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/*
* Copyright (C)2011-2012, 2014-2015, 2017 D. R. Commander.
* All Rights Reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* - Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* - Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
* - Neither the name of the libjpeg-turbo Project nor the names of its
* contributors may be used to endorse or promote products derived from this
* software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS",
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*
* This program demonstrates how to compress, decompress, and transform JPEG
* images using the TurboJPEG Java API
*/
import java.io.*;
import java.awt.*;
import java.awt.image.*;
import java.nio.*;
import javax.imageio.*;
import javax.swing.*;
import org.libjpegturbo.turbojpeg.*;
public class TJExample implements TJCustomFilter {
private static final String classname = new TJExample().getClass().getName();
private static final int DEFAULT_SUBSAMP = TJ.SAMP_444;
private static final int DEFAULT_QUALITY = 95;
private static final String[] subsampName = {
"4:4:4", "4:2:2", "4:2:0", "Grayscale", "4:4:0", "4:1:1"
};
private static final String[] colorspaceName = {
"RGB", "YCbCr", "GRAY", "CMYK", "YCCK"
};
/* DCT filter example. This produces a negative of the image. */
public void customFilter(ShortBuffer coeffBuffer, Rectangle bufferRegion,
Rectangle planeRegion, int componentIndex,
int transformIndex, TJTransform transform)
throws TJException {
for (int i = 0; i < bufferRegion.width * bufferRegion.height; i++) {
coeffBuffer.put(i, (short)(-coeffBuffer.get(i)));
}
}
private static final void usage() throws Exception {
System.out.println("\nUSAGE: java [Java options] " + classname +
" <Input image> <Output image> [options]\n");
System.out.println("Input and output images can be in any image format that the Java Image I/O");
System.out.println("extensions understand. If either filename ends in a .jpg extension, then");
System.out.println("the TurboJPEG API will be used to compress or decompress the image.\n");
System.out.println("Compression Options (used if the output image is a JPEG image)");
System.out.println("--------------------------------------------------------------\n");
System.out.println("-subsamp <444|422|420|gray> = Apply this level of chrominance subsampling when");
System.out.println(" compressing the output image. The default is to use the same level of");
System.out.println(" subsampling as in the input image, if the input image is also a JPEG");
System.out.println(" image, or to use grayscale if the input image is a grayscale non-JPEG");
System.out.println(" image, or to use " + subsampName[DEFAULT_SUBSAMP] + " subsampling otherwise.\n");
System.out.println("-q <1-100> = Compress the output image with this JPEG quality level");
System.out.println(" (default = " + DEFAULT_QUALITY + ").\n");
System.out.println("Decompression Options (used if the input image is a JPEG image)");
System.out.println("---------------------------------------------------------------\n");
System.out.println("-scale M/N = Scale the input image by a factor of M/N when decompressing it.");
System.out.print("(M/N = ");
for (int i = 0; i < scalingFactors.length; i++) {
System.out.print(scalingFactors[i].getNum() + "/" +
scalingFactors[i].getDenom());
if (scalingFactors.length == 2 && i != scalingFactors.length - 1)
System.out.print(" or ");
else if (scalingFactors.length > 2) {
if (i != scalingFactors.length - 1)
System.out.print(", ");
if (i == scalingFactors.length - 2)
System.out.print("or ");
}
}
System.out.println(")\n");
System.out.println("-hflip, -vflip, -transpose, -transverse, -rot90, -rot180, -rot270 =");
System.out.println(" Perform one of these lossless transform operations on the input image");
System.out.println(" prior to decompressing it (these options are mutually exclusive.)\n");
System.out.println("-grayscale = Perform lossless grayscale conversion on the input image prior");
System.out.println(" to decompressing it (can be combined with the other transform operations");
System.out.println(" above.)\n");
System.out.println("-crop WxH+X+Y = Perform lossless cropping on the input image prior to");
System.out.println(" decompressing it. X and Y specify the upper left corner of the cropping");
System.out.println(" region, and W and H specify the width and height of the cropping region.");
System.out.println(" X and Y must be evenly divible by the MCU block size (8x8 if the input");
System.out.println(" image was compressed using no subsampling or grayscale, 16x8 if it was");
System.out.println(" compressed using 4:2:2 subsampling, or 16x16 if it was compressed using");
System.out.println(" 4:2:0 subsampling.)\n");
System.out.println("General Options");
System.out.println("---------------\n");
System.out.println("-display = Display output image (Output filename need not be specified in this");
System.out.println(" case.)\n");
System.out.println("-fastupsample = Use the fastest chrominance upsampling algorithm available in");
System.out.println(" the underlying codec.\n");
System.out.println("-fastdct = Use the fastest DCT/IDCT algorithms available in the underlying");
System.out.println(" codec.\n");
System.out.println("-accuratedct = Use the most accurate DCT/IDCT algorithms available in the");
System.out.println(" underlying codec.\n");
System.exit(1);
}
public static void main(String[] argv) {
try {
TJScalingFactor scalingFactor = new TJScalingFactor(1, 1);
int outSubsamp = -1, outQual = -1;
TJTransform xform = new TJTransform();
boolean display = false;
int flags = 0;
int width, height;
String inFormat = "jpg", outFormat = "jpg";
BufferedImage img = null;
byte[] imgBuf = null;
if (argv.length < 2)
usage();
if (argv[1].substring(0, 2).equalsIgnoreCase("-d"))
display = true;
/* Parse arguments. */
for (int i = 2; i < argv.length; i++) {
if (argv[i].length() < 2)
continue;
else if (argv[i].length() > 2 &&
argv[i].substring(0, 3).equalsIgnoreCase("-sc") &&
i < argv.length - 1) {
int match = 0;
String[] scaleArg = argv[++i].split("/");
if (scaleArg.length == 2) {
TJScalingFactor tempsf =
new TJScalingFactor(Integer.parseInt(scaleArg[0]),
Integer.parseInt(scaleArg[1]));
for (int j = 0; j < scalingFactors.length; j++) {
if (tempsf.equals(scalingFactors[j])) {
scalingFactor = scalingFactors[j];
match = 1;
break;
}
}
}
if (match != 1)
usage();
}
else if (argv[i].length() > 2 &&
argv[i].substring(0, 3).equalsIgnoreCase("-su") &&
i < argv.length - 1) {
i++;
if (argv[i].substring(0, 1).equalsIgnoreCase("g"))
outSubsamp = TJ.SAMP_GRAY;
else if (argv[i].equals("444"))
outSubsamp = TJ.SAMP_444;
else if (argv[i].equals("422"))
outSubsamp = TJ.SAMP_422;
else if (argv[i].equals("420"))
outSubsamp = TJ.SAMP_420;
else
usage();
}
else if (argv[i].substring(0, 2).equalsIgnoreCase("-q") &&
i < argv.length - 1) {
outQual = Integer.parseInt(argv[++i]);
if (outQual < 1 || outQual > 100)
usage();
} else if (argv[i].substring(0, 2).equalsIgnoreCase("-g"))
xform.options |= TJTransform.OPT_GRAY;
else if (argv[i].equalsIgnoreCase("-hflip"))
xform.op = TJTransform.OP_HFLIP;
else if (argv[i].equalsIgnoreCase("-vflip"))
xform.op = TJTransform.OP_VFLIP;
else if (argv[i].equalsIgnoreCase("-transpose"))
xform.op = TJTransform.OP_TRANSPOSE;
else if (argv[i].equalsIgnoreCase("-transverse"))
xform.op = TJTransform.OP_TRANSVERSE;
else if (argv[i].equalsIgnoreCase("-rot90"))
xform.op = TJTransform.OP_ROT90;
else if (argv[i].equalsIgnoreCase("-rot180"))
xform.op = TJTransform.OP_ROT180;
else if (argv[i].equalsIgnoreCase("-rot270"))
xform.op = TJTransform.OP_ROT270;
else if (argv[i].equalsIgnoreCase("-custom"))
xform.cf = new TJExample();
else if (argv[i].length() > 2 &&
argv[i].substring(0, 2).equalsIgnoreCase("-c") &&
i < argv.length - 1) {
String[] cropArg = argv[++i].split("[x\\+]");
if (cropArg.length != 4)
usage();
xform.width = Integer.parseInt(cropArg[0]);
xform.height = Integer.parseInt(cropArg[1]);
xform.x = Integer.parseInt(cropArg[2]);
xform.y = Integer.parseInt(cropArg[3]);
if (xform.x < 0 || xform.y < 0 || xform.width < 1 ||
xform.height < 1)
usage();
xform.options |= TJTransform.OPT_CROP;
}
else if (argv[i].substring(0, 2).equalsIgnoreCase("-d"))
display = true;
else if (argv[i].equalsIgnoreCase("-fastupsample")) {
System.out.println("Using fast upsampling code");
flags |= TJ.FLAG_FASTUPSAMPLE;
}
else if (argv[i].equalsIgnoreCase("-fastdct")) {
System.out.println("Using fastest DCT/IDCT algorithm");
flags |= TJ.FLAG_FASTDCT;
}
else if (argv[i].equalsIgnoreCase("-accuratedct")) {
System.out.println("Using most accurate DCT/IDCT algorithm");
flags |= TJ.FLAG_ACCURATEDCT;
}
else usage();
}
/* Determine input and output image formats based on file extensions. */
String[] inFileTokens = argv[0].split("\\.");
if (inFileTokens.length > 1)
inFormat = inFileTokens[inFileTokens.length - 1];
String[] outFileTokens;
if (display)
outFormat = "bmp";
else {
outFileTokens = argv[1].split("\\.");
if (outFileTokens.length > 1)
outFormat = outFileTokens[outFileTokens.length - 1];
}
if (inFormat.equalsIgnoreCase("jpg")) {
/* Input image is a JPEG image. Decompress and/or transform it. */
boolean doTransform = (xform.op != TJTransform.OP_NONE ||
xform.options != 0 || xform.cf != null);
/* Read the JPEG file into memory. */
File jpegFile = new File(argv[0]);
FileInputStream fis = new FileInputStream(jpegFile);
int jpegSize = fis.available();
if (jpegSize < 1) {
System.out.println("Input file contains no data");
System.exit(1);
}
byte[] jpegBuf = new byte[jpegSize];
fis.read(jpegBuf);
fis.close();
TJDecompressor tjd;
if (doTransform) {
/* Transform it. */
TJTransformer tjt = new TJTransformer(jpegBuf);
TJTransform[] xforms = new TJTransform[1];
xforms[0] = xform;
xforms[0].options |= TJTransform.OPT_TRIM;
TJDecompressor[] tjds = tjt.transform(xforms, 0);
tjd = tjds[0];
tjt.close();
} else
tjd = new TJDecompressor(jpegBuf);
width = tjd.getWidth();
height = tjd.getHeight();
int inSubsamp = tjd.getSubsamp();
int inColorspace = tjd.getColorspace();
System.out.println((doTransform ? "Transformed" : "Input") +
" Image (jpg): " + width + " x " + height +
" pixels, " + subsampName[inSubsamp] +
" subsampling, " + colorspaceName[inColorspace]);
if (outFormat.equalsIgnoreCase("jpg") && doTransform &&
scalingFactor.isOne() && outSubsamp < 0 && outQual < 0) {
/* Input image has been transformed, and no re-compression options
have been selected. Write the transformed image to disk and
exit. */
File outFile = new File(argv[1]);
FileOutputStream fos = new FileOutputStream(outFile);
fos.write(tjd.getJPEGBuf(), 0, tjd.getJPEGSize());
fos.close();
System.exit(0);
}
/* Scaling and/or a non-JPEG output image format and/or compression
options have been selected, so we need to decompress the
input/transformed image. */
width = scalingFactor.getScaled(width);
height = scalingFactor.getScaled(height);
if (outSubsamp < 0)
outSubsamp = inSubsamp;
if (!outFormat.equalsIgnoreCase("jpg"))
img = tjd.decompress(width, height, BufferedImage.TYPE_INT_RGB,
flags);
else
imgBuf = tjd.decompress(width, 0, height, TJ.PF_BGRX, flags);
tjd.close();
} else {
/* Input image is not a JPEG image. Load it into memory. */
img = ImageIO.read(new File(argv[0]));
if (img == null)
throw new Exception("Input image type not supported.");
width = img.getWidth();
height = img.getHeight();
if (outSubsamp < 0) {
if (img.getType() == BufferedImage.TYPE_BYTE_GRAY)
outSubsamp = TJ.SAMP_GRAY;
else
outSubsamp = DEFAULT_SUBSAMP;
}
System.out.println("Input Image: " + width + " x " + height +
" pixels");
}
System.gc();
if (!display)
System.out.print("Output Image (" + outFormat + "): " + width +
" x " + height + " pixels");
if (display) {
/* Display the uncompressed image */
ImageIcon icon = new ImageIcon(img);
JLabel label = new JLabel(icon, JLabel.CENTER);
JOptionPane.showMessageDialog(null, label, "Output Image",
JOptionPane.PLAIN_MESSAGE);
} else if (outFormat.equalsIgnoreCase("jpg")) {
/* Output image format is JPEG. Compress the uncompressed image. */
if (outQual < 0)
outQual = DEFAULT_QUALITY;
System.out.println(", " + subsampName[outSubsamp] +
" subsampling, quality = " + outQual);
TJCompressor tjc = new TJCompressor();
tjc.setSubsamp(outSubsamp);
tjc.setJPEGQuality(outQual);
if (img != null)
tjc.setSourceImage(img, 0, 0, 0, 0);
else
tjc.setSourceImage(imgBuf, 0, 0, width, 0, height, TJ.PF_BGRX);
byte[] jpegBuf = tjc.compress(flags);
int jpegSize = tjc.getCompressedSize();
tjc.close();
/* Write the JPEG image to disk. */
File outFile = new File(argv[1]);
FileOutputStream fos = new FileOutputStream(outFile);
fos.write(jpegBuf, 0, jpegSize);
fos.close();
} else {
/* Output image format is not JPEG. Save the uncompressed image
directly to disk. */
System.out.print("\n");
File outFile = new File(argv[1]);
ImageIO.write(img, outFormat, outFile);
}
} catch(Exception e) {
e.printStackTrace();
System.exit(-1);
}
}
private static final TJScalingFactor[] scalingFactors = TJ.getScalingFactors();
};