/* * Portions Copyright (c) 2005 Sun Microsystems, Inc. All Rights Reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * - Redistribution of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * - Redistribution 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 Sun Microsystems, Inc. or the names of * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * This software is provided "AS IS," without a warranty of any kind. ALL * EXPRESS OR IMPLIED CONDITIONS, REPRESENTATIONS AND WARRANTIES, * INCLUDING ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A * PARTICULAR PURPOSE OR NON-INFRINGEMENT, ARE HEREBY EXCLUDED. SUN * MICROSYSTEMS, INC. ("SUN") AND ITS LICENSORS SHALL NOT BE LIABLE FOR * ANY DAMAGES SUFFERED BY LICENSEE AS A RESULT OF USING, MODIFYING OR * DISTRIBUTING THIS SOFTWARE OR ITS DERIVATIVES. IN NO EVENT WILL SUN OR * ITS LICENSORS BE LIABLE FOR ANY LOST REVENUE, PROFIT OR DATA, OR FOR * DIRECT, INDIRECT, SPECIAL, CONSEQUENTIAL, INCIDENTAL OR PUNITIVE * DAMAGES, HOWEVER CAUSED AND REGARDLESS OF THE THEORY OF LIABILITY, * ARISING OUT OF THE USE OF OR INABILITY TO USE THIS SOFTWARE, EVEN IF * SUN HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. * * You acknowledge that this software is not designed or intended for use * in the design, construction, operation or maintenance of any nuclear * facility. * * Sun gratefully acknowledges that this software was originally authored * and developed by Kenneth Bradley Russell and Christopher John Kline. */ package com.sun.opengl.util.texture.spi; import java.io.*; import javax.media.opengl.*; import com.sun.opengl.util.*; // Test harness import java.awt.image.*; import javax.swing.*; /**

Reads and writes SGI RGB/RGBA images.

Written from Paul Bourke's adaptation of the SGI specification.

*/ public class SGIImage { private Header header; private int format; private byte[] data; // Used for decoding RLE-compressed images private int[] rowStart; private int[] rowSize; private int rleEnd; private byte[] tmpData; private byte[] tmpRead; private static final int MAGIC = 474; static class Header { short magic; // IRIS image file magic number // This should be decimal 474 byte storage; // Storage format // 0 for uncompressed // 1 for RLE compression byte bpc; // Number of bytes per pixel channel // Legally 1 or 2 short dimension; // Number of dimensions // Legally 1, 2, or 3 // 1 means a single row, XSIZE long // 2 means a single 2D image // 3 means multiple 2D images short xsize; // X size in pixels short ysize; // Y size in pixels short zsize; // Number of channels // 1 indicates greyscale // 3 indicates RGB // 4 indicates RGB and Alpha int pixmin; // Minimum pixel value // This is the lowest pixel value in the image int pixmax; // Maximum pixel value // This is the highest pixel value in the image int dummy; // Ignored // Normally set to 0 String imagename; // Image name; 80 bytes long // Must be null terminated, therefore at most 79 bytes int colormap; // Colormap ID // 0 - normal mode // 1 - dithered, 3 mits for red and green, 2 for blue, obsolete // 2 - index colour, obsolete // 3 - not an image but a colourmap // 404 bytes char DUMMY Ignored // Should be set to 0, makes the header 512 bytes. Header() { magic = MAGIC; } Header(DataInputStream in) throws IOException { magic = in.readShort(); storage = in.readByte(); bpc = in.readByte(); dimension = in.readShort(); xsize = in.readShort(); ysize = in.readShort(); zsize = in.readShort(); pixmin = in.readInt(); pixmax = in.readInt(); dummy = in.readInt(); byte[] tmpname = new byte[80]; in.read(tmpname); int numChars = 0; while (tmpname[numChars++] != 0); imagename = new String(tmpname, 0, numChars); colormap = in.readInt(); byte[] tmp = new byte[404]; in.read(tmp); } public String toString() { return ("magic: " + magic + " storage: " + (int) storage + " bpc: " + (int) bpc + " dimension: " + dimension + " xsize: " + xsize + " ysize: " + ysize + " zsize: " + zsize + " pixmin: " + pixmin + " pixmax: " + pixmax + " imagename: " + imagename + " colormap: " + colormap); } } private SGIImage(Header header) { this.header = header; } /** Reads an SGI image from the specified file. */ public static SGIImage read(String filename) throws IOException { return read(new FileInputStream(filename)); } /** Reads an SGI image from the specified InputStream. */ public static SGIImage read(InputStream in) throws IOException { DataInputStream dIn = new DataInputStream(new BufferedInputStream(in)); Header header = new Header(dIn); SGIImage res = new SGIImage(header); res.decodeImage(dIn); return res; } /** Writes this SGIImage to the specified file name. If flipVertically is set, outputs the scanlines from top to bottom rather than the default bottom to top order. */ public void write(String filename, boolean flipVertically) throws IOException { write(new File(filename), flipVertically); } /** Writes this SGIImage to the specified file. If flipVertically is set, outputs the scanlines from top to bottom rather than the default bottom to top order. */ public void write(File file, boolean flipVertically) throws IOException { writeImage(file, data, header.xsize, header.ysize, header.zsize, flipVertically); } /** Creates an SGIImage from the specified data in either RGB or RGBA format. */ public static SGIImage createFromData(int width, int height, boolean hasAlpha, byte[] data) { Header header = new Header(); header.xsize = (short) width; header.ysize = (short) height; header.zsize = (short) (hasAlpha ? 4 : 3); SGIImage image = new SGIImage(header); image.data = data; return image; } /** Determines from the magic number whether the given InputStream points to an SGI RGB image. The given InputStream must return true from markSupported() and support a minimum of two bytes of read-ahead. */ public static boolean isSGIImage(InputStream in) throws IOException { if (!(in instanceof BufferedInputStream)) { in = new BufferedInputStream(in); } if (!in.markSupported()) { throw new IOException("Can not test non-destructively whether given InputStream is an SGI RGB image"); } DataInputStream dIn = new DataInputStream(in); dIn.mark(4); short magic = dIn.readShort(); dIn.reset(); return (magic == MAGIC); } /** Returns the width of the image. */ public int getWidth() { return header.xsize; } /** Returns the height of the image. */ public int getHeight() { return header.ysize; } /** Returns the OpenGL format for this texture; e.g. GL.GL_RGB or GL.GL_RGBA. */ public int getFormat() { return format; } /** Returns the raw data for this texture in the correct (bottom-to-top) order for calls to glTexImage2D. */ public byte[] getData() { return data; } public String toString() { return header.toString(); } //---------------------------------------------------------------------- // Internals only below this point // private void decodeImage(DataInputStream in) throws IOException { if (header.storage == 1) { // Read RLE compression data; row starts and sizes int x = header.ysize * header.zsize; rowStart = new int[x]; rowSize = new int[x]; rleEnd = 4 * 2 * x + 512; for (int i = 0; i < x; i++) { rowStart[i] = in.readInt(); } for (int i = 0; i < x; i++) { rowSize[i] = in.readInt(); } tmpRead = new byte[header.xsize * 256]; } tmpData = readAll(in); int xsize = header.xsize; int ysize = header.ysize; int zsize = header.zsize; int lptr = 0; data = new byte[xsize * ysize * 4]; byte[] rbuf = new byte[xsize]; byte[] gbuf = new byte[xsize]; byte[] bbuf = new byte[xsize]; byte[] abuf = new byte[xsize]; for (int y = 0; y < ysize; y++) { if (zsize >= 4) { getRow(rbuf, y, 0); getRow(gbuf, y, 1); getRow(bbuf, y, 2); getRow(abuf, y, 3); rgbatorgba(rbuf, gbuf, bbuf, abuf, data, lptr); } else if (zsize == 3) { getRow(rbuf, y, 0); getRow(gbuf, y, 1); getRow(bbuf, y, 2); rgbtorgba(rbuf, gbuf, bbuf, data, lptr); } else if (zsize == 2) { getRow(rbuf, y, 0); getRow(abuf, y, 1); latorgba(rbuf, abuf, data, lptr); } else { getRow(rbuf, y, 0); bwtorgba(rbuf, data, lptr); } lptr += 4 * xsize; } rowStart = null; rowSize = null; tmpData = null; tmpRead = null; format = GL.GL_RGBA; header.zsize = 4; } private void getRow(byte[] buf, int y, int z) { if (header.storage == 1) { int offs = rowStart[y + z * header.ysize] - rleEnd; System.arraycopy(tmpData, offs, tmpRead, 0, rowSize[y + z * header.ysize]); int iPtr = 0; int oPtr = 0; for (;;) { byte pixel = tmpRead[iPtr++]; int count = (int) (pixel & 0x7F); if (count == 0) { return; } if ((pixel & 0x80) != 0) { while ((count--) > 0) { buf[oPtr++] = tmpRead[iPtr++]; } } else { pixel = tmpRead[iPtr++]; while ((count--) > 0) { buf[oPtr++] = pixel; } } } } else { int offs = (y * header.xsize) + (z * header.xsize * header.ysize); System.arraycopy(tmpData, offs, buf, 0, header.xsize); } } private void bwtorgba(byte[] b, byte[] dest, int lptr) { for (int i = 0; i < b.length; i++) { dest[4 * i + lptr + 0] = b[i]; dest[4 * i + lptr + 1] = b[i]; dest[4 * i + lptr + 2] = b[i]; dest[4 * i + lptr + 3] = (byte) 0xFF; } } private void latorgba(byte[] b, byte[] a, byte[] dest, int lptr) { for (int i = 0; i < b.length; i++) { dest[4 * i + lptr + 0] = b[i]; dest[4 * i + lptr + 1] = b[i]; dest[4 * i + lptr + 2] = b[i]; dest[4 * i + lptr + 3] = a[i]; } } private void rgbtorgba(byte[] r, byte[] g, byte[] b, byte[] dest, int lptr) { for (int i = 0; i < b.length; i++) { dest[4 * i + lptr + 0] = r[i]; dest[4 * i + lptr + 1] = g[i]; dest[4 * i + lptr + 2] = b[i]; dest[4 * i + lptr + 3] = (byte) 0xFF; } } private void rgbatorgba(byte[] r, byte[] g, byte[] b, byte[] a, byte[] dest, int lptr) { for (int i = 0; i < b.length; i++) { dest[4 * i + lptr + 0] = r[i]; dest[4 * i + lptr + 1] = g[i]; dest[4 * i + lptr + 2] = b[i]; dest[4 * i + lptr + 3] = a[i]; } } private static byte imgref(byte[] i, int x, int y, int z, int xs, int ys, int zs) { return i[(xs*ys*z)+(xs*y)+x]; } private void writeHeader(DataOutputStream stream, int xsize, int ysize, int zsize, boolean rle) throws IOException { // effects: outputs the 512-byte IRIS RGB header to STREAM, using xsize, // ysize, and depth as the dimensions of the image. NOTE that // the following defaults are used: // STORAGE = 1 (storage format = RLE) // BPC = 1 (# bytes/channel) // DIMENSION = 3 // PIXMIN = 0 // PIXMAX = 255 // IMAGENAME = <80 nulls> // COLORMAP = 0 // See ftp://ftp.sgi.com/pub/sgi/SGIIMAGESPEC for more details. // write out MAGIC, STORAGE, BPC stream.writeShort(474); stream.write((rle ? 1 : 0)); stream.write(1); // write out DIMENSION stream.writeShort(3); // write XSIZE, YSIZE, ZSIZE stream.writeShort(xsize); stream.writeShort(ysize); stream.writeShort(zsize); // write PIXMIN, PIXMAX stream.writeInt(0); stream.writeInt(255); // write DUMMY stream.writeInt(0); // write IMAGENAME for (int i = 0; i < 80; i++) stream.write(0); // write COLORMAP stream.writeInt(0); // write DUMMY (404 bytes) for (int i = 0; i < 404; i++) stream.write(0); } private void writeImage(File file, byte[] data, int xsize, int ysize, int zsize, boolean yflip) throws IOException { // Input data is in RGBRGBRGB or RGBARGBARGBA format; first unswizzle it byte[] tmpData = new byte[xsize * ysize * zsize]; int dest = 0; for (int i = 0; i < zsize; i++) { for (int j = i; j < (xsize * ysize * zsize); j += zsize) { tmpData[dest++] = data[j]; } } data = tmpData; // requires: DATA must be an array of size XSIZE * YSIZE * ZSIZE, // indexed in the following manner: // data[0] ...data[xsize-1] == first row of first channel // data[xsize]...data[2*xsize-1] == second row of first channel // ... data[(ysize - 1) * xsize]...data[(ysize * xsize) - 1] == // last row of first channel // Later channels follow the same format. // *** NOTE that "first row" is defined by the BOTTOM ROW of // the image. That is, the origin is in the lower left corner. // effects: writes out an SGI image to FILE, RLE-compressed, INCLUDING // header, of dimensions (xsize, ysize, zsize), and containing // the data in DATA. If YFLIP is set, outputs the data in DATA // in reverse order vertically (equivalent to a flip about the // x axis). // Build the offset tables int[] starttab = new int[ysize * zsize]; int[] lengthtab = new int[ysize * zsize]; // Temporary buffer for holding RLE data. // Note that this makes the assumption that RLE-compressed data will // never exceed twice the size of the input data. // There are surely formal proofs about how big the RLE buffer should // be, as well as what the optimal look-ahead size is (i.e. don't switch // copy/repeat modes for less than N repeats). However, I'm going from // empirical evidence here; the break-even point seems to be a look- // ahead of 3. (That is, if the three values following this one are all // the same as the current value, switch to repeat mode.) int lookahead = 3; byte[] rlebuf = new byte[2 * xsize * ysize * zsize]; int cur_loc = 0; // current offset location. int ptr = 0; int total_size = 0; int ystart = 0; int yincr = 1; int yend = ysize; if (yflip) { ystart = ysize - 1; yend = -1; yincr = -1; } boolean DEBUG = false; for (int z = 0; z < zsize; z++) { for (int y = ystart; y != yend; y += yincr) { // RLE-compress each row. int x = 0; byte count = 0; boolean repeat_mode = false; boolean should_switch = false; int start_ptr = ptr; int num_ptr = ptr++; byte repeat_val = 0; while (x < xsize) { // see if we should switch modes should_switch = false; if (repeat_mode) { if (imgref(data, x, y, z, xsize, ysize, zsize) != repeat_val) { should_switch = true; } } else { // look ahead to see if we should switch to repeat mode. // stay within the scanline for the lookahead if ((x + lookahead) < xsize) { should_switch = true; for (int i = 1; i <= lookahead; i++) { if (DEBUG) System.err.println("left side was " + ((int) imgref(data, x, y, z, xsize, ysize, zsize)) + ", right side was " + (int)imgref(data, x+i, y, z, xsize, ysize, zsize)); if (imgref(data, x, y, z, xsize, ysize, zsize) != imgref(data, x+i, y, z, xsize, ysize, zsize)) should_switch = false; } } } if (should_switch || (count == 127)) { // update the number of elements we repeated/copied if (x > 0) { if (repeat_mode) rlebuf[num_ptr] = count; else rlebuf[num_ptr] = (byte) (count | 0x80); } // perform mode switch if necessary; output repeat_val if // switching FROM repeat mode, and set it if switching // TO repeat mode. if (repeat_mode) { if (should_switch) repeat_mode = false; rlebuf[ptr++] = repeat_val; } else { if (should_switch) repeat_mode = true; repeat_val = imgref(data, x, y, z, xsize, ysize, zsize); } if (x > 0) { // reset the number pointer num_ptr = ptr++; // reset number of bytes copied count = 0; } } // if not in repeat mode, copy element to ptr if (!repeat_mode) { rlebuf[ptr++] = imgref(data, x, y, z, xsize, ysize, zsize); } count++; if (x == xsize - 1) { // Need to store the number of pixels we copied/repeated. if (repeat_mode) { rlebuf[num_ptr] = count; // If we ended the row in repeat mode, store the // repeated value rlebuf[ptr++] = repeat_val; } else rlebuf[num_ptr] = (byte) (count | 0x80); // output zero counter for the last value in the row rlebuf[ptr++] = 0; } x++; } // output this row's length into the length table int rowlen = ptr - start_ptr; if (yflip) lengthtab[ysize*z+(ysize-y-1)] = rowlen; else lengthtab[ysize*z+y] = rowlen; // add to the start table, and update the current offset if (yflip) starttab[ysize*z+(ysize-y-1)] = cur_loc; else starttab[ysize*z+y] = cur_loc; cur_loc += rowlen; } } // Now we have the offset tables computed, as well as the RLE data. // Output this information to the file. total_size = ptr; if (DEBUG) System.err.println("total_size was " + total_size); DataOutputStream stream = new DataOutputStream(new BufferedOutputStream(new FileOutputStream(file))); writeHeader(stream, xsize, ysize, zsize, true); int SIZEOF_INT = 4; for (int i = 0; i < (ysize * zsize); i++) stream.writeInt(starttab[i] + 512 + (2 * ysize * zsize * SIZEOF_INT)); for (int i = 0; i < (ysize * zsize); i++) stream.writeInt(lengthtab[i]); for (int i = 0; i < total_size; i++) stream.write(rlebuf[i]); stream.close(); } private byte[] readAll(DataInputStream in) throws IOException { byte[] dest = new byte[16384]; int pos = 0; int numRead = 0; boolean done = false; do { numRead = in.read(dest, pos, dest.length - pos); if (pos == dest.length) { // Resize destination buffer byte[] newDest = new byte[2 * dest.length]; System.arraycopy(dest, 0, newDest, 0, pos); dest = newDest; } if (numRead > 0) { pos += numRead; } done = ((numRead == -1) || (in.available() == 0)); } while (!done); // Trim destination buffer if (pos != dest.length) { byte[] finalDest = new byte[pos]; System.arraycopy(dest, 0, finalDest, 0, pos); dest = finalDest; } return dest; } // Test case /* public static void main(String[] args) { for (int i = 0; i < args.length; i++) { try { System.out.println(args[i] + ":"); SGIImage image = SGIImage.read(args[i]); System.out.println(image); BufferedImage img = new BufferedImage(image.getWidth(), image.getHeight(), BufferedImage.TYPE_4BYTE_ABGR); WritableRaster raster = img.getRaster(); DataBufferByte db = (DataBufferByte) raster.getDataBuffer(); byte[] src = image.getData(); byte[] dest = db.getData(); for (int j = 0; j < src.length; j += 4) { dest[j + 0] = src[j + 3]; dest[j + 1] = src[j + 2]; dest[j + 2] = src[j + 1]; dest[j + 3] = src[j + 0]; } // System.arraycopy(src, 0, dest, 0, src.length); ImageIcon icon = new ImageIcon(img); JLabel label = new JLabel(); label.setIcon(icon); JFrame frame = new JFrame(args[i]); frame.getContentPane().add(label); frame.pack(); frame.show(); } catch (IOException e) { e.printStackTrace(); } } } */ }