHeight target height
 * @return A scaled image copy of the original image.
 * @throws IllegalArgumentException
 */
private static BufferedImage getScaledInstance(BufferedImage img,
                                        int targetWidth,
                                        int targetHeight) {
    if (targetWidth < 0) {
        throw new IllegalArgumentException(String.format("Negative target sizes not allowed: %d", targetWidth));
    }
    if (targetHeight < 0) {
        throw new IllegalArgumentException(String.format("Negative target sizes not allowed: %d", targetHeight));
    }
    int type = (img.getTransparency() == Transparency.OPAQUE) ?
            BufferedImage.TYPE_INT_RGB : BufferedImage.TYPE_INT_ARGB;
    BufferedImage ret = img;
    int w;
    int h;
    // Use multi-step technique: start with original size, then
    // scale down in multiple passes with drawImage()
    // until the target size is reached
    w = img.getWidth();
    h = img.getHeight();

    int breakLoop = 0;
    
    do {
        breakLoop++;
        
        w = reduce(w, targetWidth);
        h = reduce(h, targetHeight);

        BufferedImage tmp = new BufferedImage(w, h, type);
        Graphics2D g2 = tmp.createGraphics();
        g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION, RenderingHints.VALUE_INTERPOLATION_BICUBIC);
        g2.drawImage(ret, 0, 0, w, h, null);
        g2.dispose();

        ret = tmp;
        if(breakLoop > 20) {
            // damn infinite loop...
            return null;
        }
    } while ((w != targetWidth) || (h != targetHeight));

    return ret;
}
 

/**
 * This method returns a scaled instance of the provided {@code BufferedImage}. The image is scaled so
 * that its maximum dimension becomes {@link #targetSize} pixels.
 * 
 * @param img
 *            the original image to be scaled
 * @return a scaled version of the original {@code BufferedImage} or the original image if no scaling was
 *         applied
 */
public BufferedImage rectScaling(BufferedImage img) {
	int type = (img.getTransparency() == Transparency.OPAQUE) ? BufferedImage.TYPE_INT_RGB
			: BufferedImage.TYPE_INT_ARGB;
	// get dimensions of original image
	int originalWidth = img.getWidth();
	int originalHeight = img.getHeight();
	int maxDimension = Math.max(originalWidth, originalHeight);

	// no processing is required
	if (maxDimension <= targetSize) {
		return img;
	}

	// scaling is required
	BufferedImage ret = (BufferedImage) img;
	double scalingRatio = (double) targetSize / maxDimension;
	int targetWidth = (int) (originalWidth * scalingRatio);
	int targetHeight = (int) (originalHeight * scalingRatio);

	int w, h;
	if (higherQuality) {
		// Use multi-step technique: start with original size, then
		// scale down in multiple passes with drawImage()
		// until the target size is reached
		w = originalWidth;
		h = originalHeight;
	} else {
		// Use one-step technique: scale directly from original
		// size to target size with a single drawImage() call
		w = targetWidth;
		h = targetHeight;
	}

	do {
		if (higherQuality && w > targetWidth) {
			w /= 2;
			if (w < targetWidth) {
				w = targetWidth;
			}
		}

		if (higherQuality && h > targetHeight) {
			h /= 2;
			if (h < targetHeight) {
				h = targetHeight;
			}
		}
		// long start = System.currentTimeMillis();
		BufferedImage tmp = new BufferedImage(w, h, type);
		Graphics2D g2 = tmp.createGraphics();
		g2.setRenderingHint(RenderingHints.KEY_INTERPOLATION, hint);
		g2.drawImage(ret, 0, 0, w, h, null);
		// long end = System.currentTimeMillis();
		g2.dispose();
		// System.out.println(end - start);

		ret = tmp;
	} while (w != targetWidth || h != targetHeight);

	return ret;
}
 

/**
 * Used to create a {@link BufferedImage} with the given dimensions and the
 * most optimal RGB TYPE ( {@link BufferedImage#TYPE_INT_RGB} or
 * {@link BufferedImage#TYPE_INT_ARGB} ) capable of being rendered into from
 * the given <code>src</code>.
 * <p/>
 * This does not perform a copy of the image data from <code>src</code> into
 * the result image; see {@link #copyToOptimalImage(BufferedImage)} for
 * that.
 * <p/>
 * We force all rendering results into one of these two types, avoiding the
 * case where a source image is of an unsupported (or poorly supported)
 * format by Java2D causing the rendering result to end up looking terrible
 * (common with GIFs) or be totally corrupt (e.g. solid black image).
 * <p/>
 * Originally reported by Magnus Kvalheim from Movellas when scaling certain
 * GIF and PNG images.
 * 
 * @param src
 *            The source image that will be analyzed to determine the most
 *            optimal image type it can be rendered into.
 * @param width
 *            The width of the newly created resulting image.
 * @param height
 *            The height of the newly created resulting image.
 * 
 * @return a new {@link BufferedImage} representing the most optimal target
 *         image type that <code>src</code> can be rendered into.
 * 
 * @throws IllegalArgumentException
 *             if <code>width</code> or <code>height</code> are &lt; 0.
 * 
 * @see <a
 *      href="http://www.mail-archive.com/[email protected]/msg05621.html">How
 *      Java2D handles poorly supported image types</a>
 * @see <a
 *      href="http://code.google.com/p/java-image-scaling/source/browse/trunk/src/main/java/com/mortennobel/imagescaling/MultiStepRescaleOp.java">Thanks
 *      to Morten Nobel for implementation hint</a>
 */
protected static BufferedImage createOptimalImage(BufferedImage src,
		int width, int height) throws IllegalArgumentException {
	if (width < 0 || height < 0)
		throw new IllegalArgumentException("width [" + width
				+ "] and height [" + height + "] must be >= 0");

	return new BufferedImage(
			width,
			height,
			(src.getTransparency() == Transparency.OPAQUE ? BufferedImage.TYPE_INT_RGB
					: BufferedImage.TYPE_INT_ARGB));
}
 

/**
 * Used to create a {@link BufferedImage} with the given dimensions and the
 * most optimal RGB TYPE ( {@link BufferedImage#TYPE_INT_RGB} or
 * {@link BufferedImage#TYPE_INT_ARGB} ) capable of being rendered into from
 * the given <code>src</code>.
 * <p>
 * This does not perform a copy of the image data from <code>src</code> into
 * the result image; see {@link #copyToOptimalImage(BufferedImage)} for
 * that.
 * <p>
 * We force all rendering results into one of these two types, avoiding the
 * case where a source image is of an unsupported (or poorly supported)
 * format by Java2D causing the rendering result to end up looking terrible
 * (common with GIFs) or be totally corrupt (e.g. solid black image).
 * <p>
 * Originally reported by Magnus Kvalheim from Movellas when scaling certain
 * GIF and PNG images.
 *
 * @param src    The source image that will be analyzed to determine the most
 *               optimal image type it can be rendered into.
 * @param width  The width of the newly created resulting image.
 * @param height The height of the newly created resulting image.
 * @return a new {@link BufferedImage} representing the most optimal target
 * image type that <code>src</code> can be rendered into.
 * @throws IllegalArgumentException if <code>width</code> or <code>height</code> are &lt; 0.
 * @see <a href="http://www.mail-archive.com/[email protected]/msg05621.html">How Java2D handles poorly supported image types</a>
 * @see <a href="http://code.google.com/p/java-image-scaling/source/browse/trunk/src/main/java/com/mortennobel/imagescaling/MultiStepRescaleOp.java">Thanks to Morten Nobel for implementation hint</a>
 */
protected static BufferedImage createOptimalImage(BufferedImage src,
                                                  int width, int height) throws IllegalArgumentException {
    if (width <= 0 || height <= 0)
        throw new IllegalArgumentException("width [" + width
                + "] and height [" + height + "] must be > 0");

    return new BufferedImage(
            width,
            height,
            (src.getTransparency() == Transparency.OPAQUE ? BufferedImage.TYPE_INT_RGB
                    : BufferedImage.TYPE_INT_ARGB));
}