/*
* $Id: Image.java 4847 2011-05-05 19:46:13Z redlab_b $
*
* This file is part of the iText (R) project.
* Copyright (c) 1998-2011 1T3XT BVBA
* Authors: Bruno Lowagie, Paulo Soares, et al.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License version 3
* as published by the Free Software Foundation with the addition of the
* following permission added to Section 15 as permitted in Section 7(a):
* FOR ANY PART OF THE COVERED WORK IN WHICH THE COPYRIGHT IS OWNED BY 1T3XT,
* 1T3XT DISCLAIMS THE WARRANTY OF NON INFRINGEMENT OF THIRD PARTY RIGHTS.
*
* 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 Affero General Public License for more details.
* You should have received a copy of the GNU Affero General Public License
* along with this program; if not, see http://www.gnu.org/licenses or write to
* the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
* Boston, MA, 02110-1301 USA, or download the license from the following URL:
* http://itextpdf.com/terms-of-use/
*
* The interactive user interfaces in modified source and object code versions
* of this program must display Appropriate Legal Notices, as required under
* Section 5 of the GNU Affero General Public License.
*
* In accordance with Section 7(b) of the GNU Affero General Public License,
* a covered work must retain the producer line in every PDF that is created
* or manipulated using iText.
*
* You can be released from the requirements of the license by purchasing
* a commercial license. Buying such a license is mandatory as soon as you
* develop commercial activities involving the iText software without
* disclosing the source code of your own applications.
* These activities include: offering paid services to customers as an ASP,
* serving PDFs on the fly in a web application, shipping iText with a closed
* source product.
*
* For more information, please contact iText Software Corp. at this
* address: sales@itextpdf.com
*/
package com.itextpdf.text;
import java.awt.Graphics2D;
import java.awt.image.BufferedImage;
import java.io.IOException;
import java.io.InputStream;
import java.lang.reflect.Constructor;
import java.net.MalformedURLException;
import java.net.URL;
import com.itextpdf.text.error_messages.MessageLocalization;
import com.itextpdf.text.pdf.ICC_Profile;
import com.itextpdf.text.pdf.PRIndirectReference;
import com.itextpdf.text.pdf.PdfArray;
import com.itextpdf.text.pdf.PdfContentByte;
import com.itextpdf.text.pdf.PdfDictionary;
import com.itextpdf.text.pdf.PdfIndirectReference;
import com.itextpdf.text.pdf.PdfName;
import com.itextpdf.text.pdf.PdfNumber;
import com.itextpdf.text.pdf.PdfOCG;
import com.itextpdf.text.pdf.PdfObject;
import com.itextpdf.text.pdf.PdfReader;
import com.itextpdf.text.pdf.PdfStream;
import com.itextpdf.text.pdf.PdfTemplate;
import com.itextpdf.text.pdf.PdfWriter;
import com.itextpdf.text.pdf.RandomAccessFileOrArray;
import com.itextpdf.text.pdf.codec.BmpImage;
import com.itextpdf.text.pdf.codec.CCITTG4Encoder;
import com.itextpdf.text.pdf.codec.GifImage;
import com.itextpdf.text.pdf.codec.JBIG2Image;
import com.itextpdf.text.pdf.codec.PngImage;
import com.itextpdf.text.pdf.codec.TiffImage;
/**
* An <CODE>Image</CODE> is the representation of a graphic element (JPEG, PNG
* or GIF) that has to be inserted into the document
*
* @see Element
* @see Rectangle
*/
public abstract class Image extends Rectangle {
// static final membervariables
/** this is a kind of image alignment. */
public static final int DEFAULT = 0;
/** this is a kind of image alignment. */
public static final int RIGHT = 2;
/** this is a kind of image alignment. */
public static final int LEFT = 0;
/** this is a kind of image alignment. */
public static final int MIDDLE = 1;
/** this is a kind of image alignment. */
public static final int TEXTWRAP = 4;
/** this is a kind of image alignment. */
public static final int UNDERLYING = 8;
/** This represents a coordinate in the transformation matrix. */
public static final int AX = 0;
/** This represents a coordinate in the transformation matrix. */
public static final int AY = 1;
/** This represents a coordinate in the transformation matrix. */
public static final int BX = 2;
/** This represents a coordinate in the transformation matrix. */
public static final int BY = 3;
/** This represents a coordinate in the transformation matrix. */
public static final int CX = 4;
/** This represents a coordinate in the transformation matrix. */
public static final int CY = 5;
/** This represents a coordinate in the transformation matrix. */
public static final int DX = 6;
/** This represents a coordinate in the transformation matrix. */
public static final int DY = 7;
/** type of image */
public static final int ORIGINAL_NONE = 0;
/** type of image */
public static final int ORIGINAL_JPEG = 1;
/** type of image */
public static final int ORIGINAL_PNG = 2;
/** type of image */
public static final int ORIGINAL_GIF = 3;
/** type of image */
public static final int ORIGINAL_BMP = 4;
/** type of image */
public static final int ORIGINAL_TIFF = 5;
/** type of image */
public static final int ORIGINAL_WMF = 6;
/** type of image */
public static final int ORIGINAL_PS = 7;
/** type of image */
public static final int ORIGINAL_JPEG2000 = 8;
/**
* type of image
* @since 2.1.5
*/
public static final int ORIGINAL_JBIG2 = 9;
// member variables
/** The image type. */
protected int type;
/** The URL of the image. */
protected URL url;
/** The raw data of the image. */
protected byte rawData[];
/** The bits per component of the raw image. It also flags a CCITT image. */
protected int bpc = 1;
/** The template to be treated as an image. */
protected PdfTemplate template[] = new PdfTemplate[1];
/** The alignment of the Image. */
protected int alignment;
/** Text that can be shown instead of the image. */
protected String alt;
/** This is the absolute X-position of the image. */
protected float absoluteX = Float.NaN;
/** This is the absolute Y-position of the image. */
protected float absoluteY = Float.NaN;
/** This is the width of the image without rotation. */
protected float plainWidth;
/** This is the width of the image without rotation. */
protected float plainHeight;
/** This is the scaled width of the image taking rotation into account. */
protected float scaledWidth;
/** This is the original height of the image taking rotation into account. */
protected float scaledHeight;
/**
* The compression level of the content streams.
* @since 2.1.3
*/
protected int compressionLevel = PdfStream.DEFAULT_COMPRESSION;
/** an iText attributed unique id for this image. */
protected Long mySerialId = getSerialId();
// image from file or URL
/**
* Constructs an <CODE>Image</CODE> -object, using an <VAR>url </VAR>.
*
* @param url
* the <CODE>URL</CODE> where the image can be found.
*/
public Image(final URL url) {
super(0, 0);
this.url = url;
this.alignment = DEFAULT;
rotationRadians = 0;
}
/**
* Gets an instance of an Image.
*
* @param url
* an URL
* @return an Image
* @throws BadElementException
* @throws MalformedURLException
* @throws IOException
*/
public static Image getInstance(final URL url) throws BadElementException,
MalformedURLException, IOException {
InputStream is = null;
try {
is = url.openStream();
int c1 = is.read();
int c2 = is.read();
int c3 = is.read();
int c4 = is.read();
// jbig2
int c5 = is.read();
int c6 = is.read();
int c7 = is.read();
int c8 = is.read();
is.close();
is = null;
if (c1 == 'G' && c2 == 'I' && c3 == 'F') {
GifImage gif = new GifImage(url);
Image img = gif.getImage(1);
return img;
}
if (c1 == 0xFF && c2 == 0xD8) {
return new Jpeg(url);
}
if (c1 == 0x00 && c2 == 0x00 && c3 == 0x00 && c4 == 0x0c) {
return new Jpeg2000(url);
}
if (c1 == 0xff && c2 == 0x4f && c3 == 0xff && c4 == 0x51) {
return new Jpeg2000(url);
}
if (c1 == PngImage.PNGID[0] && c2 == PngImage.PNGID[1]
&& c3 == PngImage.PNGID[2] && c4 == PngImage.PNGID[3]) {
return PngImage.getImage(url);
}
if (c1 == 0xD7 && c2 == 0xCD) {
return new ImgWMF(url);
}
if (c1 == 'B' && c2 == 'M') {
return BmpImage.getImage(url);
}
if (c1 == 'M' && c2 == 'M' && c3 == 0 && c4 == 42
|| c1 == 'I' && c2 == 'I' && c3 == 42 && c4 == 0) {
RandomAccessFileOrArray ra = null;
try {
if (url.getProtocol().equals("file")) {
String file = url.getFile();
file = Utilities.unEscapeURL(file);
ra = new RandomAccessFileOrArray(file);
} else
ra = new RandomAccessFileOrArray(url);
Image img = TiffImage.getTiffImage(ra, 1);
img.url = url;
return img;
} finally {
if (ra != null)
ra.close();
}
}
if ( c1 == 0x97 && c2 == 'J' && c3 == 'B' && c4 == '2' &&
c5 == '\r' && c6 == '\n' && c7 == 0x1a && c8 == '\n' ) {
RandomAccessFileOrArray ra = null;
try {
if (url.getProtocol().equals("file")) {
String file = url.getFile();
file = Utilities.unEscapeURL(file);
ra = new RandomAccessFileOrArray(file);
} else
ra = new RandomAccessFileOrArray(url);
Image img = JBIG2Image.getJbig2Image(ra, 1);
img.url = url;
return img;
} finally {
if (ra != null)
ra.close();
}
}
throw new IOException(url.toString()
+ " is not a recognized imageformat.");
} finally {
if (is != null) {
is.close();
}
}
}
/**
* Gets an instance of an Image.
*
* @param filename
* a filename
* @return an object of type <CODE>Gif</CODE>,<CODE>Jpeg</CODE> or
* <CODE>Png</CODE>
* @throws BadElementException
* @throws MalformedURLException
* @throws IOException
*/
public static Image getInstance(final String filename)
throws BadElementException, MalformedURLException, IOException {
return getInstance(Utilities.toURL(filename));
}
/**
* gets an instance of an Image
*
* @param imgb
* raw image date
* @return an Image object
* @throws BadElementException
* @throws MalformedURLException
* @throws IOException
*/
public static Image getInstance(final byte imgb[]) throws BadElementException,
MalformedURLException, IOException {
InputStream is = null;
try {
is = new java.io.ByteArrayInputStream(imgb);
int c1 = is.read();
int c2 = is.read();
int c3 = is.read();
int c4 = is.read();
is.close();
is = null;
if (c1 == 'G' && c2 == 'I' && c3 == 'F') {
GifImage gif = new GifImage(imgb);
return gif.getImage(1);
}
if (c1 == 0xFF && c2 == 0xD8) {
return new Jpeg(imgb);
}
if (c1 == 0x00 && c2 == 0x00 && c3 == 0x00 && c4 == 0x0c) {
return new Jpeg2000(imgb);
}
if (c1 == 0xff && c2 == 0x4f && c3 == 0xff && c4 == 0x51) {
return new Jpeg2000(imgb);
}
if (c1 == PngImage.PNGID[0] && c2 == PngImage.PNGID[1]
&& c3 == PngImage.PNGID[2] && c4 == PngImage.PNGID[3]) {
return PngImage.getImage(imgb);
}
if (c1 == 0xD7 && c2 == 0xCD) {
return new ImgWMF(imgb);
}
if (c1 == 'B' && c2 == 'M') {
return BmpImage.getImage(imgb);
}
if (c1 == 'M' && c2 == 'M' && c3 == 0 && c4 == 42
|| c1 == 'I' && c2 == 'I' && c3 == 42 && c4 == 0) {
RandomAccessFileOrArray ra = null;
try {
ra = new RandomAccessFileOrArray(imgb);
Image img = TiffImage.getTiffImage(ra, 1);
if (img.getOriginalData() == null)
img.setOriginalData(imgb);
return img;
} finally {
if (ra != null)
ra.close();
}
}
if ( c1 == 0x97 && c2 == 'J' && c3 == 'B' && c4 == '2' ) {
is = new java.io.ByteArrayInputStream(imgb);
is.skip(4);
int c5 = is.read();
int c6 = is.read();
int c7 = is.read();
int c8 = is.read();
if ( c5 == '\r' && c6 == '\n' && c7 == 0x1a && c8 == '\n' ) {
int file_header_flags = is.read();
// TODO number of pages never read, can be removed?
int number_of_pages = -1;
if ( (file_header_flags & 0x2) == 0x2 ) {
number_of_pages = is.read() << 24 | is.read() << 16 | is.read() << 8 | is.read();
}
is.close();
// a jbig2 file with a file header. the header is the only way we know here.
// embedded jbig2s don't have a header, have to create them by explicit use of Jbig2Image?
// nkerr, 2008-12-05 see also the getInstance(URL)
RandomAccessFileOrArray ra = null;
try {
ra = new RandomAccessFileOrArray(imgb);
Image img = JBIG2Image.getJbig2Image(ra, 1);
if (img.getOriginalData() == null)
img.setOriginalData(imgb);
return img;
} finally {
if (ra != null)
ra.close();
}
}
}
throw new IOException(MessageLocalization.getComposedMessage("the.byte.array.is.not.a.recognized.imageformat"));
} finally {
if (is != null) {
is.close();
}
}
}
/**
* Gets an instance of an Image in raw mode.
*
* @param width
* the width of the image in pixels
* @param height
* the height of the image in pixels
* @param components
* 1,3 or 4 for GrayScale, RGB and CMYK
* @param data
* the image data
* @param bpc
* bits per component
* @return an object of type <CODE>ImgRaw</CODE>
* @throws BadElementException
* on error
*/
public static Image getInstance(final int width, final int height, final int components,
final int bpc, final byte data[]) throws BadElementException {
return Image.getInstance(width, height, components, bpc, data, null);
}
/**
* Creates a JBIG2 Image.
* @param width the width of the image
* @param height the height of the image
* @param data the raw image data
* @param globals JBIG2 globals
* @return the Image
* @since 2.1.5
*/
public static Image getInstance(final int width, final int height, final byte[] data, final byte[] globals) {
Image img = new ImgJBIG2(width, height, data, globals);
return img;
}
/**
* Creates an Image with CCITT G3 or G4 compression. It assumes that the
* data bytes are already compressed.
*
* @param width
* the exact width of the image
* @param height
* the exact height of the image
* @param reverseBits
* reverses the bits in <code>data</code>. Bit 0 is swapped
* with bit 7 and so on
* @param typeCCITT
* the type of compression in <code>data</code>. It can be
* CCITTG4, CCITTG31D, CCITTG32D
* @param parameters
* parameters associated with this stream. Possible values are
* CCITT_BLACKIS1, CCITT_ENCODEDBYTEALIGN, CCITT_ENDOFLINE and
* CCITT_ENDOFBLOCK or a combination of them
* @param data
* the image data
* @return an Image object
* @throws BadElementException
* on error
*/
public static Image getInstance(final int width, final int height, final boolean reverseBits,
final int typeCCITT, final int parameters, final byte[] data)
throws BadElementException {
return Image.getInstance(width, height, reverseBits, typeCCITT,
parameters, data, null);
}
/**
* Creates an Image with CCITT G3 or G4 compression. It assumes that the
* data bytes are already compressed.
*
* @param width
* the exact width of the image
* @param height
* the exact height of the image
* @param reverseBits
* reverses the bits in <code>data</code>. Bit 0 is swapped
* with bit 7 and so on
* @param typeCCITT
* the type of compression in <code>data</code>. It can be
* CCITTG4, CCITTG31D, CCITTG32D
* @param parameters
* parameters associated with this stream. Possible values are
* CCITT_BLACKIS1, CCITT_ENCODEDBYTEALIGN, CCITT_ENDOFLINE and
* CCITT_ENDOFBLOCK or a combination of them
* @param data
* the image data
* @param transparency
* transparency information in the Mask format of the image
* dictionary
* @return an Image object
* @throws BadElementException
* on error
*/
public static Image getInstance(final int width, final int height, final boolean reverseBits,
final int typeCCITT, final int parameters, final byte[] data, final int transparency[])
throws BadElementException {
if (transparency != null && transparency.length != 2)
throw new BadElementException(MessageLocalization.getComposedMessage("transparency.length.must.be.equal.to.2.with.ccitt.images"));
Image img = new ImgCCITT(width, height, reverseBits, typeCCITT,
parameters, data);
img.transparency = transparency;
return img;
}
/**
* Gets an instance of an Image in raw mode.
*
* @param width
* the width of the image in pixels
* @param height
* the height of the image in pixels
* @param components
* 1,3 or 4 for GrayScale, RGB and CMYK
* @param data
* the image data
* @param bpc
* bits per component
* @param transparency
* transparency information in the Mask format of the image
* dictionary
* @return an object of type <CODE>ImgRaw</CODE>
* @throws BadElementException
* on error
*/
public static Image getInstance(final int width, final int height, final int components,
final int bpc, final byte data[], final int transparency[])
throws BadElementException {
if (transparency != null && transparency.length != components * 2)
throw new BadElementException(MessageLocalization.getComposedMessage("transparency.length.must.be.equal.to.componentes.2"));
if (components == 1 && bpc == 1) {
byte g4[] = CCITTG4Encoder.compress(data, width, height);
return Image.getInstance(width, height, false, Image.CCITTG4,
Image.CCITT_BLACKIS1, g4, transparency);
}
Image img = new ImgRaw(width, height, components, bpc, data);
img.transparency = transparency;
return img;
}
// images from a PdfTemplate
/**
* gets an instance of an Image
*
* @param template
* a PdfTemplate that has to be wrapped in an Image object
* @return an Image object
* @throws BadElementException
*/
public static Image getInstance(final PdfTemplate template)
throws BadElementException {
return new ImgTemplate(template);
}
// images from a java.awt.Image
/**
* Gets an instance of an Image from a java.awt.Image.
*
* @param image
* the <CODE>java.awt.Image</CODE> to convert
* @param color
* if different from <CODE>null</CODE> the transparency pixels
* are replaced by this color
* @param forceBW
* if <CODE>true</CODE> the image is treated as black and white
* @return an object of type <CODE>ImgRaw</CODE>
* @throws BadElementException
* on error
* @throws IOException
* on error
*/
public static Image getInstance(final java.awt.Image image, final java.awt.Color color,
boolean forceBW) throws BadElementException, IOException {
if(image instanceof BufferedImage){
BufferedImage bi = (BufferedImage) image;
if(bi.getType()==BufferedImage.TYPE_BYTE_BINARY
&& bi.getColorModel().getPixelSize() == 1) {
forceBW=true;
}
}
java.awt.image.PixelGrabber pg = new java.awt.image.PixelGrabber(image,
0, 0, -1, -1, true);
try {
pg.grabPixels();
} catch (InterruptedException e) {
throw new IOException(MessageLocalization.getComposedMessage("java.awt.image.interrupted.waiting.for.pixels"));
}
if ((pg.getStatus() & java.awt.image.ImageObserver.ABORT) != 0) {
throw new IOException(MessageLocalization.getComposedMessage("java.awt.image.fetch.aborted.or.errored"));
}
int w = pg.getWidth();
int h = pg.getHeight();
int[] pixels = (int[]) pg.getPixels();
if (forceBW) {
int byteWidth = w / 8 + ((w & 7) != 0 ? 1 : 0);
byte[] pixelsByte = new byte[byteWidth * h];
int index = 0;
int size = h * w;
int transColor = 1;
if (color != null) {
transColor = color.getRed() + color.getGreen()
+ color.getBlue() < 384 ? 0 : 1;
}
int transparency[] = null;
int cbyte = 0x80;
int wMarker = 0;
int currByte = 0;
if (color != null) {
for (int j = 0; j < size; j++) {
int alpha = pixels[j] >> 24 & 0xff;
if (alpha < 250) {
if (transColor == 1)
currByte |= cbyte;
} else {
if ((pixels[j] & 0x888) != 0)
currByte |= cbyte;
}
cbyte >>= 1;
if (cbyte == 0 || wMarker + 1 >= w) {
pixelsByte[index++] = (byte) currByte;
cbyte = 0x80;
currByte = 0;
}
++wMarker;
if (wMarker >= w)
wMarker = 0;
}
} else {
for (int j = 0; j < size; j++) {
if (transparency == null) {
int alpha = pixels[j] >> 24 & 0xff;
if (alpha == 0) {
transparency = new int[2];
/* bugfix by M.P. Liston, ASC, was: ... ? 1: 0; */
transparency[0] = transparency[1] = (pixels[j] & 0x888) != 0 ? 0xff : 0;
}
}
if ((pixels[j] & 0x888) != 0)
currByte |= cbyte;
cbyte >>= 1;
if (cbyte == 0 || wMarker + 1 >= w) {
pixelsByte[index++] = (byte) currByte;
cbyte = 0x80;
currByte = 0;
}
++wMarker;
if (wMarker >= w)
wMarker = 0;
}
}
return Image.getInstance(w, h, 1, 1, pixelsByte, transparency);
} else {
byte[] pixelsByte = new byte[w * h * 3];
byte[] smask = null;
int index = 0;
int size = h * w;
int red = 255;
int green = 255;
int blue = 255;
if (color != null) {
red = color.getRed();
green = color.getGreen();
blue = color.getBlue();
}
int transparency[] = null;
if (color != null) {
for (int j = 0; j < size; j++) {
int alpha = pixels[j] >> 24 & 0xff;
if (alpha < 250) {
pixelsByte[index++] = (byte) red;
pixelsByte[index++] = (byte) green;
pixelsByte[index++] = (byte) blue;
} else {
pixelsByte[index++] = (byte) (pixels[j] >> 16 & 0xff);
pixelsByte[index++] = (byte) (pixels[j] >> 8 & 0xff);
pixelsByte[index++] = (byte) (pixels[j] & 0xff);
}
}
} else {
int transparentPixel = 0;
smask = new byte[w * h];
boolean shades = false;
for (int j = 0; j < size; j++) {
byte alpha = smask[j] = (byte) (pixels[j] >> 24 & 0xff);
/* bugfix by Chris Nokleberg */
if (!shades) {
if (alpha != 0 && alpha != -1) {
shades = true;
} else if (transparency == null) {
if (alpha == 0) {
transparentPixel = pixels[j] & 0xffffff;
transparency = new int[6];
transparency[0] = transparency[1] = transparentPixel >> 16 & 0xff;
transparency[2] = transparency[3] = transparentPixel >> 8 & 0xff;
transparency[4] = transparency[5] = transparentPixel & 0xff;
}
} else if ((pixels[j] & 0xffffff) != transparentPixel) {
shades = true;
}
}
pixelsByte[index++] = (byte) (pixels[j] >> 16 & 0xff);
pixelsByte[index++] = (byte) (pixels[j] >> 8 & 0xff);
pixelsByte[index++] = (byte) (pixels[j] & 0xff);
}
if (shades)
transparency = null;
else
smask = null;
}
Image img = Image.getInstance(w, h, 3, 8, pixelsByte, transparency);
if (smask != null) {
Image sm = Image.getInstance(w, h, 1, 8, smask);
try {
sm.makeMask();
img.setImageMask(sm);
} catch (DocumentException de) {
throw new ExceptionConverter(de);
}
}
return img;
}
}
/**
* Gets an instance of an Image from a java.awt.Image.
*
* @param image
* the <CODE>java.awt.Image</CODE> to convert
* @param color
* if different from <CODE>null</CODE> the transparency pixels
* are replaced by this color
* @return an object of type <CODE>ImgRaw</CODE>
* @throws BadElementException
* on error
* @throws IOException
* on error
*/
public static Image getInstance(final java.awt.Image image, final java.awt.Color color)
throws BadElementException, IOException {
return Image.getInstance(image, color, false);
}
/**
* Gets an instance of a Image from a java.awt.Image.
* The image is added as a JPEG with a user defined quality.
*
* @param writer
* the <CODE>PdfWriter</CODE> object to which the image will be added
* @param awtImage
* the <CODE>java.awt.Image</CODE> to convert
* @param quality
* a float value between 0 and 1
* @return an object of type <CODE>PdfTemplate</CODE>
* @throws BadElementException
* on error
* @throws IOException
*/
public static Image getInstance(final PdfWriter writer, final java.awt.Image awtImage, final float quality) throws BadElementException, IOException {
return getInstance(new PdfContentByte(writer), awtImage, quality);
}
/**
* Gets an instance of a Image from a java.awt.Image.
* The image is added as a JPEG with a user defined quality.
*
* @param cb
* the <CODE>PdfContentByte</CODE> object to which the image will be added
* @param awtImage
* the <CODE>java.awt.Image</CODE> to convert
* @param quality
* a float value between 0 and 1
* @return an object of type <CODE>PdfTemplate</CODE>
* @throws BadElementException
* on error
* @throws IOException
*/
public static Image getInstance(final PdfContentByte cb, final java.awt.Image awtImage, final float quality) throws BadElementException, IOException {
java.awt.image.PixelGrabber pg = new java.awt.image.PixelGrabber(awtImage,
0, 0, -1, -1, true);
try {
pg.grabPixels();
} catch (InterruptedException e) {
throw new IOException(MessageLocalization.getComposedMessage("java.awt.image.interrupted.waiting.for.pixels"));
}
if ((pg.getStatus() & java.awt.image.ImageObserver.ABORT) != 0) {
throw new IOException(MessageLocalization.getComposedMessage("java.awt.image.fetch.aborted.or.errored"));
}
int w = pg.getWidth();
int h = pg.getHeight();
PdfTemplate tp = cb.createTemplate(w, h);
Graphics2D g2d = tp.createGraphics(w, h, true, quality);
g2d.drawImage(awtImage, 0, 0, null);
g2d.dispose();
return getInstance(tp);
}
// image from indirect reference
/**
* Holds value of property directReference.
* An image is embedded into a PDF as an Image XObject.
* This object is referenced by a PdfIndirectReference object.
*/
private PdfIndirectReference directReference;
/**
* Getter for property directReference.
* @return Value of property directReference.
*/
public PdfIndirectReference getDirectReference() {
return this.directReference;
}
/**
* Setter for property directReference.
* @param directReference New value of property directReference.
*/
public void setDirectReference(final PdfIndirectReference directReference) {
this.directReference = directReference;
}
/**
* Reuses an existing image.
* @param ref the reference to the image dictionary
* @throws BadElementException on error
* @return the image
*/
public static Image getInstance(final PRIndirectReference ref) throws BadElementException {
PdfDictionary dic = (PdfDictionary)PdfReader.getPdfObjectRelease(ref);
int width = ((PdfNumber)PdfReader.getPdfObjectRelease(dic.get(PdfName.WIDTH))).intValue();
int height = ((PdfNumber)PdfReader.getPdfObjectRelease(dic.get(PdfName.HEIGHT))).intValue();
Image imask = null;
PdfObject obj = dic.get(PdfName.SMASK);
if (obj != null && obj.isIndirect()) {
imask = getInstance((PRIndirectReference)obj);
}
else {
obj = dic.get(PdfName.MASK);
if (obj != null && obj.isIndirect()) {
PdfObject obj2 = PdfReader.getPdfObjectRelease(obj);
if (obj2 instanceof PdfDictionary)
imask = getInstance((PRIndirectReference)obj);
}
}
Image img = new ImgRaw(width, height, 1, 1, null);
img.imageMask = imask;
img.directReference = ref;
return img;
}
// copy constructor
/**
* Constructs an <CODE>Image</CODE> -object, using an <VAR>url </VAR>.
*
* @param image
* another Image object.
*/
protected Image(final Image image) {
super(image);
this.type = image.type;
this.url = image.url;
this.rawData = image.rawData;
this.bpc = image.bpc;
this.template = image.template;
this.alignment = image.alignment;
this.alt = image.alt;
this.absoluteX = image.absoluteX;
this.absoluteY = image.absoluteY;
this.plainWidth = image.plainWidth;
this.plainHeight = image.plainHeight;
this.scaledWidth = image.scaledWidth;
this.scaledHeight = image.scaledHeight;
this.mySerialId = image.mySerialId;
this.directReference = image.directReference;
this.rotationRadians = image.rotationRadians;
this.initialRotation = image.initialRotation;
this.indentationLeft = image.indentationLeft;
this.indentationRight = image.indentationRight;
this.spacingBefore = image.spacingBefore;
this.spacingAfter = image.spacingAfter;
this.widthPercentage = image.widthPercentage;
this.scaleToFitLineWhenOverflow = image.scaleToFitLineWhenOverflow;
this.annotation = image.annotation;
this.layer = image.layer;
this.interpolation = image.interpolation;
this.originalType = image.originalType;
this.originalData = image.originalData;
this.deflated = image.deflated;
this.dpiX = image.dpiX;
this.dpiY = image.dpiY;
this.XYRatio = image.XYRatio;
this.colorspace = image.colorspace;
this.invert = image.invert;
this.profile = image.profile;
this.additional = image.additional;
this.mask = image.mask;
this.imageMask = image.imageMask;
this.smask = image.smask;
this.transparency = image.transparency;
}
/**
* gets an instance of an Image
*
* @param image
* an Image object
* @return a new Image object
*/
public static Image getInstance(final Image image) {
if (image == null)
return null;
try {
Class<? extends Image> cs = image.getClass();
Constructor<? extends Image> constructor = cs
.getDeclaredConstructor(new Class[] { Image.class });
return constructor.newInstance(new Object[] { image });
} catch (Exception e) {
throw new ExceptionConverter(e);
}
}
// implementation of the Element interface
/**
* Returns the type.
*
* @return a type
*/
@Override
public int type() {
return type;
}
/**
* @see com.itextpdf.text.Element#isNestable()
* @since iText 2.0.8
*/
@Override
public boolean isNestable() {
return true;
}
// checking the type of Image
/**
* Returns <CODE>true</CODE> if the image is a <CODE>Jpeg</CODE>
* -object.
*
* @return a <CODE>boolean</CODE>
*/
public boolean isJpeg() {
return type == JPEG;
}
/**
* Returns <CODE>true</CODE> if the image is a <CODE>ImgRaw</CODE>
* -object.
*
* @return a <CODE>boolean</CODE>
*/
public boolean isImgRaw() {
return type == IMGRAW;
}
/**
* Returns <CODE>true</CODE> if the image is an <CODE>ImgTemplate</CODE>
* -object.
*
* @return a <CODE>boolean</CODE>
*/
public boolean isImgTemplate() {
return type == IMGTEMPLATE;
}
// getters and setters
/**
* Gets the <CODE>String</CODE> -representation of the reference to the
* image.
*
* @return a <CODE>String</CODE>
*/
public URL getUrl() {
return url;
}
/**
* Sets the url of the image
*
* @param url
* the url of the image
*/
public void setUrl(final URL url) {
this.url = url;
}
/**
* Gets the raw data for the image.
* <P>
* Remark: this only makes sense for Images of the type <CODE>RawImage
* </CODE>.
*
* @return the raw data
*/
public byte[] getRawData() {
return rawData;
}
/**
* Gets the bpc for the image.
* <P>
* Remark: this only makes sense for Images of the type <CODE>RawImage
* </CODE>.
*
* @return a bpc value
*/
public int getBpc() {
return bpc;
}
/**
* Gets the template to be used as an image.
* <P>
* Remark: this only makes sense for Images of the type <CODE>ImgTemplate
* </CODE>.
*
* @return the template
*/
public PdfTemplate getTemplateData() {
return template[0];
}
/**
* Sets data from a PdfTemplate
*
* @param template
* the template with the content
*/
public void setTemplateData(final PdfTemplate template) {
this.template[0] = template;
}
/**
* Gets the alignment for the image.
*
* @return a value
*/
public int getAlignment() {
return alignment;
}
/**
* Sets the alignment for the image.
*
* @param alignment
* the alignment
*/
public void setAlignment(final int alignment) {
this.alignment = alignment;
}
/**
* Gets the alternative text for the image.
*
* @return a <CODE>String</CODE>
*/
public String getAlt() {
return alt;
}
/**
* Sets the alternative information for the image.
*
* @param alt
* the alternative information
*/
public void setAlt(final String alt) {
this.alt = alt;
}
/**
* Sets the absolute position of the <CODE>Image</CODE>.
*
* @param absoluteX
* @param absoluteY
*/
public void setAbsolutePosition(final float absoluteX, final float absoluteY) {
this.absoluteX = absoluteX;
this.absoluteY = absoluteY;
}
/**
* Checks if the <CODE>Images</CODE> has to be added at an absolute X
* position.
*
* @return a boolean
*/
public boolean hasAbsoluteX() {
return !Float.isNaN(absoluteX);
}
/**
* Returns the absolute X position.
*
* @return a position
*/
public float getAbsoluteX() {
return absoluteX;
}
/**
* Checks if the <CODE>Images</CODE> has to be added at an absolute
* position.
*
* @return a boolean
*/
public boolean hasAbsoluteY() {
return !Float.isNaN(absoluteY);
}
/**
* Returns the absolute Y position.
*
* @return a position
*/
public float getAbsoluteY() {
return absoluteY;
}
// width and height
/**
* Gets the scaled width of the image.
*
* @return a value
*/
public float getScaledWidth() {
return scaledWidth;
}
/**
* Gets the scaled height of the image.
*
* @return a value
*/
public float getScaledHeight() {
return scaledHeight;
}
/**
* Gets the plain width of the image.
*
* @return a value
*/
public float getPlainWidth() {
return plainWidth;
}
/**
* Gets the plain height of the image.
*
* @return a value
*/
public float getPlainHeight() {
return plainHeight;
}
/**
* Scale the image to an absolute width and an absolute height.
*
* @param newWidth
* the new width
* @param newHeight
* the new height
*/
public void scaleAbsolute(final float newWidth, final float newHeight) {
plainWidth = newWidth;
plainHeight = newHeight;
float[] matrix = matrix();
scaledWidth = matrix[DX] - matrix[CX];
scaledHeight = matrix[DY] - matrix[CY];
setWidthPercentage(0);
}
/**
* Scale the image to an absolute width.
*
* @param newWidth
* the new width
*/
public void scaleAbsoluteWidth(final float newWidth) {
plainWidth = newWidth;
float[] matrix = matrix();
scaledWidth = matrix[DX] - matrix[CX];
scaledHeight = matrix[DY] - matrix[CY];
setWidthPercentage(0);
}
/**
* Scale the image to an absolute height.
*
* @param newHeight
* the new height
*/
public void scaleAbsoluteHeight(final float newHeight) {
plainHeight = newHeight;
float[] matrix = matrix();
scaledWidth = matrix[DX] - matrix[CX];
scaledHeight = matrix[DY] - matrix[CY];
setWidthPercentage(0);
}
/**
* Scale the image to a certain percentage.
*
* @param percent
* the scaling percentage
*/
public void scalePercent(final float percent) {
scalePercent(percent, percent);
}
/**
* Scale the width and height of an image to a certain percentage.
*
* @param percentX
* the scaling percentage of the width
* @param percentY
* the scaling percentage of the height
*/
public void scalePercent(final float percentX, final float percentY) {
plainWidth = getWidth() * percentX / 100f;
plainHeight = getHeight() * percentY / 100f;
float[] matrix = matrix();
scaledWidth = matrix[DX] - matrix[CX];
scaledHeight = matrix[DY] - matrix[CY];
setWidthPercentage(0);
}
/**
* Scales the image so that it fits a certain width and height.
*
* @param fitWidth
* the width to fit
* @param fitHeight
* the height to fit
*/
public void scaleToFit(final float fitWidth, final float fitHeight) {
scalePercent(100);
float percentX = fitWidth * 100 / getScaledWidth();
float percentY = fitHeight * 100 / getScaledHeight();
scalePercent(percentX < percentY ? percentX : percentY);
setWidthPercentage(0);
}
/**
* Returns the transformation matrix of the image.
*
* @return an array [AX, AY, BX, BY, CX, CY, DX, DY]
*/
public float[] matrix() {
float[] matrix = new float[8];
float cosX = (float) Math.cos(rotationRadians);
float sinX = (float) Math.sin(rotationRadians);
matrix[AX] = plainWidth * cosX;
matrix[AY] = plainWidth * sinX;
matrix[BX] = -plainHeight * sinX;
matrix[BY] = plainHeight * cosX;
if (rotationRadians < Math.PI / 2f) {
matrix[CX] = matrix[BX];
matrix[CY] = 0;
matrix[DX] = matrix[AX];
matrix[DY] = matrix[AY] + matrix[BY];
} else if (rotationRadians < Math.PI) {
matrix[CX] = matrix[AX] + matrix[BX];
matrix[CY] = matrix[BY];
matrix[DX] = 0;
matrix[DY] = matrix[AY];
} else if (rotationRadians < Math.PI * 1.5f) {
matrix[CX] = matrix[AX];
matrix[CY] = matrix[AY] + matrix[BY];
matrix[DX] = matrix[BX];
matrix[DY] = 0;
} else {
matrix[CX] = 0;
matrix[CY] = matrix[AY];
matrix[DX] = matrix[AX] + matrix[BX];
matrix[DY] = matrix[BY];
}
return matrix;
}
// serial stamping
/** a static that is used for attributing a unique id to each image. */
static long serialId = 0;
/** Creates a new serial id.
* @return the new serialId */
static protected synchronized Long getSerialId() {
++serialId;
return Long.valueOf(serialId);
}
/**
* Returns a serial id for the Image (reuse the same image more than once)
*
* @return a serialId
*/
public Long getMySerialId() {
return mySerialId;
}
// rotation, note that the superclass also has a rotation value.
/** This is the rotation of the image in radians. */
protected float rotationRadians;
/** Holds value of property initialRotation. */
private float initialRotation;
/**
* Gets the current image rotation in radians.
* @return the current image rotation in radians
*/
public float getImageRotation() {
double d = 2.0 * Math.PI;
float rot = (float) ((rotationRadians - initialRotation) % d);
if (rot < 0) {
rot += d;
}
return rot;
}
/**
* Sets the rotation of the image in radians.
*
* @param r
* rotation in radians
*/
public void setRotation(final float r) {
double d = 2.0 * Math.PI;
rotationRadians = (float) ((r + initialRotation) % d);
if (rotationRadians < 0) {
rotationRadians += d;
}
float[] matrix = matrix();
scaledWidth = matrix[DX] - matrix[CX];
scaledHeight = matrix[DY] - matrix[CY];
}
/**
* Sets the rotation of the image in degrees.
*
* @param deg
* rotation in degrees
*/
public void setRotationDegrees(final float deg) {
double d = Math.PI;
setRotation(deg / 180 * (float) d);
}
/**
* Getter for property initialRotation.
* @return Value of property initialRotation.
*/
public float getInitialRotation() {
return this.initialRotation;
}
/**
* Some image formats, like TIFF may present the images rotated that have
* to be compensated.
* @param initialRotation New value of property initialRotation.
*/
public void setInitialRotation(final float initialRotation) {
float old_rot = rotationRadians - this.initialRotation;
this.initialRotation = initialRotation;
setRotation(old_rot);
}
// indentations
/** the indentation to the left. */
protected float indentationLeft = 0;
/** the indentation to the right. */
protected float indentationRight = 0;
/** The spacing before the image. */
protected float spacingBefore;
/** The spacing after the image. */
protected float spacingAfter;
/**
* Gets the left indentation.
*
* @return the left indentation
*/
public float getIndentationLeft() {
return indentationLeft;
}
/**
* Sets the left indentation.
*
* @param f
*/
public void setIndentationLeft(final float f) {
indentationLeft = f;
}
/**
* Gets the right indentation.
*
* @return the right indentation
*/
public float getIndentationRight() {
return indentationRight;
}
/**
* Sets the right indentation.
*
* @param f
*/
public void setIndentationRight(final float f) {
indentationRight = f;
}
/**
* Gets the spacing before this image.
*
* @return the spacing
*/
public float getSpacingBefore() {
return spacingBefore;
}
/**
* Sets the spacing before this image.
*
* @param spacing
* the new spacing
*/
public void setSpacingBefore(final float spacing) {
this.spacingBefore = spacing;
}
/**
* Gets the spacing before this image.
*
* @return the spacing
*/
public float getSpacingAfter() {
return spacingAfter;
}
/**
* Sets the spacing after this image.
*
* @param spacing
* the new spacing
*/
public void setSpacingAfter(final float spacing) {
this.spacingAfter = spacing;
}
// widthpercentage (for the moment only used in ColumnText)
/**
* Holds value of property widthPercentage.
*/
private float widthPercentage = 100;
/**
* Getter for property widthPercentage.
*
* @return Value of property widthPercentage.
*/
public float getWidthPercentage() {
return this.widthPercentage;
}
/**
* Setter for property widthPercentage.
*
* @param widthPercentage
* New value of property widthPercentage.
*/
public void setWidthPercentage(final float widthPercentage) {
this.widthPercentage = widthPercentage;
}
// scaling the image to the available width (or not)
/**
* Indicates if the image should be scaled to fit the line
* when the image exceeds the available width.
* @since iText 5.0.6
*/
protected boolean scaleToFitLineWhenOverflow;
/**
* Gets the value of scaleToFitLineWhenOverflow.
* @return true if the image size has to scale to the available width
* @since iText 5.0.6
*/
public boolean isScaleToFitLineWhenOverflow() {
return scaleToFitLineWhenOverflow;
}
/**
* Sets the value of scaleToFitLineWhenOverflow
* @param scaleToFitLineWhenOverflow true if you want the image to scale to the available width
* @since iText 5.0.6
*/
public void setScaleToFitLineWhenOverflow(final boolean scaleToFitLineWhenOverflow) {
this.scaleToFitLineWhenOverflow = scaleToFitLineWhenOverflow;
}
// annotation
/** if the annotation is not null the image will be clickable. */
protected Annotation annotation = null;
/**
* Sets the annotation of this Image.
*
* @param annotation
* the annotation
*/
public void setAnnotation(final Annotation annotation) {
this.annotation = annotation;
}
/**
* Gets the annotation.
*
* @return the annotation that is linked to this image
*/
public Annotation getAnnotation() {
return annotation;
}
// Optional Content
/** Optional Content layer to which we want this Image to belong. */
protected PdfOCG layer;
/**
* Gets the layer this image belongs to.
*
* @return the layer this image belongs to or <code>null</code> for no
* layer defined
*/
public PdfOCG getLayer() {
return layer;
}
/**
* Sets the layer this image belongs to.
*
* @param layer
* the layer this image belongs to
*/
public void setLayer(final PdfOCG layer) {
this.layer = layer;
}
// interpolation
/** Holds value of property interpolation. */
protected boolean interpolation;
/**
* Getter for property interpolation.
*
* @return Value of property interpolation.
*/
public boolean isInterpolation() {
return interpolation;
}
/**
* Sets the image interpolation. Image interpolation attempts to produce a
* smooth transition between adjacent sample values.
*
* @param interpolation
* New value of property interpolation.
*/
public void setInterpolation(final boolean interpolation) {
this.interpolation = interpolation;
}
// original type and data
/** Holds value of property originalType. */
protected int originalType = ORIGINAL_NONE;
/** Holds value of property originalData. */
protected byte[] originalData;
/**
* Getter for property originalType.
*
* @return Value of property originalType.
*
*/
public int getOriginalType() {
return this.originalType;
}
/**
* Setter for property originalType.
*
* @param originalType
* New value of property originalType.
*
*/
public void setOriginalType(final int originalType) {
this.originalType = originalType;
}
/**
* Getter for property originalData.
*
* @return Value of property originalData.
*
*/
public byte[] getOriginalData() {
return this.originalData;
}
/**
* Setter for property originalData.
*
* @param originalData
* New value of property originalData.
*
*/
public void setOriginalData(final byte[] originalData) {
this.originalData = originalData;
}
// the following values are only set for specific types of images.
/** Holds value of property deflated. */
protected boolean deflated = false;
/**
* Getter for property deflated.
*
* @return Value of property deflated.
*
*/
public boolean isDeflated() {
return this.deflated;
}
/**
* Setter for property deflated.
*
* @param deflated
* New value of property deflated.
*/
public void setDeflated(final boolean deflated) {
this.deflated = deflated;
}
// DPI info
/** Holds value of property dpiX. */
protected int dpiX = 0;
/** Holds value of property dpiY. */
protected int dpiY = 0;
/**
* Gets the dots-per-inch in the X direction. Returns 0 if not available.
*
* @return the dots-per-inch in the X direction
*/
public int getDpiX() {
return dpiX;
}
/**
* Gets the dots-per-inch in the Y direction. Returns 0 if not available.
*
* @return the dots-per-inch in the Y direction
*/
public int getDpiY() {
return dpiY;
}
/**
* Sets the dots per inch value
*
* @param dpiX
* dpi for x coordinates
* @param dpiY
* dpi for y coordinates
*/
public void setDpi(final int dpiX, final int dpiY) {
this.dpiX = dpiX;
this.dpiY = dpiY;
}
// XY Ratio
/** Holds value of property XYRatio. */
private float XYRatio = 0;
/**
* Gets the X/Y pixel dimensionless aspect ratio.
*
* @return the X/Y pixel dimensionless aspect ratio
*/
public float getXYRatio() {
return this.XYRatio;
}
/**
* Sets the X/Y pixel dimensionless aspect ratio.
*
* @param XYRatio
* the X/Y pixel dimensionless aspect ratio
*/
public void setXYRatio(final float XYRatio) {
this.XYRatio = XYRatio;
}
// color, colorspaces and transparency
/** this is the colorspace of a jpeg-image. */
protected int colorspace = -1;
/**
* Gets the colorspace for the image.
* <P>
* Remark: this only makes sense for Images of the type <CODE>Jpeg</CODE>.
*
* @return a colorspace value
*/
public int getColorspace() {
return colorspace;
}
/** Image color inversion */
protected boolean invert = false;
/**
* Getter for the inverted value
*
* @return true if the image is inverted
*/
public boolean isInverted() {
return invert;
}
/**
* Sets inverted true or false
*
* @param invert
* true or false
*/
public void setInverted(final boolean invert) {
this.invert = invert;
}
/** ICC Profile attached */
protected ICC_Profile profile = null;
/**
* Tags this image with an ICC profile.
*
* @param profile
* the profile
*/
public void tagICC(final ICC_Profile profile) {
this.profile = profile;
}
/**
* Checks is the image has an ICC profile.
*
* @return the ICC profile or <CODE>null</CODE>
*/
public boolean hasICCProfile() {
return this.profile != null;
}
/**
* Gets the images ICC profile.
*
* @return the ICC profile
*/
public ICC_Profile getICCProfile() {
return profile;
}
/** a dictionary with additional information */
private PdfDictionary additional = null;
/**
* Getter for the dictionary with additional information.
*
* @return a PdfDictionary with additional information.
*/
public PdfDictionary getAdditional() {
return this.additional;
}
/**
* Sets the /Colorspace key.
*
* @param additional
* a PdfDictionary with additional information.
*/
public void setAdditional(final PdfDictionary additional) {
this.additional = additional;
}
/**
* Replaces CalRGB and CalGray colorspaces with DeviceRGB and DeviceGray.
*/
public void simplifyColorspace() {
if (additional == null)
return;
PdfArray value = additional.getAsArray(PdfName.COLORSPACE);
if (value == null)
return;
PdfObject cs = simplifyColorspace(value);
PdfObject newValue;
if (cs.isName())
newValue = cs;
else {
newValue = value;
PdfName first = value.getAsName(0);
if (PdfName.INDEXED.equals(first)) {
if (value.size() >= 2) {
PdfArray second = value.getAsArray(1);
if (second != null) {
value.set(1, simplifyColorspace(second));
}
}
}
}
additional.put(PdfName.COLORSPACE, newValue);
}
/**
* Gets a PDF Name from an array or returns the object that was passed.
*/
private PdfObject simplifyColorspace(final PdfArray obj) {
if (obj == null)
return obj;
PdfName first = obj.getAsName(0);
if (PdfName.CALGRAY.equals(first))
return PdfName.DEVICEGRAY;
else if (PdfName.CALRGB.equals(first))
return PdfName.DEVICERGB;
else
return obj;
}
/** Is this image a mask? */
protected boolean mask = false;
/** The image that serves as a mask for this image. */
protected Image imageMask;
/** Holds value of property smask. */
private boolean smask;
/**
* Returns <CODE>true</CODE> if this <CODE>Image</CODE> is a mask.
*
* @return <CODE>true</CODE> if this <CODE>Image</CODE> is a mask
*/
public boolean isMask() {
return mask;
}
/**
* Make this <CODE>Image</CODE> a mask.
*
* @throws DocumentException
* if this <CODE>Image</CODE> can not be a mask
*/
public void makeMask() throws DocumentException {
if (!isMaskCandidate())
throw new DocumentException(MessageLocalization.getComposedMessage("this.image.can.not.be.an.image.mask"));
mask = true;
}
/**
* Returns <CODE>true</CODE> if this <CODE>Image</CODE> has the
* requisites to be a mask.
*
* @return <CODE>true</CODE> if this <CODE>Image</CODE> can be a mask
*/
public boolean isMaskCandidate() {
if (type == IMGRAW) {
if (bpc > 0xff)
return true;
}
return colorspace == 1;
}
/**
* Gets the explicit masking.
*
* @return the explicit masking
*/
public Image getImageMask() {
return imageMask;
}
/**
* Sets the explicit masking.
*
* @param mask
* the mask to be applied
* @throws DocumentException
* on error
*/
public void setImageMask(final Image mask) throws DocumentException {
if (this.mask)
throw new DocumentException(MessageLocalization.getComposedMessage("an.image.mask.cannot.contain.another.image.mask"));
if (!mask.mask)
throw new DocumentException(MessageLocalization.getComposedMessage("the.image.mask.is.not.a.mask.did.you.do.makemask"));
imageMask = mask;
smask = mask.bpc > 1 && mask.bpc <= 8;
}
/**
* Getter for property smask.
*
* @return Value of property smask.
*
*/
public boolean isSmask() {
return this.smask;
}
/**
* Setter for property smask.
*
* @param smask
* New value of property smask.
*/
public void setSmask(final boolean smask) {
this.smask = smask;
}
/** this is the transparency information of the raw image */
protected int transparency[];
/**
* Returns the transparency.
*
* @return the transparency values
*/
public int[] getTransparency() {
return transparency;
}
/**
* Sets the transparency values
*
* @param transparency
* the transparency values
*/
public void setTransparency(final int transparency[]) {
this.transparency = transparency;
}
/**
* Returns the compression level used for images written as a compressed stream.
* @return the compression level (0 = best speed, 9 = best compression, -1 is default)
* @since 2.1.3
*/
public int getCompressionLevel() {
return compressionLevel;
}
/**
* Sets the compression level to be used if the image is written as a compressed stream.
* @param compressionLevel a value between 0 (best speed) and 9 (best compression)
* @since 2.1.3
*/
public void setCompressionLevel(final int compressionLevel) {
if (compressionLevel < PdfStream.NO_COMPRESSION || compressionLevel > PdfStream.BEST_COMPRESSION)
this.compressionLevel = PdfStream.DEFAULT_COMPRESSION;
else
this.compressionLevel = compressionLevel;
}
}