Mercurial > hg > digilib-old
view servlet/src/digilib/image/ImageLoaderDocuImage.java @ 831:30037e93ec2a stream
helper function to show request and response header.
| author | robcast |
|---|---|
| date | Fri, 25 Feb 2011 12:41:07 +0100 |
| parents | a630d0303cce |
| children | c07c21ac78f9 |
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/* ImageLoaderDocuImage -- Image class implementation using JDK 1.4 ImageLoader Digital Image Library servlet components Copyright (C) 2002 - 2011 Robert Casties (robcast@mail.berlios.de) 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 of the License, or (at your option) any later version. Please read license.txt for the full details. A copy of the GPL may be found at http://www.gnu.org/copyleft/lgpl.html You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ package digilib.image; import java.awt.Image; import java.awt.Rectangle; import java.awt.RenderingHints; import java.awt.color.ColorSpace; import java.awt.geom.AffineTransform; import java.awt.geom.Rectangle2D; import java.awt.image.AffineTransformOp; import java.awt.image.BufferedImage; import java.awt.image.ColorConvertOp; import java.awt.image.ConvolveOp; import java.awt.image.Kernel; import java.awt.image.RescaleOp; import java.io.IOException; import java.io.OutputStream; import java.io.RandomAccessFile; import java.util.Arrays; import java.util.Iterator; import javax.imageio.IIOImage; import javax.imageio.ImageIO; import javax.imageio.ImageReadParam; import javax.imageio.ImageReader; import javax.imageio.ImageWriteParam; import javax.imageio.ImageWriter; import javax.imageio.stream.FileImageInputStream; import javax.imageio.stream.ImageInputStream; import javax.imageio.stream.ImageOutputStream; import javax.servlet.ServletException; import digilib.io.FileOpException; import digilib.io.FileOps; import digilib.io.ImageInput; import digilib.util.ImageSize; /** Implementation of DocuImage using the ImageLoader API of Java 1.4 and Java2D. */ public class ImageLoaderDocuImage extends ImageInfoDocuImage { /** image object */ protected BufferedImage img; /** interpolation type */ protected RenderingHints renderHint; protected static Kernel[] convolutionKernels = { null, new Kernel(1, 1, new float[] {1f}), new Kernel(2, 2, new float[] {0.25f, 0.25f, 0.25f, 0.25f}), new Kernel(3, 3, new float[] {1f/9f, 1f/9f, 1f/9f, 1f/9f, 1f/9f, 1f/9f, 1f/9f, 1f/9f, 1f/9f}) }; /** the size of the current image */ protected ImageSize imageSize; /* loadSubimage is supported. */ public boolean isSubimageSupported() { return true; } public void setQuality(int qual) { quality = qual; renderHint = new RenderingHints(null); // hint.put(RenderingHints.KEY_ANTIALIASING, // RenderingHints.VALUE_ANTIALIAS_OFF); // setup interpolation quality if (qual > 0) { logger.debug("quality q1"); renderHint.put(RenderingHints.KEY_INTERPOLATION, RenderingHints.VALUE_INTERPOLATION_BICUBIC); } else { logger.debug("quality q0"); renderHint.put(RenderingHints.KEY_INTERPOLATION, RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR); } } /* returns the size of the current image */ public ImageSize getSize() { if (imageSize == null) { int h = 0; int w = 0; try { if (img == null) { ImageReader reader = getReader(input); // get size from ImageReader h = reader.getHeight(0); w = reader.getWidth(0); } else { // get size from image h = img.getHeight(); w = img.getWidth(); } imageSize = new ImageSize(w, h); } catch (IOException e) { logger.debug("error in getSize:", e); } } return imageSize; } /* returns a list of supported image formats */ public Iterator<String> getSupportedFormats() { String[] formats = ImageIO.getReaderFormatNames(); return Arrays.asList(formats).iterator(); } /* Check image size and type and store in ImageInput */ public ImageInput identify(ImageInput input) throws IOException { // try parent method first ImageInput ii = super.identify(input); if (ii != null) { return ii; } logger.debug("identifying (ImageIO) " + input); ImageReader reader = null; try { /* * try ImageReader */ reader = getReader(input); // set size ImageSize d = new ImageSize(reader.getWidth(0), reader.getHeight(0)); input.setSize(d); // set mime type if (input.getMimetype() == null) { if (input.hasFile()) { String t = FileOps.mimeForFile(input.getFile()); input.setMimetype(t); } else { // FIXME: is format name a mime type??? String t = reader.getFormatName(); input.setMimetype(t); } } return input; } catch (FileOpException e) { // maybe just our class doesn't know what to do logger.error("ImageLoaderDocuimage unable to identify:", e); return null; } finally { if (reader != null) { reader.dispose(); } } } /* load image file */ public void loadImage(ImageInput ii) throws FileOpException { logger.debug("loadImage: " + ii); this.input = ii; try { if (ii.hasImageInputStream()) { img = ImageIO.read(ii.getImageInputStream()); } else if (ii.hasFile()) { img = ImageIO.read(ii.getFile()); } } catch (IOException e) { throw new FileOpException("Error reading image."); } } /** * Get an ImageReader for the image file. * * @return */ public ImageReader getReader(ImageInput input) throws IOException { logger.debug("get ImageReader for " + input); ImageInputStream istream = null; if (input.hasImageInputStream()) { // stream input istream = input.getImageInputStream(); } else if (input.hasFile()) { // file only input RandomAccessFile rf = new RandomAccessFile(input.getFile(), "r"); istream = new FileImageInputStream(rf); } else { throw new FileOpException("Unable to get data from ImageInput"); } Iterator<ImageReader> readers; String mt = null; if (input.hasMimetype()) { // check hasMimetype first or we might get into a loop mt = input.getMimetype(); } else { // try file extension mt = FileOps.mimeForFile(input.getFile()); } if (mt == null) { logger.debug("No mime-type. Trying automagic."); readers = ImageIO.getImageReaders(istream); } else { logger.debug("File type:" + mt); readers = ImageIO.getImageReadersByMIMEType(mt); } if (!readers.hasNext()) { throw new FileOpException("Can't find Reader to load File!"); } ImageReader reader = readers.next(); /* are there more readers? */ logger.debug("ImageIO: this reader: " + reader.getClass()); /* while (readers.hasNext()) { logger.debug("ImageIO: next reader: " + readers.next().getClass()); } */ reader.setInput(istream); return reader; } /* Load an image file into the Object. */ public void loadSubimage(ImageInput ii, Rectangle region, int prescale) throws FileOpException { logger.debug("loadSubimage"); this.input = ii; ImageReader reader = null; try { reader = getReader(ii); // set up reader parameters ImageReadParam readParam = reader.getDefaultReadParam(); readParam.setSourceRegion(region); if (prescale > 1) { readParam.setSourceSubsampling(prescale, prescale, 0, 0); } // read image logger.debug("loading.."); img = reader.read(0, readParam); logger.debug("loaded"); } catch (IOException e) { throw new FileOpException("Unable to load File!"); } finally { if (reader != null) { reader.dispose(); } } } /* write image of type mt to Stream */ public void writeImage(String mt, OutputStream ostream) throws ImageOpException, ServletException { logger.debug("writeImage"); // setup output ImageWriter writer = null; ImageOutputStream imgout = null; try { imgout = ImageIO.createImageOutputStream(ostream); if (mt == "image/jpeg") { /* * JPEG doesn't do transparency so we have to convert any RGBA * image to RGB :-( *Java2D BUG* */ if (img.getColorModel().hasAlpha()) { logger.debug("BARF: JPEG with transparency!!"); int w = img.getWidth(); int h = img.getHeight(); // BufferedImage.TYPE_INT_RGB seems to be fastest (JDK1.4.1, // OSX) int destType = BufferedImage.TYPE_INT_RGB; BufferedImage img2 = new BufferedImage(w, h, destType); img2.createGraphics().drawImage(img, null, 0, 0); img = img2; } writer = (ImageWriter) ImageIO.getImageWritersByFormatName( "jpeg").next(); if (writer == null) { throw new ImageOpException("Unable to get JPEG writer"); } ImageWriteParam param = writer.getDefaultWriteParam(); if (quality > 1) { // change JPEG compression quality param.setCompressionMode(ImageWriteParam.MODE_EXPLICIT); //logger.debug("JPEG qual before: " // + Float.toString(param.getCompressionQuality())); param.setCompressionQuality(0.9f); //logger.debug("JPEG qual now: " // + Float.toString(param.getCompressionQuality())); } writer.setOutput(imgout); // render output logger.debug("writing"); writer.write(null, new IIOImage(img, null, null), param); } else if (mt == "image/png") { // render output writer = (ImageWriter) ImageIO.getImageWritersByFormatName( "png").next(); if (writer == null) { throw new ImageOpException("Unable to get PNG writer"); } writer.setOutput(imgout); logger.debug("writing"); writer.write(img); } else { // unknown mime type throw new ImageOpException("Unknown mime type: " + mt); } } catch (IOException e) { logger.error("Error writing image:", e); throw new ServletException("Error writing image:", e); } // TODO: should we: finally { writer.dispose(); } } public void scale(double scale, double scaleY) throws ImageOpException { logger.debug("scale: " + scale); /* for downscaling in high quality the image is blurred first */ if ((scale <= 0.5) && (quality > 1)) { int bl = (int) Math.floor(1 / scale); blur(bl); } /* then scaled */ AffineTransformOp scaleOp = new AffineTransformOp(AffineTransform .getScaleInstance(scale, scale), renderHint); BufferedImage scaledImg = null; /* enforce destination image type (*Java2D BUG*) int type = img.getType(); if ((quality > 0) && (type != 0)) { logger.debug("creating destination image"); Rectangle2D dstBounds = scaleOp.getBounds2D(img); scaledImg = new BufferedImage((int) dstBounds.getWidth(), (int) dstBounds.getHeight(), type); } */ logger.debug("scaling..."); scaledImg = scaleOp.filter(img, scaledImg); if (scaledImg == null) { throw new ImageOpException("Unable to scale"); } // DEBUG logger.debug("destination image type " + scaledImg.getType()); logger.debug("SCALE: " + scale + " ->" + scaledImg.getWidth() + "x" + scaledImg.getHeight()); img = scaledImg; } public void blur(int radius) throws ImageOpException { logger.debug("blur: " + radius); // minimum radius is 2 int klen = Math.max(radius, 2); Kernel blur = null; if (klen < convolutionKernels.length) { blur = convolutionKernels[klen]; } else { // calculate our own kernel int ksize = klen * klen; // kernel is constant 1/k float f = 1f / ksize; float[] kern = new float[ksize]; for (int i = 0; i < ksize; ++i) { kern[i] = f; } blur = new Kernel(klen, klen, kern); } // blur with convolve operation ConvolveOp blurOp = new ConvolveOp(blur, ConvolveOp.EDGE_NO_OP, renderHint); BufferedImage blurredImg = null; // blur needs explicit destination image type for color *Java2D BUG* if (img.getType() == BufferedImage.TYPE_3BYTE_BGR) { logger.debug("blur: fixing destination image type"); blurredImg = new BufferedImage(img.getWidth(), img.getHeight(), img .getType()); } blurredImg = blurOp.filter(img, blurredImg); img = blurredImg; } public void crop(int x_off, int y_off, int width, int height) throws ImageOpException { // setup Crop BufferedImage croppedImg = img.getSubimage(x_off, y_off, width, height); if (croppedImg == null) { throw new ImageOpException("Unable to crop"); } logger.debug("CROP:" + croppedImg.getWidth() + "x" + croppedImg.getHeight()); img = croppedImg; } public void enhance(float mult, float add) throws ImageOpException { /* * Only one constant should work regardless of the number of bands * according to the JDK spec. Doesn't work on JDK 1.4 for OSX and Linux * (at least). RescaleOp scaleOp = new RescaleOp( (float)mult, * (float)add, null); scaleOp.filter(img, img); */ /* The number of constants must match the number of bands in the image. */ int ncol = img.getColorModel().getNumComponents(); float[] dm = new float[ncol]; float[] da = new float[ncol]; for (int i = 0; i < ncol; i++) { dm[i] = (float) mult; da[i] = (float) add; } RescaleOp scaleOp = new RescaleOp(dm, da, null); scaleOp.filter(img, img); } public void enhanceRGB(float[] rgbm, float[] rgba) throws ImageOpException { /* * The number of constants must match the number of bands in the image. * We do only 3 (RGB) bands. */ int ncol = img.getColorModel().getNumColorComponents(); if ((ncol != 3) || (rgbm.length != 3) || (rgba.length != 3)) { logger.debug("ERROR(enhance): unknown number of color bands or coefficients (" + ncol + ")"); return; } RescaleOp scaleOp = new RescaleOp(rgbOrdered(rgbm), rgbOrdered(rgba), null); scaleOp.filter(img, img); } /** * Ensures that the array f is in the right order to map the images RGB * components. (not sure what happens otherwise) */ public float[] rgbOrdered(float[] fa) { /* * TODO: this is UGLY, UGLY!! */ float[] fb; int t = img.getType(); if (img.getColorModel().hasAlpha()) { fb = new float[4]; if ((t == BufferedImage.TYPE_INT_ARGB) || (t == BufferedImage.TYPE_INT_ARGB_PRE)) { // RGB Type fb[0] = fa[0]; fb[1] = fa[1]; fb[2] = fa[2]; fb[3] = 1f; } else { // this isn't tested :-( fb[0] = 1f; fb[1] = fa[0]; fb[2] = fa[1]; fb[3] = fa[2]; } } else { fb = new float[3]; if (t == BufferedImage.TYPE_3BYTE_BGR) { // BGR Type (actually it looks like RBG...) fb[0] = fa[0]; fb[1] = fa[2]; fb[2] = fa[1]; } else { fb[0] = fa[0]; fb[1] = fa[1]; fb[2] = fa[2]; } } return fb; } /* * (non-Javadoc) * * @see * digilib.image.DocuImageImpl#colorOp(digilib.image.DocuImage.ColorOps) */ public void colorOp(ColorOp op) throws ImageOpException { if (op == ColorOp.GRAYSCALE) { // convert image to grayscale ColorConvertOp colop = new ColorConvertOp( ColorSpace.getInstance(ColorSpace.CS_GRAY), null); img = colop.filter(img, null); } } public void rotate(double angle) throws ImageOpException { // setup rotation double rangle = Math.toRadians(angle); // create offset to make shure the rotated image has no negative // coordinates double w = img.getWidth(); double h = img.getHeight(); AffineTransform trafo = new AffineTransform(); // center of rotation double x = (w / 2); double y = (h / 2); trafo.rotate(rangle, x, y); // try rotation to see how far we're out of bounds AffineTransformOp rotOp = new AffineTransformOp(trafo, renderHint); Rectangle2D rotbounds = rotOp.getBounds2D(img); double xoff = rotbounds.getX(); double yoff = rotbounds.getY(); // move image back in line trafo.preConcatenate(AffineTransform.getTranslateInstance(-xoff, -yoff)); // transform image rotOp = new AffineTransformOp(trafo, renderHint); BufferedImage rotImg = rotOp.filter(img, null); // calculate new bounding box // Rectangle2D bounds = rotOp.getBounds2D(img); img = rotImg; // crop new image (with self-made rounding) /* * img = rotImg.getSubimage( (int) (bounds.getX()+0.5), (int) * (bounds.getY()+0.5), (int) (bounds.getWidth()+0.5), (int) * (bounds.getHeight()+0.5)); */ } public void mirror(double angle) throws ImageOpException { // setup mirror double mx = 1; double my = 1; double tx = 0; double ty = 0; if (Math.abs(angle - 0) < epsilon) { // 0 degree mx = -1; tx = getWidth(); } else if (Math.abs(angle - 90) < epsilon) { // 90 degree my = -1; ty = getHeight(); } else if (Math.abs(angle - 180) < epsilon) { // 180 degree mx = -1; tx = getWidth(); } else if (Math.abs(angle - 270) < epsilon) { // 270 degree my = -1; ty = getHeight(); } else if (Math.abs(angle - 360) < epsilon) { // 360 degree mx = -1; tx = getWidth(); } AffineTransformOp mirOp = new AffineTransformOp(new AffineTransform(mx, 0, 0, my, tx, ty), renderHint); BufferedImage mirImg = mirOp.filter(img, null); img = mirImg; } public void dispose() { // is this necessary? img = null; } public Image getAwtImage(){ return (Image) img; } }