/******************************************************************************* * Copyright (c) 2000, 2005 IBM Corporation and others. * All rights reserved. This program and the accompanying materials * are made available under the terms of the Eclipse Public License v1.0 * which accompanies this distribution, and is available at * http://www.eclipse.org/legal/epl-v10.html * * Contributors: * IBM Corporation - initial API and implementation *******************************************************************************/ package org.eclipse.swt.tools.internal; import java.io.*; import java.util.Vector; /** * Customize the icon of a Windows exe * * WARNING! This class is not part of SWT API. It is NOT API. It is an internal * tool that may be changed or removed at anytime. * * Based on MSDN "An In-Depth Look into the Win32 Portable Executable File Format" */ public class IconExe { /** * Replace the Desktop icons provided in the Windows executable program * with matching icons provided by the user. * * Takes 2 arguments * argument 0: the Windows executable e.g c:/eclipse/eclipse.exe * argument 1: The .ico file to write to the given executable e.g. c:/myApp.ico * * Note 1. Write access to the executable program is required. As a result, that * program must not be currently running or edited elsewhere. * * Note 2. The Eclipse 3.1 launcher requires a .ico file with the following 6 images * 1. 32x32, 4 bit (Windows 16 colors palette) * 2. 16x16, 4 bit (Windows 16 colors palette) * 3. 16x16, 8 bit (256 colors) * 4. 32x32, 8 bit (256 colors) * 5. 48x48, 4 bit (Windows 16 colors palette) * 6. 48x48, 8 bit (256 colors) * A user icon matching exactly the width/height/depth of an executable icon will be written * to the executable and will replace that executable icon. If an executable icon * does not match a user icon, it is silently left as is. * * Note 3. This function modifies the content of the executable program and may cause * its corruption. */ public static void main(String[] args) { if (args.length < 2) { System.err.println("Usage: IconExe <windows executable> <ico file>"); return; } ImageLoader loader = new ImageLoader(); try { ImageData[] data = null; if (args.length == 2) { /* ICO case */ data = loader.load(args[1]); } else { /* BMP case - each following argument is a single BMP file * BMP is handled for testing purpose only. The ICO file is the * official Microsoft format for image resources. */ data = new ImageData[args.length - 1]; for (int i = 1; i < args.length; i++) { ImageData[] current = loader.load(args[i]); data[i - 1] = current[0]; } } int nMissing = unloadIcons(args[0], data); if (nMissing != 0) System.err.println("Error - "+nMissing+" icon(s) not replaced in "+args[0]+" using "+args[1]); } catch (Exception e) { e.printStackTrace(); } } /* Implementation */ /** * Retrieve the Desktop icons provided in the Windows executable program. * These icons are typically shown in various places of the Windows desktop. * * Note. The Eclipse 3.1 launcher returns the following 6 images * 1. 32x32, 4 bit (Windows 16 colors palette) * 2. 16x16, 4 bit (Windows 16 colors palette) * 3. 16x16, 8 bit (256 colors) * 4. 32x32, 8 bit (256 colors) * 5. 48x48, 4 bit (Windows 16 colors palette) * 6. 48x48, 8 bit (256 colors) * * @param program the Windows executable e.g c:/eclipse/eclipse.exe */ static ImageData[] loadIcons(String program) throws FileNotFoundException, IOException { RandomAccessFile raf = new RandomAccessFile(program, "r"); IconExe iconExe = new IconExe(); IconResInfo[] iconInfo = iconExe.getIcons(raf); ImageData[] data = new ImageData[iconInfo.length]; for (int i = 0; i < data.length; i++) data[i] = iconInfo[i].data; raf.close(); return data; } /** * Replace the Desktop icons provided in the Windows executable program * with icons provided by the user. * * Note 1. Write access to the executable program is required. As a result, that * program must not be currently running or edited elsewhere. * * Note 2. Use loadIcons to determine which set of icons (width, height, depth) * is required to replace the icons in the executable program. A user icon * matching exactly the width/height/depth of an executable icon will be written * to the executable and will replace that executable icon. If an executable icon * does not match a user icon, it is left as is. Verify the return value matches * the number of icons to write. Finally, use loadIcons after this operation * to verify the icons have changed as expected. * * Note 3. The Eclipse 3.1 launcher requires the following 6 images (in any order). * 1. 32x32, 4 bit (Windows 16 colors palette) * 2. 16x16, 4 bit (Windows 16 colors palette) * 3. 16x16, 8 bit (256 colors) * 4. 32x32, 8 bit (256 colors) * 5. 48x48, 4 bit (Windows 16 colors palette) * 6. 48x48, 8 bit (256 colors) * * Note 4. This function modifies the content of the executable program and may cause * its corruption. * * @param program the Windows executable e.g c:/eclipse/eclipse.exe * @param icons to write to the given executable * @return the number of icons from the original program that were not successfully replaced (0 if success) */ static int unloadIcons(String program, ImageData[] icons) throws FileNotFoundException, IOException { RandomAccessFile raf = new RandomAccessFile(program, "rw"); IconExe iconExe = new IconExe(); IconResInfo[] iconInfo = iconExe.getIcons(raf); int cnt = 0; for (int i = 0; i < iconInfo.length; i++) { for (int j = 0; j < icons.length; j++) if (iconInfo[i].data.width == icons[j].width && iconInfo[i].data.height == icons[j].height && iconInfo[i].data.depth == icons[j].depth) { raf.seek(iconInfo[i].offset); unloadIcon(raf, icons[j]); cnt++; } } raf.close(); return iconInfo.length - cnt; } public static final String VERSION = "20050124"; static final boolean DEBUG = false; public static class IconResInfo { ImageData data; int offset; int size; } IconResInfo[] iconInfo = null; int iconCnt; IconResInfo[] getIcons(RandomAccessFile raf) throws IOException { iconInfo = new IconResInfo[4]; iconCnt = 0; IMAGE_DOS_HEADER imageDosHeader = new IMAGE_DOS_HEADER(); read(raf, imageDosHeader); if (imageDosHeader.e_magic != IMAGE_DOS_SIGNATURE) return null; int imageNtHeadersOffset = imageDosHeader.e_lfanew; raf.seek(imageNtHeadersOffset); IMAGE_NT_HEADERS imageNtHeaders = new IMAGE_NT_HEADERS(); read(raf, imageNtHeaders); if (imageNtHeaders.Signature != IMAGE_NT_SIGNATURE) return null; // DumpResources int resourcesRVA = imageNtHeaders.OptionalHeader.DataDirectory[IMAGE_DIRECTORY_ENTRY_RESOURCE].VirtualAddress; if (resourcesRVA == 0) return null; if (DEBUG) System.out.println("* Resources (RVA= "+resourcesRVA+")"); IMAGE_SECTION_HEADER imageSectionHeader = new IMAGE_SECTION_HEADER(); int firstSectionOffset = imageNtHeadersOffset + IMAGE_NT_HEADERS.FIELD_OFFSET_OptionalHeader + imageNtHeaders.FileHeader.SizeOfOptionalHeader; raf.seek(firstSectionOffset); boolean found = false; for (int i = 0; i < imageNtHeaders.FileHeader.NumberOfSections; i++) { read(raf, imageSectionHeader); if (resourcesRVA >= imageSectionHeader.VirtualAddress && resourcesRVA < imageSectionHeader.VirtualAddress + imageSectionHeader.Misc_VirtualSize) { // could check the imageSectionHeader name is .rsrc found = true; break; } } if (!found) return null; int delta = imageSectionHeader.VirtualAddress - imageSectionHeader.PointerToRawData; int imageResourceDirectoryOffset = resourcesRVA - delta; dumpResourceDirectory(raf, imageResourceDirectoryOffset, imageResourceDirectoryOffset, delta, 0, 0, false); if (iconCnt < iconInfo.length) { IconResInfo[] newArray = new IconResInfo[iconCnt]; System.arraycopy(iconInfo, 0, newArray, 0, iconCnt); iconInfo = newArray; } return iconInfo; } void dumpResourceDirectory(RandomAccessFile raf, int imageResourceDirectoryOffset, int resourceBase, int delta, int type, int level, boolean rt_icon_root) throws IOException { if (DEBUG) System.out.println("** LEVEL "+level); IMAGE_RESOURCE_DIRECTORY imageResourceDirectory = new IMAGE_RESOURCE_DIRECTORY(); raf.seek(imageResourceDirectoryOffset); read(raf, imageResourceDirectory); if (DEBUG) { String sType = ""+type; // level 1 resources are resource types if (level == 1) { System.out.println("___________________________"); if (type == RT_ICON) sType = "RT_ICON"; if (type == RT_GROUP_ICON) sType = "RT_GROUP_ICON"; } System.out.println("Resource Directory ["+sType+"]"+" (Named "+imageResourceDirectory.NumberOfNamedEntries+", ID "+imageResourceDirectory.NumberOfIdEntries+")"); } // int IRDE_StartOffset = imageResourceDirectoryOffset + IMAGE_RESOURCE_DIRECTORY.SIZEOF; IMAGE_RESOURCE_DIRECTORY_ENTRY[] imageResourceDirectoryEntries = new IMAGE_RESOURCE_DIRECTORY_ENTRY[imageResourceDirectory.NumberOfIdEntries]; for (int i = 0; i < imageResourceDirectoryEntries.length; i++) { imageResourceDirectoryEntries[i] = new IMAGE_RESOURCE_DIRECTORY_ENTRY(); read(raf, imageResourceDirectoryEntries[i]); } for (int i = 0; i < imageResourceDirectoryEntries.length; i++) { if (imageResourceDirectoryEntries[i].DataIsDirectory) { dumpResourceDirectory(raf, imageResourceDirectoryEntries[i].OffsetToDirectory + resourceBase, resourceBase, delta, imageResourceDirectoryEntries[i].Id, level + 1, rt_icon_root ? true : type == RT_ICON); } else { // Resource found /// pResDirEntry->Name IMAGE_RESOURCE_DIRECTORY_ENTRY irde = imageResourceDirectoryEntries[i]; IMAGE_RESOURCE_DATA_ENTRY data = new IMAGE_RESOURCE_DATA_ENTRY(); raf.seek(imageResourceDirectoryEntries[i].OffsetToData + resourceBase); read(raf, data); if (DEBUG) System.out.println("Resource Id "+irde.Id+" Data Offset RVA "+data.OffsetToData+", Size "+data.Size); if (rt_icon_root) { if (DEBUG) System.out.println("iconcnt "+iconCnt+" |"+iconInfo.length); iconInfo[iconCnt] = new IconResInfo(); iconInfo[iconCnt].data = parseIcon(raf, data.OffsetToData - delta, data.Size); iconInfo[iconCnt].offset = data.OffsetToData - delta; iconInfo[iconCnt].size = data.Size; iconCnt++; if (iconCnt == iconInfo.length) { IconResInfo[] newArray = new IconResInfo[iconInfo.length + 4]; System.arraycopy(iconInfo, 0, newArray, 0, iconInfo.length); iconInfo = newArray; } } } } } static ImageData parseIcon(RandomAccessFile raf, int offset, int size) throws IOException { raf.seek(offset); BITMAPINFO bitmapInfo = new BITMAPINFO(); read(raf, bitmapInfo); bitmapInfo.bmiHeader.biHeight /= 2; int width = bitmapInfo.bmiHeader.biWidth; int height = bitmapInfo.bmiHeader.biHeight; int depth = bitmapInfo.bmiHeader.biBitCount; PaletteData palette = loadPalette(bitmapInfo.bmiHeader, raf); byte[] shapeData = loadData(bitmapInfo.bmiHeader, raf); bitmapInfo.bmiHeader.biBitCount = 1; byte[] maskData = loadData(bitmapInfo.bmiHeader, raf); maskData = convertPad(maskData, width, height, 1, 4, 2); bitInvertData(maskData, 0, maskData.length); return ImageData.internal_new( width, height, depth, palette, 4, shapeData, 2, maskData, null, -1, -1, SWT.IMAGE_ICO, 0, 0, 0, 0); } static byte[] bitInvertData(byte[] data, int startIndex, int endIndex) { // Destructively bit invert data in the given byte array. for (int i = startIndex; i < endIndex; i++) { data[i] = (byte)(255 - data[i - startIndex]); } return data; } static final byte[] convertPad(byte[] data, int width, int height, int depth, int pad, int newPad) { if (pad == newPad) return data; int stride = (width * depth + 7) / 8; int bpl = (stride + (pad - 1)) / pad * pad; int newBpl = (stride + (newPad - 1)) / newPad * newPad; byte[] newData = new byte[height * newBpl]; int srcIndex = 0, destIndex = 0; for (int y = 0; y < height; y++) { System.arraycopy(data, srcIndex, newData, destIndex, newBpl); srcIndex += bpl; destIndex += newBpl; } return newData; } static PaletteData loadPalette(BITMAPINFOHEADER bih, RandomAccessFile raf) throws IOException { int depth = bih.biBitCount; if (depth <= 8) { int numColors = bih.biClrUsed; if (numColors == 0) { numColors = 1 << depth; } else { if (numColors > 256) numColors = 256; } byte[] buf = new byte[numColors * 4]; raf.read(buf); return paletteFromBytes(buf, numColors); } if (depth == 16) return new PaletteData(0x7C00, 0x3E0, 0x1F); if (depth == 24) return new PaletteData(0xFF, 0xFF00, 0xFF0000); return new PaletteData(0xFF00, 0xFF0000, 0xFF000000); } static PaletteData paletteFromBytes(byte[] bytes, int numColors) { int bytesOffset = 0; RGB[] colors = new RGB[numColors]; for (int i = 0; i < numColors; i++) { colors[i] = new RGB(bytes[bytesOffset + 2] & 0xFF, bytes[bytesOffset + 1] & 0xFF, bytes[bytesOffset] & 0xFF); bytesOffset += 4; } return new PaletteData(colors); } static byte[] loadData(BITMAPINFOHEADER bih, RandomAccessFile raf) throws IOException { int stride = (bih.biWidth * bih.biBitCount + 7) / 8; stride = (stride + 3) / 4 * 4; // Round up to 4 byte multiple byte[] data = loadData(bih, raf, stride); flipScanLines(data, stride, bih.biHeight); return data; } static void flipScanLines(byte[] data, int stride, int height) { int i1 = 0; int i2 = (height - 1) * stride; for (int i = 0; i < height / 2; i++) { for (int index = 0; index < stride; index++) { byte b = data[index + i1]; data[index + i1] = data[index + i2]; data[index + i2] = b; } i1 += stride; i2 -= stride; } } static byte[] loadData(BITMAPINFOHEADER bih, RandomAccessFile raf, int stride) throws IOException { int dataSize = bih.biHeight * stride; byte[] data = new byte[dataSize]; int cmp = bih.biCompression; if (cmp == 0) { // BMP_NO_COMPRESSION raf.read(data); } else { if (DEBUG) System.out.println("ICO cannot be compressed?"); } return data; } static void unloadIcon(RandomAccessFile raf, ImageData icon) throws IOException { int sizeImage = (((icon.width * icon.depth + 31) / 32 * 4) + ((icon.width + 31) / 32 * 4)) * icon.height; write4(raf, BMPHeaderFixedSize); write4(raf, icon.width); write4(raf, icon.height * 2); writeU2(raf, 1); writeU2(raf, icon.depth); write4(raf, 0); write4(raf, sizeImage); write4(raf, 0); write4(raf, 0); write4(raf, icon.palette.colors != null ? icon.palette.colors.length : 0); write4(raf, 0); byte[] rgbs = paletteToBytes(icon.palette); raf.write(rgbs); unloadShapeData(raf, icon); unloadMaskData(raf, icon); } static byte[] paletteToBytes(PaletteData pal) { int n = pal.colors == null ? 0 : (pal.colors.length < 256 ? pal.colors.length : 256); byte[] bytes = new byte[n * 4]; int offset = 0; for (int i = 0; i < n; i++) { RGB col = pal.colors[i]; bytes[offset] = (byte)col.blue; bytes[offset + 1] = (byte)col.green; bytes[offset + 2] = (byte)col.red; offset += 4; } return bytes; } static void unloadMaskData(RandomAccessFile raf, ImageData icon) { ImageData mask = icon.getTransparencyMask(); int bpl = (icon.width + 7) / 8; int pad = mask.scanlinePad; int srcBpl = (bpl + pad - 1) / pad * pad; int destBpl = (bpl + 3) / 4 * 4; byte[] buf = new byte[destBpl]; int offset = (icon.height - 1) * srcBpl; byte[] data = mask.data; try { for (int i = 0; i < icon.height; i++) { System.arraycopy(data, offset, buf, 0, bpl); bitInvertData(buf, 0, bpl); raf.write(buf, 0, destBpl); offset -= srcBpl; } } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } } static void unloadShapeData(RandomAccessFile raf, ImageData icon) { int bpl = (icon.width * icon.depth + 7) / 8; int pad = icon.scanlinePad; int srcBpl = (bpl + pad - 1) / pad * pad; int destBpl = (bpl + 3) / 4 * 4; byte[] buf = new byte[destBpl]; int offset = (icon.height - 1) * srcBpl; byte[] data = icon.data; try { for (int i = 0; i < icon.height; i++) { System.arraycopy(data, offset, buf, 0, bpl); raf.write(buf, 0, destBpl); offset -= srcBpl; } } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } } static boolean readIconGroup(RandomAccessFile raf, int offset, int size) throws IOException { raf.seek(offset); NEWHEADER newHeader = new NEWHEADER(); read(raf, newHeader); if (newHeader.ResType != RES_ICON) return false; RESDIR[] resDir = new RESDIR[newHeader.ResCount]; for (int i = 0; i < newHeader.ResCount; i++) { resDir[i] = new RESDIR(); read(raf, resDir[i]); } return true; } static void copyFile(String src, String dst) throws FileNotFoundException, IOException { File srcFile = new File(src); File dstFile = new File(dst); FileInputStream in = new FileInputStream(srcFile); FileOutputStream out = new FileOutputStream(dstFile); int c; while ((c = in.read()) != -1) out.write(c); in.close(); out.close(); } /* IO utilities to parse Windows executable */ static final int IMAGE_DOS_SIGNATURE = 0x5a4d; static final int IMAGE_NT_SIGNATURE = 0x00004550; static final int IMAGE_DIRECTORY_ENTRY_RESOURCE = 2; static final int RES_ICON = 1; static final int RT_ICON = 3; static final int RT_GROUP_ICON = 14; static final int BMPHeaderFixedSize = 40; public static class IMAGE_DOS_HEADER { int e_magic; // WORD int e_cblp; // WORD int e_cp; // WORD int e_crlc; // WORD int e_cparhdr; // WORD int e_minalloc; // WORD int e_maxalloc; // WORD int e_ss; // WORD int e_sp; // WORD int e_csum; // WORD int e_ip; // WORD int e_cs; // WORD int e_lfarlc; // WORD int e_ovno; // WORD int[] e_res = new int[4]; // WORD[4] int e_oemid; // WORD int e_oeminfo; // WORD int[] e_res2 = new int[10]; // WORD[10] int e_lfanew; // LONG } public static class IMAGE_FILE_HEADER { int Machine; // WORD int NumberOfSections; // WORD int TimeDateStamp; // DWORD int PointerToSymbolTable; // DWORD int NumberOfSymbols; // DWORD int SizeOfOptionalHeader; // WORD int Characteristics; // WORD } public static class IMAGE_DATA_DIRECTORY { int VirtualAddress; // DWORD int Size; // DWORD } public static class IMAGE_OPTIONAL_HEADER { int Magic; // WORD int MajorLinkerVersion; // BYTE int MinorLinkerVersion; // BYTE int SizeOfCode; // DWORD int SizeOfInitializedData; // DWORD int SizeOfUninitializedData; // DWORD int AddressOfEntryPoint; // DWORD int BaseOfCode; // DWORD int BaseOfData; // DWORD int ImageBase; // DWORD int SectionAlignment; // DWORD int FileAlignment; // DWORD int MajorOperatingSystemVersion; // WORD int MinorOperatingSystemVersion; // WORD int MajorImageVersion; // WORD int MinorImageVersion; // WORD int MajorSubsystemVersion; // WORD int MinorSubsystemVersion; // WORD int Win32VersionValue; // DWORD int SizeOfImage; // DWORD int SizeOfHeaders; // DWORD int CheckSum; // DWORD int Subsystem; // WORD int DllCharacteristics; // WORD int SizeOfStackReserve; // DWORD int SizeOfStackCommit; // DWORD int SizeOfHeapReserve; // DWORD int SizeOfHeapCommit; // DWORD int LoaderFlags; // DWORD int NumberOfRvaAndSizes; // DWORD IMAGE_DATA_DIRECTORY[] DataDirectory = new IMAGE_DATA_DIRECTORY[16]; } public static class IMAGE_NT_HEADERS { int Signature; // DWORD IMAGE_FILE_HEADER FileHeader = new IMAGE_FILE_HEADER(); IMAGE_OPTIONAL_HEADER OptionalHeader = new IMAGE_OPTIONAL_HEADER(); final static int FIELD_OFFSET_OptionalHeader = 24; } public static class IMAGE_SECTION_HEADER { int[] Name = new int[8]; // BYTE[8] int Misc_VirtualSize; // DWORD (union Misc { DWORD PhysicalAddress; DWORD VirtualSize } int VirtualAddress; // DWORD int SizeOfRawData; // DWORD int PointerToRawData; // DWORD int PointerToRelocations; // DWORD int PointerToLinenumbers; // DWORD int NumberOfRelocations; // WORD int NumberOfLinenumbers; // WORD int Characteristics; // DWORD } public static class IMAGE_RESOURCE_DIRECTORY { int Characteristics; // DWORD int TimeDateStamp; // DWORD int MajorVersion; // WORD int MinorVersion; // WORD int NumberOfNamedEntries; // WORD - used int NumberOfIdEntries; // WORD - used final static int SIZEOF = 16; } public static class IMAGE_RESOURCE_DIRECTORY_ENTRY { // union int NameOffset; // DWORD 31 bits boolean NameIsString; // DWORD 1 bit int Name; // DWORD int Id; // WORD // union int OffsetToData; // DWORD int OffsetToDirectory; // DWORD 31 bits boolean DataIsDirectory; // DWORD 1 bit } public static class IMAGE_RESOURCE_DATA_ENTRY { int OffsetToData; // DWORD int Size; // DWORD int CodePage; // DWORD int Reserved; // DWORD } public static class NEWHEADER { int Reserved; // WORD int ResType; // WORD int ResCount; // WORD } public static class ICONRESDIR { int Width; // BYTE int Height; // BYTE int ColorCount; // BYTE int reserved; // BYTE } public static class CURSORDIR { int Width; // WORD int Height; // WORD } public static class RESDIR { // union ICONRESDIR Icon = new ICONRESDIR(); CURSORDIR Cursor = new CURSORDIR(); int Planes; // WORD int BitCount; // WORD int BytesInRes; // DWORD int IconCursorId; // WORD } public static class BITMAPINFOHEADER { int biSize; // DWORD int biWidth; // LONG int biHeight; // LONG int biPlanes; // WORD int biBitCount; // WORD int biCompression; // DWORD int biSizeImage; // DWORD int biXPelsPerMeter; // LONG int biYPelsPerMeter; // LONG int biClrUsed; // DWORD int biClrImportant; // DWORD } static class RGBQUAD { int rgBlue; // BYTE int rgbGreen; // BYTE int rgbRed; // BYTE int rgbReserved; // BYTE } static class BITMAPINFO { BITMAPINFOHEADER bmiHeader = new BITMAPINFOHEADER(); RGBQUAD[] bmiColors = null; } static void read(RandomAccessFile raf, BITMAPINFOHEADER bih) throws IOException { bih.biSize = read4(raf); bih.biWidth = read4(raf); bih.biHeight = read4(raf); bih.biPlanes = readU2(raf); bih.biBitCount = readU2(raf); bih.biCompression = read4(raf); bih.biSizeImage = read4(raf); bih.biXPelsPerMeter = read4(raf); bih.biYPelsPerMeter = read4(raf); bih.biClrUsed = read4(raf); bih.biClrImportant = read4(raf); } static void read(RandomAccessFile raf, BITMAPINFO bi) throws IOException { read(raf, bi.bmiHeader); } /* Little Endian helpers */ static int readU2(RandomAccessFile raf) throws IOException { int b0 = raf.readByte() & 0xFF; int b1 = raf.readByte() & 0xFF; return (b1 << 8 | b0); } static int read4(RandomAccessFile raf) throws IOException { int b0 = raf.readByte() & 0xFF; int b1 = raf.readByte() & 0xFF; int b2 = raf.readByte() & 0xFF; int b3 = raf.readByte() & 0xFF; return b3 << 24 | b2 << 16 | b1 << 8 | b0; } static void write4(RandomAccessFile raf, int value) throws IOException { raf.write(value & 0xFF); raf.write((value >> 8) & 0xFF); raf.write((value >> 16) & 0xFF); raf.write((value >> 24) & 0xFF); } static void writeU2(RandomAccessFile raf, int value) throws IOException { raf.write(value & 0xFF); raf.write((value >> 8) & 0xFF); } static void read(RandomAccessFile raf, IMAGE_DOS_HEADER idh) throws IOException { idh.e_magic = readU2(raf); idh.e_cblp = readU2(raf); idh.e_cp = readU2(raf); idh.e_crlc = readU2(raf); idh.e_cparhdr = readU2(raf); idh.e_minalloc = readU2(raf); idh.e_maxalloc = readU2(raf); idh.e_ss = readU2(raf); idh.e_sp = readU2(raf); idh.e_csum = readU2(raf); idh.e_ip = readU2(raf); idh.e_cs = readU2(raf); idh.e_lfarlc = readU2(raf); idh.e_ovno = readU2(raf); for (int i = 0; i < idh.e_res.length; i++) idh.e_res[i] = readU2(raf); idh.e_oemid = readU2(raf); idh.e_oeminfo = readU2(raf); for (int i = 0; i < idh.e_res2.length; i++) idh.e_res2[i] = readU2(raf); idh.e_lfanew = read4(raf); } static void read(RandomAccessFile raf, IMAGE_FILE_HEADER ifh) throws IOException { ifh.Machine = readU2(raf); ifh.NumberOfSections = readU2(raf); ifh.TimeDateStamp = read4(raf); ifh.PointerToSymbolTable = read4(raf); ifh.NumberOfSymbols = read4(raf); ifh.SizeOfOptionalHeader = readU2(raf); ifh.Characteristics = readU2(raf); } static void read(RandomAccessFile raf, IMAGE_DATA_DIRECTORY idd) throws IOException { idd.VirtualAddress = read4(raf); idd.Size = read4(raf); } static void read(RandomAccessFile raf, IMAGE_OPTIONAL_HEADER ioh) throws IOException { ioh.Magic = readU2(raf); ioh.MajorLinkerVersion = raf.read(); ioh.MinorLinkerVersion = raf.read(); ioh.SizeOfCode = read4(raf); ioh.SizeOfInitializedData = read4(raf); ioh.SizeOfUninitializedData = read4(raf); ioh.AddressOfEntryPoint = read4(raf); ioh.BaseOfCode = read4(raf); ioh.BaseOfData = read4(raf); ioh.ImageBase = read4(raf); ioh.SectionAlignment = read4(raf); ioh.FileAlignment = read4(raf); ioh.MajorOperatingSystemVersion = readU2(raf); ioh.MinorOperatingSystemVersion = readU2(raf); ioh.MajorImageVersion = readU2(raf); ioh.MinorImageVersion = readU2(raf); ioh.MajorSubsystemVersion = readU2(raf); ioh.MinorSubsystemVersion = readU2(raf); ioh.Win32VersionValue = read4(raf); ioh.SizeOfImage = read4(raf); ioh.SizeOfHeaders = read4(raf); ioh.CheckSum = read4(raf); ioh.Subsystem = readU2(raf); ioh.DllCharacteristics = readU2(raf); ioh.SizeOfStackReserve = read4(raf); ioh.SizeOfStackCommit = read4(raf); ioh.SizeOfHeapReserve = read4(raf); ioh.SizeOfHeapCommit = read4(raf); ioh.LoaderFlags = read4(raf); ioh.NumberOfRvaAndSizes = read4(raf); for (int i = 0 ; i < ioh.DataDirectory.length; i++) { ioh.DataDirectory[i] = new IMAGE_DATA_DIRECTORY(); read(raf, ioh.DataDirectory[i]); } } static void read(RandomAccessFile raf, IMAGE_NT_HEADERS inh) throws IOException { inh.Signature = read4(raf); read(raf, inh.FileHeader); read(raf, inh.OptionalHeader); } static void read(RandomAccessFile raf, IMAGE_SECTION_HEADER ish) throws IOException { for (int i = 0 ; i < ish.Name.length; i++) ish.Name[i] = raf.read(); ish.Misc_VirtualSize = read4(raf); ish.VirtualAddress = read4(raf); ish.SizeOfRawData = read4(raf); ish.PointerToRawData = read4(raf); ish.PointerToRelocations = read4(raf); ish.PointerToLinenumbers = read4(raf); ish.NumberOfRelocations = readU2(raf); ish.NumberOfLinenumbers = readU2(raf); ish.Characteristics = read4(raf); } static void read(RandomAccessFile raf, IMAGE_RESOURCE_DIRECTORY ird) throws IOException { ird.Characteristics = read4(raf); ird.TimeDateStamp = read4(raf); ird.MajorVersion = readU2(raf); ird.MinorVersion = readU2(raf); ird.NumberOfNamedEntries = readU2(raf); ird.NumberOfIdEntries = readU2(raf); } static void read(RandomAccessFile raf, IMAGE_RESOURCE_DIRECTORY_ENTRY irde) throws IOException { irde.Name = read4(raf); irde.OffsetToData = read4(raf); // construct other union members irde.NameOffset = irde.Name & ~ (1 << 31); irde.NameIsString = (irde.Name & (1 << 31)) != 0; irde.Id = irde.Name & 0xFFFF; irde.OffsetToDirectory = irde.OffsetToData & ~ (1 << 31); irde.DataIsDirectory = (irde.OffsetToData & (1 << 31)) != 0; } static void read(RandomAccessFile raf, IMAGE_RESOURCE_DATA_ENTRY irde) throws IOException { irde.OffsetToData = read4(raf); irde.Size = read4(raf); irde.CodePage = read4(raf); irde.Reserved = read4(raf); } static void read(RandomAccessFile raf, NEWHEADER nh) throws IOException { nh.Reserved = readU2(raf); nh.ResType = readU2(raf); nh.ResCount = readU2(raf); } static void read(RandomAccessFile raf, ICONRESDIR i) throws IOException { i.Width = raf.read(); i.Height = raf.read(); i.ColorCount = raf.read(); i.reserved = raf.read(); } static void read(RandomAccessFile raf, CURSORDIR c) throws IOException { c.Width = readU2(raf); c.Height = readU2(raf); } static void read(RandomAccessFile raf, RESDIR rs) throws IOException { long start = raf.getFilePointer(); read(raf, rs.Icon); raf.seek(start); read(raf, rs.Cursor); rs.Planes = readU2(raf); rs.BitCount = readU2(raf); rs.BytesInRes = read4(raf); rs.IconCursorId = readU2(raf); } /* ImageData and Image Decoder inlining to avoid dependency on SWT * The following section can be entirely removed if SWT can be used. */ static class RGB { /** * the red component of the RGB */ public int red; /** * the green component of the RGB */ public int green; /** * the blue component of the RGB */ public int blue; static final long serialVersionUID = 3258415023461249074L; /** * Constructs an instance of this class with the given * red, green and blue values. * * @param red the red component of the new instance * @param green the green component of the new instance * @param blue the blue component of the new instance * * @exception IllegalArgumentException <ul> * <li>ERROR_INVALID_ARGUMENT - if the red, green or blue argument is not between 0 and 255</li> * </ul> */ public RGB(int red, int green, int blue) { if ((red > 255) || (red < 0) || (green > 255) || (green < 0) || (blue > 255) || (blue < 0)) SWT.error(SWT.ERROR_INVALID_ARGUMENT); this.red = red; this.green = green; this.blue = blue; } /** * Compares the argument to the receiver, and returns true * if they represent the <em>same</em> object using a class * specific comparison. * * @param object the object to compare with this object * @return <code>true</code> if the object is the same as this object and <code>false</code> otherwise * * @see #hashCode() */ @Override public boolean equals (Object object) { if (object == this) return true; if (!(object instanceof RGB)) return false; RGB rgb = (RGB)object; return (rgb.red == this.red) && (rgb.green == this.green) && (rgb.blue == this.blue); } /** * Returns an integer hash code for the receiver. Any two * objects which return <code>true</code> when passed to * <code>equals</code> must return the same value for this * method. * * @return the receiver's hash * * @see #equals(Object) */ @Override public int hashCode () { return (blue << 16) | (green << 8) | red; } /** * Returns a string containing a concise, human-readable * description of the receiver. * * @return a string representation of the <code>RGB</code> */ @Override public String toString () { return "RGB {" + red + ", " + green + ", " + blue + "}"; //$NON-NLS-1$//$NON-NLS-2$ //$NON-NLS-3$ //$NON-NLS-4$ } } static class PaletteData { /** * true if the receiver is a direct palette, * and false otherwise */ public boolean isDirect; /** * the RGB values for an indexed palette, where the * indices of the array correspond to pixel values */ public RGB[] colors; /** * the red mask for a direct palette */ public int redMask; /** * the green mask for a direct palette */ public int greenMask; /** * the blue mask for a direct palette */ public int blueMask; /** * the red shift for a direct palette */ public int redShift; /** * the green shift for a direct palette */ public int greenShift; /** * the blue shift for a direct palette */ public int blueShift; /** * Constructs a new indexed palette given an array of RGB values. * * @param colors the array of <code>RGB</code>s for the palette * * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if the argument is null</li> * </ul> */ public PaletteData(RGB[] colors) { if (colors == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); this.colors = colors; this.isDirect = false; } /** * Constructs a new direct palette given the red, green and blue masks. * * @param redMask the red mask * @param greenMask the green mask * @param blueMask the blue mask */ public PaletteData(int redMask, int greenMask, int blueMask) { this.redMask = redMask; this.greenMask = greenMask; this.blueMask = blueMask; this.isDirect = true; this.redShift = shiftForMask(redMask); this.greenShift = shiftForMask(greenMask); this.blueShift = shiftForMask(blueMask); } /** * Returns the pixel value corresponding to the given <code>RBG</code>. * * @param rgb the RGB to get the pixel value for * @return the pixel value for the given RGB * * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if the argument is null</li> * <li>ERROR_INVALID_ARGUMENT - if the RGB is not found in the palette</li> * </ul> */ public int getPixel(RGB rgb) { if (rgb == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); if (isDirect) { int pixel = 0; pixel |= (redShift < 0 ? rgb.red << -redShift : rgb.red >>> redShift) & redMask; pixel |= (greenShift < 0 ? rgb.green << -greenShift : rgb.green >>> greenShift) & greenMask; pixel |= (blueShift < 0 ? rgb.blue << -blueShift : rgb.blue >>> blueShift) & blueMask; return pixel; } else { for (int i = 0; i < colors.length; i++) { if (colors[i].equals(rgb)) return i; } /* The RGB did not exist in the palette */ SWT.error(SWT.ERROR_INVALID_ARGUMENT); return 0; } } /** * Returns an <code>RGB</code> corresponding to the given pixel value. * * @param pixel the pixel to get the RGB value for * @return the RGB value for the given pixel * * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if the argument is null</li> * <li>ERROR_INVALID_ARGUMENT - if the pixel does not exist in the palette</li> * </ul> */ public RGB getRGB(int pixel) { if (isDirect) { int r = pixel & redMask; r = (redShift < 0) ? r >>> -redShift : r << redShift; int g = pixel & greenMask; g = (greenShift < 0) ? g >>> -greenShift : g << greenShift; int b = pixel & blueMask; b = (blueShift < 0) ? b >>> -blueShift : b << blueShift; return new RGB(r, g, b); } else { if (pixel < 0 || pixel >= colors.length) { SWT.error(SWT.ERROR_INVALID_ARGUMENT); } return colors[pixel]; } } /** * Returns all the RGB values in the receiver if it is an * indexed palette, or null if it is a direct palette. * * @return the <code>RGB</code>s for the receiver or null */ public RGB[] getRGBs() { return colors; } /** * Computes the shift value for a given mask. * * @param mask the mask to compute the shift for * @return the shift amount * * @see PaletteData */ int shiftForMask(int mask) { for (int i = 31; i >= 0; i--) { if (((mask >> i) & 0x1) != 0) return 7 - i; } return 32; } } static class ImageLoader { /** * the array of ImageData objects in this ImageLoader. * This array is read in when the load method is called, * and it is written out when the save method is called */ public ImageData[] data; /** * the width of the logical screen on which the images * reside, in pixels (this corresponds to the GIF89a * Logical Screen Width value) */ public int logicalScreenWidth; /** * the height of the logical screen on which the images * reside, in pixels (this corresponds to the GIF89a * Logical Screen Height value) */ public int logicalScreenHeight; /** * the background pixel for the logical screen (this * corresponds to the GIF89a Background Color Index value). * The default is -1 which means 'unspecified background' * */ public int backgroundPixel; /** * the number of times to repeat the display of a sequence * of animated images (this corresponds to the commonly-used * GIF application extension for "NETSCAPE 2.0 01") */ public int repeatCount; /* * the set of ImageLoader event listeners, created on demand */ Vector<?> imageLoaderListeners; /** * Construct a new empty ImageLoader. */ public ImageLoader() { reset(); } /** * Resets the fields of the ImageLoader, except for the * <code>imageLoaderListeners</code> field. */ void reset() { data = null; logicalScreenWidth = 0; logicalScreenHeight = 0; backgroundPixel = -1; repeatCount = 1; } /** * Loads an array of <code>ImageData</code> objects from the * specified input stream. Throws an error if either an error * occurs while loading the images, or if the images are not * of a supported type. Returns the loaded image data array. * * @param stream the input stream to load the images from * @return an array of <code>ImageData</code> objects loaded from the specified input stream * * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if the stream is null</li> * </ul> * @exception SWTException <ul> * <li>ERROR_INVALID_IMAGE - if the image file contains invalid data</li> * <li>ERROR_IO - if an input/output error occurs while reading data</li> * <li>ERROR_UNSUPPORTED_FORMAT - if the image file contains an unrecognized format</li> * </ul> */ public ImageData[] load(InputStream stream) { if (stream == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); reset(); data = FileFormat.load(stream, this); return data; } /** * Loads an array of <code>ImageData</code> objects from the * file with the specified name. Throws an error if either * an error occurs while loading the images, or if the images are * not of a supported type. Returns the loaded image data array. * * @param filename the name of the file to load the images from * @return an array of <code>ImageData</code> objects loaded from the specified file * * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if the file name is null</li> * </ul> * @exception SWTException <ul> * <li>ERROR_INVALID_IMAGE - if the image file contains invalid data</li> * <li>ERROR_IO - if an IO error occurs while reading data</li> * <li>ERROR_UNSUPPORTED_FORMAT - if the image file contains an unrecognized format</li> * </ul> */ public ImageData[] load(String filename) { if (filename == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); InputStream stream = null; try { stream = new FileInputStream(filename); return load(stream); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } finally { try { if (stream != null) stream.close(); } catch (IOException e) { // Ignore error } } return null; } } static class ImageData { /** * The width of the image, in pixels. */ public int width; /** * The height of the image, in pixels. */ public int height; /** * The color depth of the image, in bits per pixel. * <p> * Note that a depth of 8 or less does not necessarily * mean that the image is palette indexed, or * conversely that a depth greater than 8 means that * the image is direct color. Check the associated * PaletteData's isDirect field for such determinations. */ public int depth; /** * The scanline padding. * <p> * If one scanline of the image is not a multiple of * this number, it will be padded with zeros until it is. * </p> */ public int scanlinePad; /** * The number of bytes per scanline. * <p> * This is a multiple of the scanline padding. * </p> */ public int bytesPerLine; /** * The pixel data of the image. * <p> * Note that for 16 bit depth images the pixel data is stored * in least significant byte order; however, for 24bit and * 32bit depth images the pixel data is stored in most * significant byte order. * </p> */ public byte[] data; /** * The color table for the image. */ public PaletteData palette; /** * The transparent pixel. * <p> * Pixels with this value are transparent. * </p><p> * The default is -1 which means 'no transparent pixel'. * </p> */ public int transparentPixel; /** * An icon-specific field containing the data from the icon mask. * <p> * This is a 1 bit bitmap stored with the most significant * bit first. The number of bytes per scanline is * '((width + 7) / 8 + (maskPad - 1)) / maskPad * maskPad'. * </p><p> * The default is null which means 'no transparency mask'. * </p> */ public byte[] maskData; /** * An icon-specific field containing the scanline pad of the mask. * <p> * If one scanline of the transparency mask is not a * multiple of this number, it will be padded with zeros until * it is. * </p> */ public int maskPad; /** * The alpha data of the image. * <p> * Every pixel can have an <em>alpha blending</em> value that * varies from 0, meaning fully transparent, to 255 meaning * fully opaque. The number of bytes per scanline is * 'width'. * </p> */ public byte[] alphaData; /** * The global alpha value to be used for every pixel. * <p> * If this value is set, the <code>alphaData</code> field * is ignored and when the image is rendered each pixel * will be blended with the background an amount * proportional to this value. * </p><p> * The default is -1 which means 'no global alpha value' * </p> */ public int alpha; /** * The type of file from which the image was read. * * It is expressed as one of the following values: * <dl> * <dt><code>IMAGE_BMP</code></dt> * <dd>Windows BMP file format, no compression</dd> * <dt><code>IMAGE_BMP_RLE</code></dt> * <dd>Windows BMP file format, RLE compression if appropriate</dd> * <dt><code>IMAGE_GIF</code></dt> * <dd>GIF file format</dd> * <dt><code>IMAGE_ICO</code></dt> * <dd>Windows ICO file format</dd> * <dt><code>IMAGE_JPEG</code></dt> * <dd>JPEG file format</dd> * <dt><code>IMAGE_PNG</code></dt> * <dd>PNG file format</dd> * </dl> */ public int type; /** * The x coordinate of the top left corner of the image * within the logical screen (this field corresponds to * the GIF89a Image Left Position value). */ public int x; /** * The y coordinate of the top left corner of the image * within the logical screen (this field corresponds to * the GIF89a Image Top Position value). */ public int y; /** * A description of how to dispose of the current image * before displaying the next. * * It is expressed as one of the following values: * <dl> * <dt><code>DM_UNSPECIFIED</code></dt> * <dd>disposal method not specified</dd> * <dt><code>DM_FILL_NONE</code></dt> * <dd>do nothing - leave the image in place</dd> * <dt><code>DM_FILL_BACKGROUND</code></dt> * <dd>fill with the background color</dd> * <dt><code>DM_FILL_PREVIOUS</code></dt> * <dd>restore the previous picture</dd> * </dl> * (this field corresponds to the GIF89a Disposal Method value) */ public int disposalMethod; /** * The time to delay before displaying the next image * in an animation (this field corresponds to the GIF89a * Delay Time value). */ public int delayTime; /** * Arbitrary channel width data to 8-bit conversion table. */ static final byte[][] ANY_TO_EIGHT = new byte[9][]; static { for (int b = 0; b < 9; ++b) { byte[] data = ANY_TO_EIGHT[b] = new byte[1 << b]; if (b == 0) continue; int inc = 0; for (int bit = 0x10000; (bit >>= b) != 0;) inc |= bit; for (int v = 0, p = 0; v < 0x10000; v+= inc) data[p++] = (byte)(v >> 8); } } static final byte[] ONE_TO_ONE_MAPPING = ANY_TO_EIGHT[8]; /** * Scaled 8x8 Bayer dither matrix. */ static final int[][] DITHER_MATRIX = { { 0xfc0000, 0x7c0000, 0xdc0000, 0x5c0000, 0xf40000, 0x740000, 0xd40000, 0x540000 }, { 0x3c0000, 0xbc0000, 0x1c0000, 0x9c0000, 0x340000, 0xb40000, 0x140000, 0x940000 }, { 0xcc0000, 0x4c0000, 0xec0000, 0x6c0000, 0xc40000, 0x440000, 0xe40000, 0x640000 }, { 0x0c0000, 0x8c0000, 0x2c0000, 0xac0000, 0x040000, 0x840000, 0x240000, 0xa40000 }, { 0xf00000, 0x700000, 0xd00000, 0x500000, 0xf80000, 0x780000, 0xd80000, 0x580000 }, { 0x300000, 0xb00000, 0x100000, 0x900000, 0x380000, 0xb80000, 0x180000, 0x980000 }, { 0xc00000, 0x400000, 0xe00000, 0x600000, 0xc80000, 0x480000, 0xe80000, 0x680000 }, { 0x000000, 0x800000, 0x200000, 0xa00000, 0x080000, 0x880000, 0x280000, 0xa80000 } }; /** * Constructs a new, empty ImageData with the given width, height, * depth and palette. The data will be initialized to an (all zero) * array of the appropriate size. * * @param width the width of the image * @param height the height of the image * @param depth the depth of the image * @param palette the palette of the image (must not be null) * * @exception IllegalArgumentException <ul> * <li>ERROR_INVALID_ARGUMENT - if the width or height is negative, or if the depth is not * one of 1, 2, 4, 8, 16, 24 or 32</li> * <li>ERROR_NULL_ARGUMENT - if the palette is null</li> * </ul> */ public ImageData(int width, int height, int depth, PaletteData palette) { this(width, height, depth, palette, 4, null, 0, null, null, -1, -1, SWT.IMAGE_UNDEFINED, 0, 0, 0, 0); } /** * Constructs a new, empty ImageData with the given width, height, * depth, palette, scanlinePad and data. * * @param width the width of the image * @param height the height of the image * @param depth the depth of the image * @param palette the palette of the image * @param scanlinePad the padding of each line, in bytes * @param data the data of the image * * @exception IllegalArgumentException <ul> * <li>ERROR_INVALID_ARGUMENT - if the width or height is negative, or if the depth is not * one of 1, 2, 4, 8, 16, 24 or 32</li> * <li>ERROR_NULL_ARGUMENT - if the palette or data is null</li> * <li>ERROR_CANNOT_BE_ZERO - if the scanlinePad is zero</li> * </ul> */ public ImageData(int width, int height, int depth, PaletteData palette, int scanlinePad, byte[] data) { this(width, height, depth, palette, scanlinePad, checkData(data), 0, null, null, -1, -1, SWT.IMAGE_UNDEFINED, 0, 0, 0, 0); } /** * Constructs an <code>ImageData</code> loaded from a file with the * specified name. Throws an error if an error occurs loading the * image, or if the image has an unsupported type. * <p> * This constructor is provided for convenience when loading a single * image only. If the file contains multiple images, only the first * one will be loaded. To load multiple images, use * <code>ImageLoader.load()</code>. * </p> * * @param filename the name of the file to load the image from (must not be null) * * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if the file name is null</li> * </ul> * @exception SWTException <ul> * <li>ERROR_INVALID_IMAGE - if the image file contains invalid data</li> * <li>ERROR_IO if an IO error occurs while reading data</li> * <li>ERROR_UNSUPPORTED_FORMAT - if the image file contains an unrecognized format</li> * </ul> */ public ImageData(String filename) { ImageData[] data = new ImageLoader().load(filename); if (data.length < 1) SWT.error(SWT.ERROR_INVALID_IMAGE); ImageData i = data[0]; setAllFields( i.width, i.height, i.depth, i.scanlinePad, i.bytesPerLine, i.data, i.palette, i.transparentPixel, i.maskData, i.maskPad, i.alphaData, i.alpha, i.type, i.x, i.y, i.disposalMethod, i.delayTime); } /** * Prevents uninitialized instances from being created outside the package. */ ImageData() { } /** * Constructs an image data by giving values for all non-computable fields. * <p> * This method is for internal use, and is not described further. * </p> */ ImageData( int width, int height, int depth, PaletteData palette, int scanlinePad, byte[] data, int maskPad, byte[] maskData, byte[] alphaData, int alpha, int transparentPixel, int type, int x, int y, int disposalMethod, int delayTime) { if (palette == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); if (!(depth == 1 || depth == 2 || depth == 4 || depth == 8 || depth == 16 || depth == 24 || depth == 32)) { SWT.error(SWT.ERROR_INVALID_ARGUMENT); } if (width <= 0 || height <= 0) { SWT.error(SWT.ERROR_INVALID_ARGUMENT); } if (scanlinePad == 0) SWT.error (SWT.ERROR_CANNOT_BE_ZERO); int bytesPerLine = (((width * depth + 7) / 8) + (scanlinePad - 1)) / scanlinePad * scanlinePad; setAllFields( width, height, depth, scanlinePad, bytesPerLine, data != null ? data : new byte[bytesPerLine * height], palette, transparentPixel, maskData, maskPad, alphaData, alpha, type, x, y, disposalMethod, delayTime); } /** * Initializes all fields in the receiver. This method must be called * by all public constructors to ensure that all fields are initialized * for a new ImageData object. If a new field is added to the class, * then it must be added to this method. * <p> * This method is for internal use, and is not described further. * </p> */ void setAllFields(int width, int height, int depth, int scanlinePad, int bytesPerLine, byte[] data, PaletteData palette, int transparentPixel, byte[] maskData, int maskPad, byte[] alphaData, int alpha, int type, int x, int y, int disposalMethod, int delayTime) { this.width = width; this.height = height; this.depth = depth; this.scanlinePad = scanlinePad; this.bytesPerLine = bytesPerLine; this.data = data; this.palette = palette; this.transparentPixel = transparentPixel; this.maskData = maskData; this.maskPad = maskPad; this.alphaData = alphaData; this.alpha = alpha; this.type = type; this.x = x; this.y = y; this.disposalMethod = disposalMethod; this.delayTime = delayTime; } /** * Invokes internal SWT functionality to create a new instance of * this class. * <p> * <b>IMPORTANT:</b> This method is <em>not</em> part of the public * API for <code>ImageData</code>. It is marked public only so that it * can be shared within the packages provided by SWT. It is subject * to change without notice, and should never be called from * application code. * </p> * <p> * This method is for internal use, and is not described further. * </p> */ public static ImageData internal_new( int width, int height, int depth, PaletteData palette, int scanlinePad, byte[] data, int maskPad, byte[] maskData, byte[] alphaData, int alpha, int transparentPixel, int type, int x, int y, int disposalMethod, int delayTime) { return new ImageData( width, height, depth, palette, scanlinePad, data, maskPad, maskData, alphaData, alpha, transparentPixel, type, x, y, disposalMethod, delayTime); } ImageData colorMaskImage(int pixel) { ImageData mask = new ImageData(width, height, 1, bwPalette(), 2, null, 0, null, null, -1, -1, SWT.IMAGE_UNDEFINED, 0, 0, 0, 0); int[] row = new int[width]; for (int y = 0; y < height; y++) { getPixels(0, y, width, row, 0); for (int i = 0; i < width; i++) { if (pixel != -1 && row[i] == pixel) { row[i] = 0; } else { row[i] = 1; } } mask.setPixels(0, y, width, row, 0); } return mask; } static byte[] checkData(byte [] data) { if (data == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); return data; } /** * Returns <code>getWidth</code> pixel values starting at offset * <code>x</code> in scanline <code>y</code> in the receiver's * data starting at <code>startIndex</code>. * * @param x the x position of the first pixel to get * @param y the y position of the first pixel to get * @param getWidth the width of the data to get * @param pixels the buffer in which to put the pixels * @param startIndex the offset into the byte array to begin storing pixels * * @exception IndexOutOfBoundsException if getWidth is too large * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if pixels is null</li> * <li>ERROR_INVALID_ARGUMENT - if x or y is out of bounds</li> * <li>ERROR_INVALID_ARGUMENT - if getWidth is negative</li> * </ul> * @exception SWTException <ul> * <li>ERROR_UNSUPPORTED_DEPTH - if the depth is not one of 1, 2, 4 or 8 * (For higher depths, use the int[] version of this method.)</li> * </ul> */ public void getPixels(int x, int y, int getWidth, byte[] pixels, int startIndex) { if (pixels == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); if (getWidth < 0 || x >= width || y >= height || x < 0 || y < 0) SWT.error (SWT.ERROR_INVALID_ARGUMENT); if (getWidth == 0) return; int index; int theByte; int mask = 0; int n = getWidth; int i = startIndex; int srcX = x, srcY = y; if (depth == 1) { index = (y * bytesPerLine) + (x >> 3); theByte = data[index] & 0xFF; while (n > 0) { mask = 1 << (7 - (srcX & 0x7)); if ((theByte & mask) == 0) { pixels[i] = 0; } else { pixels[i] = 1; } i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; if (n > 0) theByte = data[index] & 0xFF; srcX = 0; } else { if (mask == 1) { index++; if (n > 0) theByte = data[index] & 0xFF; } } } return; } if (depth == 2) { index = (y * bytesPerLine) + (x >> 2); theByte = data[index] & 0xFF; int offset; while (n > 0) { offset = 3 - (srcX % 4); mask = 3 << (offset * 2); pixels[i] = (byte)((theByte & mask) >> (offset * 2)); i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; if (n > 0) theByte = data[index] & 0xFF; srcX = 0; } else { if (offset == 0) { index++; theByte = data[index] & 0xFF; } } } return; } if (depth == 4) { index = (y * bytesPerLine) + (x >> 1); if ((x & 0x1) == 1) { theByte = data[index] & 0xFF; pixels[i] = (byte)(theByte & 0x0F); i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } while (n > 1) { theByte = data[index] & 0xFF; pixels[i] = (byte)(theByte >> 4); i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { pixels[i] = (byte)(theByte & 0x0F); i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } } if (n > 0) { theByte = data[index] & 0xFF; pixels[i] = (byte)(theByte >> 4); } return; } if (depth == 8) { index = (y * bytesPerLine) + x; for (int j = 0; j < getWidth; j++) { pixels[i] = data[index]; i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } return; } SWT.error(SWT.ERROR_UNSUPPORTED_DEPTH); } /** * Returns <code>getWidth</code> pixel values starting at offset * <code>x</code> in scanline <code>y</code> in the receiver's * data starting at <code>startIndex</code>. * * @param x the x position of the first pixel to get * @param y the y position of the first pixel to get * @param getWidth the width of the data to get * @param pixels the buffer in which to put the pixels * @param startIndex the offset into the buffer to begin storing pixels * * @exception IndexOutOfBoundsException if getWidth is too large * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if pixels is null</li> * <li>ERROR_INVALID_ARGUMENT - if x or y is out of bounds</li> * <li>ERROR_INVALID_ARGUMENT - if getWidth is negative</li> * </ul> * @exception SWTException <ul> * <li>ERROR_UNSUPPORTED_DEPTH - if the depth is not one of 1, 2, 4, 8, 16, 24 or 32</li> * </ul> */ public void getPixels(int x, int y, int getWidth, int[] pixels, int startIndex) { if (pixels == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); if (getWidth < 0 || x >= width || y >= height || x < 0 || y < 0) SWT.error (SWT.ERROR_INVALID_ARGUMENT); if (getWidth == 0) return; int index; int theByte; int mask; int n = getWidth; int i = startIndex; int srcX = x, srcY = y; if (depth == 1) { index = (y * bytesPerLine) + (x >> 3); theByte = data[index] & 0xFF; while (n > 0) { mask = 1 << (7 - (srcX & 0x7)); if ((theByte & mask) == 0) { pixels[i] = 0; } else { pixels[i] = 1; } i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; if (n > 0) theByte = data[index] & 0xFF; srcX = 0; } else { if (mask == 1) { index++; if (n > 0) theByte = data[index] & 0xFF; } } } return; } if (depth == 2) { index = (y * bytesPerLine) + (x >> 2); theByte = data[index] & 0xFF; int offset; while (n > 0) { offset = 3 - (srcX % 4); mask = 3 << (offset * 2); pixels[i] = (byte)((theByte & mask) >> (offset * 2)); i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; if (n > 0) theByte = data[index] & 0xFF; srcX = 0; } else { if (offset == 0) { index++; theByte = data[index] & 0xFF; } } } return; } if (depth == 4) { index = (y * bytesPerLine) + (x >> 1); if ((x & 0x1) == 1) { theByte = data[index] & 0xFF; pixels[i] = theByte & 0x0F; i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } while (n > 1) { theByte = data[index] & 0xFF; pixels[i] = theByte >> 4; i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { pixels[i] = theByte & 0x0F; i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } } if (n > 0) { theByte = data[index] & 0xFF; pixels[i] = theByte >> 4; } return; } if (depth == 8) { index = (y * bytesPerLine) + x; for (int j = 0; j < getWidth; j++) { pixels[i] = data[index] & 0xFF; i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } return; } if (depth == 16) { index = (y * bytesPerLine) + (x * 2); for (int j = 0; j < getWidth; j++) { pixels[i] = ((data[index+1] & 0xFF) << 8) + (data[index] & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index += 2; } } return; } if (depth == 24) { index = (y * bytesPerLine) + (x * 3); for (int j = 0; j < getWidth; j++) { pixels[i] = ((data[index] & 0xFF) << 16) | ((data[index+1] & 0xFF) << 8) | (data[index+2] & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index += 3; } } return; } if (depth == 32) { index = (y * bytesPerLine) + (x * 4); i = startIndex; for (int j = 0; j < getWidth; j++) { pixels[i] = ((data[index] & 0xFF) << 24) | ((data[index+1] & 0xFF) << 16) | ((data[index+2] & 0xFF) << 8) | (data[index+3] & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index += 4; } } return; } SWT.error(SWT.ERROR_UNSUPPORTED_DEPTH); } /** * Returns an array of <code>RGB</code>s which comprise the * indexed color table of the receiver, or null if the receiver * has a direct color model. * * @return the RGB values for the image or null if direct color * * @see PaletteData#getRGBs() */ public RGB[] getRGBs() { return palette.getRGBs(); } /** * Returns an <code>ImageData</code> which specifies the * transparency mask information for the receiver, or null if the * receiver has no transparency and is not an icon. * * @return the transparency mask or null if none exists */ public ImageData getTransparencyMask() { if (getTransparencyType() == SWT.TRANSPARENCY_MASK) { return new ImageData(width, height, 1, bwPalette(), maskPad, maskData); } else { return colorMaskImage(transparentPixel); } } /** * Returns the image transparency type. * * @return the receiver's transparency type */ public int getTransparencyType() { if (maskData != null) return SWT.TRANSPARENCY_MASK; if (transparentPixel != -1) return SWT.TRANSPARENCY_PIXEL; if (alphaData != null) return SWT.TRANSPARENCY_ALPHA; return SWT.TRANSPARENCY_NONE; } /** * Returns the byte order of the receiver. * * @return MSB_FIRST or LSB_FIRST */ int getByteOrder() { return depth != 16 ? MSB_FIRST : LSB_FIRST; } /** * Sets the pixel values starting at offset <code>x</code> in * scanline <code>y</code> in the receiver's data to the * values from the array <code>pixels</code> starting at * <code>startIndex</code>. * * @param x the x position of the pixel to set * @param y the y position of the pixel to set * @param putWidth the width of the pixels to set * @param pixels the pixels to set * @param startIndex the index at which to begin setting * * @exception IndexOutOfBoundsException if putWidth is too large * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if pixels is null</li> * <li>ERROR_INVALID_ARGUMENT - if x or y is out of bounds</li> * <li>ERROR_INVALID_ARGUMENT - if putWidth is negative</li> * </ul> * @exception SWTException <ul> * <li>ERROR_UNSUPPORTED_DEPTH if the depth is not one of 1, 2, 4, 8 * (For higher depths, use the int[] version of this method.)</li> * </ul> */ public void setPixels(int x, int y, int putWidth, byte[] pixels, int startIndex) { if (pixels == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); if (putWidth < 0 || x >= width || y >= height || x < 0 || y < 0) SWT.error(SWT.ERROR_INVALID_ARGUMENT); if (putWidth == 0) return; int index; int theByte; int mask; int n = putWidth; int i = startIndex; int srcX = x, srcY = y; if (depth == 1) { index = (y * bytesPerLine) + (x >> 3); while (n > 0) { mask = 1 << (7 - (srcX & 0x7)); if ((pixels[i] & 0x1) == 1) { data[index] = (byte)((data[index] & 0xFF) | mask); } else { data[index] = (byte)((data[index] & 0xFF) & (mask ^ -1)); } i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { if (mask == 1) { index++; } } } return; } if (depth == 2) { byte [] masks = { (byte)0xFC, (byte)0xF3, (byte)0xCF, (byte)0x3F }; index = (y * bytesPerLine) + (x >> 2); int offset = 3 - (x % 4); while (n > 0) { theByte = pixels[i] & 0x3; data[index] = (byte)((data[index] & masks[offset]) | (theByte << (offset * 2))); i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; offset = 0; srcX = 0; } else { if (offset == 0) { index++; offset = 3; } else { offset--; } } } return; } if (depth == 4) { index = (y * bytesPerLine) + (x >> 1); boolean high = (x & 0x1) == 0; while (n > 0) { theByte = pixels[i] & 0x0F; if (high) { data[index] = (byte)((data[index] & 0x0F) | (theByte << 4)); } else { data[index] = (byte)((data[index] & 0xF0) | theByte); } i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; high = true; srcX = 0; } else { if (!high) index++; high = !high; } } return; } if (depth == 8) { index = (y * bytesPerLine) + x; for (int j = 0; j < putWidth; j++) { data[index] = (byte)(pixels[i] & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } return; } SWT.error(SWT.ERROR_UNSUPPORTED_DEPTH); } /** * Sets the pixel values starting at offset <code>x</code> in * scanline <code>y</code> in the receiver's data to the * values from the array <code>pixels</code> starting at * <code>startIndex</code>. * * @param x the x position of the pixel to set * @param y the y position of the pixel to set * @param putWidth the width of the pixels to set * @param pixels the pixels to set * @param startIndex the index at which to begin setting * * @exception IndexOutOfBoundsException if putWidth is too large * @exception IllegalArgumentException <ul> * <li>ERROR_NULL_ARGUMENT - if pixels is null</li> * <li>ERROR_INVALID_ARGUMENT - if x or y is out of bounds</li> * <li>ERROR_INVALID_ARGUMENT - if putWidth is negative</li> * </ul> * @exception SWTException <ul> * <li>ERROR_UNSUPPORTED_DEPTH if the depth is not one of 1, 2, 4, 8, 16, 24 or 32</li> * </ul> */ public void setPixels(int x, int y, int putWidth, int[] pixels, int startIndex) { if (pixels == null) SWT.error(SWT.ERROR_NULL_ARGUMENT); if (putWidth < 0 || x >= width || y >= height || x < 0 || y < 0) SWT.error(SWT.ERROR_INVALID_ARGUMENT); if (putWidth == 0) return; int index; int theByte; int mask; int n = putWidth; int i = startIndex; int pixel; int srcX = x, srcY = y; if (depth == 1) { index = (y * bytesPerLine) + (x >> 3); while (n > 0) { mask = 1 << (7 - (srcX & 0x7)); if ((pixels[i] & 0x1) == 1) { data[index] = (byte)((data[index] & 0xFF) | mask); } else { data[index] = (byte)((data[index] & 0xFF) & (mask ^ -1)); } i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { if (mask == 1) { index++; } } } return; } if (depth == 2) { byte [] masks = { (byte)0xFC, (byte)0xF3, (byte)0xCF, (byte)0x3F }; index = (y * bytesPerLine) + (x >> 2); int offset = 3 - (x % 4); while (n > 0) { theByte = pixels[i] & 0x3; data[index] = (byte)((data[index] & masks[offset]) | (theByte << (offset * 2))); i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; offset = 3; srcX = 0; } else { if (offset == 0) { index++; offset = 3; } else { offset--; } } } return; } if (depth == 4) { index = (y * bytesPerLine) + (x >> 1); boolean high = (x & 0x1) == 0; while (n > 0) { theByte = pixels[i] & 0x0F; if (high) { data[index] = (byte)((data[index] & 0x0F) | (theByte << 4)); } else { data[index] = (byte)((data[index] & 0xF0) | theByte); } i++; n--; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; high = true; srcX = 0; } else { if (!high) index++; high = !high; } } return; } if (depth == 8) { index = (y * bytesPerLine) + x; for (int j = 0; j < putWidth; j++) { data[index] = (byte)(pixels[i] & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index++; } } return; } if (depth == 16) { index = (y * bytesPerLine) + (x * 2); for (int j = 0; j < putWidth; j++) { pixel = pixels[i]; data[index] = (byte)(pixel & 0xFF); data[index + 1] = (byte)((pixel >> 8) & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index += 2; } } return; } if (depth == 24) { index = (y * bytesPerLine) + (x * 3); for (int j = 0; j < putWidth; j++) { pixel = pixels[i]; data[index] = (byte)((pixel >> 16) & 0xFF); data[index + 1] = (byte)((pixel >> 8) & 0xFF); data[index + 2] = (byte)(pixel & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index += 3; } } return; } if (depth == 32) { index = (y * bytesPerLine) + (x * 4); for (int j = 0; j < putWidth; j++) { pixel = pixels[i]; data[index] = (byte)((pixel >> 24) & 0xFF); data[index + 1] = (byte)((pixel >> 16) & 0xFF); data[index + 2] = (byte)((pixel >> 8) & 0xFF); data[index + 3] = (byte)(pixel & 0xFF); i++; srcX++; if (srcX >= width) { srcY++; index = srcY * bytesPerLine; srcX = 0; } else { index += 4; } } return; } SWT.error(SWT.ERROR_UNSUPPORTED_DEPTH); } /** * Returns a palette with 2 colors: black & white. */ static PaletteData bwPalette() { return new PaletteData(new RGB[] {new RGB(0, 0, 0), new RGB(255, 255, 255)}); } /** * Gets the offset of the most significant bit for * the given mask. */ static int getMSBOffset(int mask) { for (int i = 31; i >= 0; i--) { if (((mask >> i) & 0x1) != 0) return i + 1; } return 0; } /** * Finds the closest match. */ static int closestMatch(int depth, byte red, byte green, byte blue, int redMask, int greenMask, int blueMask, byte[] reds, byte[] greens, byte[] blues) { if (depth > 8) { int rshift = 32 - getMSBOffset(redMask); int gshift = 32 - getMSBOffset(greenMask); int bshift = 32 - getMSBOffset(blueMask); return (((red << 24) >>> rshift) & redMask) | (((green << 24) >>> gshift) & greenMask) | (((blue << 24) >>> bshift) & blueMask); } int r, g, b; int minDistance = 0x7fffffff; int nearestPixel = 0; int n = reds.length; for (int j = 0; j < n; j++) { r = (reds[j] & 0xFF) - (red & 0xFF); g = (greens[j] & 0xFF) - (green & 0xFF); b = (blues[j] & 0xFF) - (blue & 0xFF); int distance = r*r + g*g + b*b; if (distance < minDistance) { nearestPixel = j; if (distance == 0) break; minDistance = distance; } } return nearestPixel; } static final ImageData convertMask(ImageData mask) { if (mask.depth == 1) return mask; PaletteData palette = new PaletteData(new RGB[] {new RGB(0, 0, 0), new RGB(255,255,255)}); ImageData newMask = new ImageData(mask.width, mask.height, 1, palette); /* Find index of black in mask palette */ int blackIndex = 0; RGB[] rgbs = mask.getRGBs(); if (rgbs != null) { while (blackIndex < rgbs.length) { if (rgbs[blackIndex].equals(palette.colors[0])) break; blackIndex++; } } int[] pixels = new int[mask.width]; for (int y = 0; y < mask.height; y++) { mask.getPixels(0, y, mask.width, pixels, 0); for (int i = 0; i < pixels.length; i++) { if (pixels[i] == blackIndex) { pixels[i] = 0; } else { pixels[i] = 1; } } newMask.setPixels(0, y, mask.width, pixels, 0); } return newMask; } static final byte[] convertPad(byte[] data, int width, int height, int depth, int pad, int newPad) { if (pad == newPad) return data; int stride = (width * depth + 7) / 8; int bpl = (stride + (pad - 1)) / pad * pad; int newBpl = (stride + (newPad - 1)) / newPad * newPad; byte[] newData = new byte[height * newBpl]; int srcIndex = 0, destIndex = 0; for (int y = 0; y < height; y++) { System.arraycopy(data, srcIndex, newData, destIndex, stride); srcIndex += bpl; destIndex += newBpl; } return newData; } /** * Blit operation bits to be OR'ed together to specify the desired operation. */ static final int BLIT_SRC = 1, // copy source directly, else applies logic operations BLIT_ALPHA = 2, // enable alpha blending BLIT_DITHER = 4; // enable dithering in low color modes /** * Alpha mode, values 0 - 255 specify global alpha level */ static final int ALPHA_OPAQUE = 255, // Fully opaque (ignores any alpha data) ALPHA_TRANSPARENT = 0, // Fully transparent (ignores any alpha data) ALPHA_CHANNEL_SEPARATE = -1, // Use alpha channel from separate alphaData ALPHA_CHANNEL_SOURCE = -2, // Use alpha channel embedded in sourceData ALPHA_MASK_UNPACKED = -3, // Use transparency mask formed by bytes in alphaData (non-zero is opaque) ALPHA_MASK_PACKED = -4, // Use transparency mask formed by packed bits in alphaData ALPHA_MASK_INDEX = -5, // Consider source palette indices transparent if in alphaData array ALPHA_MASK_RGB = -6; // Consider source RGBs transparent if in RGB888 format alphaData array /** * Byte and bit order constants. */ static final int LSB_FIRST = 0; static final int MSB_FIRST = 1; /** * Data types (internal) */ //private static final int // // direct / true color formats with arbitrary masks & shifts // TYPE_GENERIC_8 = 0, // TYPE_GENERIC_16_MSB = 1, // TYPE_GENERIC_16_LSB = 2, // TYPE_GENERIC_24 = 3, // TYPE_GENERIC_32_MSB = 4, // TYPE_GENERIC_32_LSB = 5, // // palette indexed color formats // TYPE_INDEX_8 = 6, // TYPE_INDEX_4 = 7, // TYPE_INDEX_2 = 8, // TYPE_INDEX_1_MSB = 9, // TYPE_INDEX_1_LSB = 10; /** * Computes the required channel shift from a mask. */ static int getChannelShift(int mask) { if (mask == 0) return 0; int i; for (i = 0; ((mask & 1) == 0) && (i < 32); ++i) { mask >>>= 1; } return i; } /** * Computes the required channel width (depth) from a mask. */ static int getChannelWidth(int mask, int shift) { if (mask == 0) return 0; int i; mask >>>= shift; for (i = shift; ((mask & 1) != 0) && (i < 32); ++i) { mask >>>= 1; } return i - shift; } /** * Extracts a field from packed RGB data given a mask for that field. */ static byte getChannelField(int data, int mask) { final int shift = getChannelShift(mask); return ANY_TO_EIGHT[getChannelWidth(mask, shift)][(data & mask) >>> shift]; } /* * Fill in dithered gradated values for a color channel */ static final void buildDitheredGradientChannel(int from, int to, int steps, int bandWidth, int bandHeight, boolean vertical, byte[] bitmapData, int dp, int bytesPerLine, int bits) { final int mask = 0xff00 >>> bits; int val = from << 16; final int inc = ((to << 16) - val) / steps + 1; if (vertical) { for (int dy = 0; dy < bandHeight; ++dy, dp += bytesPerLine) { for (int dx = 0, dptr = dp; dx < bandWidth; ++dx, dptr += 4) { final int thresh = DITHER_MATRIX[dy & 7][dx] >>> bits; int temp = val + thresh; if (temp > 0xffffff) bitmapData[dptr] = -1; else bitmapData[dptr] = (byte)((temp >>> 16) & mask); } val += inc; } } else { for (int dx = 0; dx < bandWidth; ++dx, dp += 4) { for (int dy = 0, dptr = dp; dy < bandHeight; ++dy, dptr += bytesPerLine) { final int thresh = DITHER_MATRIX[dy][dx & 7] >>> bits; int temp = val + thresh; if (temp > 0xffffff) bitmapData[dptr] = -1; else bitmapData[dptr] = (byte)((temp >>> 16) & mask); } val += inc; } } } } static class LEDataInputStream extends InputStream { int position; InputStream in; /** * The byte array containing the bytes to read. */ protected byte[] buf; /** * The current position within the byte array <code>buf</code>. A value * equal to buf.length indicates no bytes available. A value of * 0 indicates the buffer is full. */ protected int pos; public LEDataInputStream(InputStream input) { this(input, 512); } public LEDataInputStream(InputStream input, int bufferSize) { this.in = input; if (bufferSize > 0) { buf = new byte[bufferSize]; pos = bufferSize; } else throw new IllegalArgumentException(); } @Override public void close() throws IOException { buf = null; if (in != null) { in.close(); in = null; } } /** * Answer how many bytes were read. */ public int getPosition() { return position; } /** * Answers how many bytes are available for reading without blocking */ @Override public int available() throws IOException { if (buf == null) throw new IOException(); return (buf.length - pos) + in.available(); } /** * Answer the next byte of the input stream. */ @Override public int read() throws IOException { if (buf == null) throw new IOException(); position++; if (pos < buf.length) return (buf[pos++] & 0xFF); return in.read(); } /** * Don't imitate the JDK behaviour of reading a random number * of bytes when you can actually read them all. */ @Override public int read(byte b[], int off, int len) throws IOException { int result; int left = len; result = readData(b, off, len); while (true) { if (result == -1) return -1; position += result; if (result == left) return len; left -= result; off += result; result = readData(b, off, left); } } /** * Reads at most <code>length</code> bytes from this LEDataInputStream and * stores them in byte array <code>buffer</code> starting at <code>offset</code>. * <p> * Answer the number of bytes actually read or -1 if no bytes were read and * end of stream was encountered. This implementation reads bytes from * the pushback buffer first, then the target stream if more bytes are required * to satisfy <code>count</code>. * </p> * @param buffer the byte array in which to store the read bytes. * @param offset the offset in <code>buffer</code> to store the read bytes. * @param length the maximum number of bytes to store in <code>buffer</code>. * * @return int the number of bytes actually read or -1 if end of stream. * * @exception java.io.IOException if an IOException occurs. */ private int readData(byte[] buffer, int offset, int length) throws IOException { if (buf == null) throw new IOException(); if (offset < 0 || offset > buffer.length || length < 0 || (length > buffer.length - offset)) { throw new ArrayIndexOutOfBoundsException(); } int cacheCopied = 0; int newOffset = offset; // Are there pushback bytes available? int available = buf.length - pos; if (available > 0) { cacheCopied = (available >= length) ? length : available; System.arraycopy(buf, pos, buffer, newOffset, cacheCopied); newOffset += cacheCopied; pos += cacheCopied; } // Have we copied enough? if (cacheCopied == length) return length; int inCopied = in.read(buffer, newOffset, length - cacheCopied); if (inCopied > 0) return inCopied + cacheCopied; if (cacheCopied == 0) return inCopied; return cacheCopied; } /** * Answer an integer comprised of the next * four bytes of the input stream. */ public int readInt() throws IOException { byte[] buf = new byte[4]; read(buf); return ((((((buf[3] & 0xFF) << 8) | (buf[2] & 0xFF)) << 8) | (buf[1] & 0xFF)) << 8) | (buf[0] & 0xFF); } /** * Answer a short comprised of the next * two bytes of the input stream. */ public short readShort() throws IOException { byte[] buf = new byte[2]; read(buf); return (short)(((buf[1] & 0xFF) << 8) | (buf[0] & 0xFF)); } /** * Push back the entire content of the given buffer <code>b</code>. * <p> * The bytes are pushed so that they would be read back b[0], b[1], etc. * If the push back buffer cannot handle the bytes copied from <code>b</code>, * an IOException will be thrown and no byte will be pushed back. * </p> * * @param b the byte array containing bytes to push back into the stream * * @exception java.io.IOException if the pushback buffer is too small */ public void unread(byte[] b) throws IOException { int length = b.length; if (length > pos) throw new IOException(); position -= length; pos -= length; System.arraycopy(b, 0, buf, pos, length); } } public static abstract class FileFormat { LEDataInputStream inputStream; ImageLoader loader; int compression; byte[] bitInvertData(byte[] data, int startIndex, int endIndex) { // Destructively bit invert data in the given byte array. for (int i = startIndex; i < endIndex; i++) { data[i] = (byte)(255 - data[i - startIndex]); } return data; } /** * Return whether or not the specified input stream * represents a supported file format. */ abstract boolean isFileFormat(LEDataInputStream stream); abstract ImageData[] loadFromByteStream(); public ImageData[] loadFromStream(LEDataInputStream stream) { try { inputStream = stream; return loadFromByteStream(); } catch (Exception e) { SWT.error(SWT.ERROR_IO, e); return null; } } public static ImageData[] load(InputStream is, ImageLoader loader) { LEDataInputStream stream = new LEDataInputStream(is); boolean isSupported = false; FileFormat fileFormat = new WinICOFileFormat(); if (fileFormat.isFileFormat(stream)) isSupported = true; else { fileFormat = new WinBMPFileFormat(); if (fileFormat.isFileFormat(stream)) isSupported = true; } if (!isSupported) SWT.error(SWT.ERROR_UNSUPPORTED_FORMAT); fileFormat.loader = loader; return fileFormat.loadFromStream(stream); } } static class WinBMPFileFormat extends FileFormat { static final int BMPFileHeaderSize = 14; static final int BMPHeaderFixedSize = 40; int importantColors; void decompressData(byte[] src, byte[] dest, int stride, int cmp) { if (cmp == 1) { // BMP_RLE8_COMPRESSION if (decompressRLE8Data(src, src.length, stride, dest, dest.length) <= 0) SWT.error(SWT.ERROR_INVALID_IMAGE); return; } if (cmp == 2) { // BMP_RLE4_COMPRESSION if (decompressRLE4Data(src, src.length, stride, dest, dest.length) <= 0) SWT.error(SWT.ERROR_INVALID_IMAGE); return; } SWT.error(SWT.ERROR_INVALID_IMAGE); } int decompressRLE4Data(byte[] src, int numBytes, int stride, byte[] dest, int destSize) { int sp = 0; int se = numBytes; int dp = 0; int de = destSize; int x = 0, y = 0; while (sp < se) { int len = src[sp] & 0xFF; sp++; if (len == 0) { len = src[sp] & 0xFF; sp++; switch (len) { case 0: /* end of line */ y++; x = 0; dp = y * stride; if (dp >= de) return -1; break; case 1: /* end of bitmap */ return 1; case 2: /* delta */ x += src[sp] & 0xFF; sp++; y += src[sp] & 0xFF; sp++; dp = y * stride + x / 2; if (dp >= de) return -1; break; default: /* absolute mode run */ if ((len & 1) != 0) /* odd run lengths not currently supported */ return -1; x += len; len = len / 2; if (len > (se - sp)) return -1; if (len > (de - dp)) return -1; for (int i = 0; i < len; i++) { dest[dp] = src[sp]; dp++; sp++; } if ((sp & 1) != 0) sp++; /* word align sp? */ break; } } else { if ((len & 1) != 0) return -1; x += len; len = len / 2; byte theByte = src[sp]; sp++; if (len > (de - dp)) return -1; for (int i = 0; i < len; i++) { dest[dp] = theByte; dp++; } } } return 1; } int decompressRLE8Data(byte[] src, int numBytes, int stride, byte[] dest, int destSize) { int sp = 0; int se = numBytes; int dp = 0; int de = destSize; int x = 0, y = 0; while (sp < se) { int len = src[sp] & 0xFF; sp++; if (len == 0) { len = src[sp] & 0xFF; sp++; switch (len) { case 0: /* end of line */ y++; x = 0; dp = y * stride; if (dp >= de) return -1; break; case 1: /* end of bitmap */ return 1; case 2: /* delta */ x += src[sp] & 0xFF; sp++; y += src[sp] & 0xFF; sp++; dp = y * stride + x; if (dp >= de) return -1; break; default: /* absolute mode run */ if (len > (se - sp)) return -1; if (len > (de - dp)) return -1; for (int i = 0; i < len; i++) { dest[dp] = src[sp]; dp++; sp++; } if ((sp & 1) != 0) sp++; /* word align sp? */ x += len; break; } } else { byte theByte = src[sp]; sp++; if (len > (de - dp)) return -1; for (int i = 0; i < len; i++) { dest[dp] = theByte; dp++; } x += len; } } return 1; } @Override boolean isFileFormat(LEDataInputStream stream) { try { byte[] header = new byte[18]; stream.read(header); stream.unread(header); int infoHeaderSize = (header[14] & 0xFF) | ((header[15] & 0xFF) << 8) | ((header[16] & 0xFF) << 16) | ((header[17] & 0xFF) << 24); return header[0] == 0x42 && header[1] == 0x4D && infoHeaderSize >= BMPHeaderFixedSize; } catch (Exception e) { return false; } } byte[] loadData(byte[] infoHeader) { int width = (infoHeader[4] & 0xFF) | ((infoHeader[5] & 0xFF) << 8) | ((infoHeader[6] & 0xFF) << 16) | ((infoHeader[7] & 0xFF) << 24); int height = (infoHeader[8] & 0xFF) | ((infoHeader[9] & 0xFF) << 8) | ((infoHeader[10] & 0xFF) << 16) | ((infoHeader[11] & 0xFF) << 24); int bitCount = (infoHeader[14] & 0xFF) | ((infoHeader[15] & 0xFF) << 8); int stride = (width * bitCount + 7) / 8; stride = (stride + 3) / 4 * 4; // Round up to 4 byte multiple byte[] data = loadData(infoHeader, stride); flipScanLines(data, stride, height); return data; } byte[] loadData(byte[] infoHeader, int stride) { int height = (infoHeader[8] & 0xFF) | ((infoHeader[9] & 0xFF) << 8) | ((infoHeader[10] & 0xFF) << 16) | ((infoHeader[11] & 0xFF) << 24); int dataSize = height * stride; byte[] data = new byte[dataSize]; int cmp = (infoHeader[16] & 0xFF) | ((infoHeader[17] & 0xFF) << 8) | ((infoHeader[18] & 0xFF) << 16) | ((infoHeader[19] & 0xFF) << 24); if (cmp == 0) { // BMP_NO_COMPRESSION try { if (inputStream.read(data) != dataSize) SWT.error(SWT.ERROR_INVALID_IMAGE); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } } else { int compressedSize = (infoHeader[20] & 0xFF) | ((infoHeader[21] & 0xFF) << 8) | ((infoHeader[22] & 0xFF) << 16) | ((infoHeader[23] & 0xFF) << 24); byte[] compressed = new byte[compressedSize]; try { if (inputStream.read(compressed) != compressedSize) SWT.error(SWT.ERROR_INVALID_IMAGE); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } decompressData(compressed, data, stride, cmp); } return data; } int[] loadFileHeader() { int[] header = new int[5]; try { header[0] = inputStream.readShort(); header[1] = inputStream.readInt(); header[2] = inputStream.readShort(); header[3] = inputStream.readShort(); header[4] = inputStream.readInt(); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } if (header[0] != 0x4D42) SWT.error(SWT.ERROR_INVALID_IMAGE); return header; } @Override ImageData[] loadFromByteStream() { int[] fileHeader = loadFileHeader(); byte[] infoHeader = new byte[BMPHeaderFixedSize]; try { inputStream.read(infoHeader); } catch (Exception e) { SWT.error(SWT.ERROR_IO, e); } int width = (infoHeader[4] & 0xFF) | ((infoHeader[5] & 0xFF) << 8) | ((infoHeader[6] & 0xFF) << 16) | ((infoHeader[7] & 0xFF) << 24); int height = (infoHeader[8] & 0xFF) | ((infoHeader[9] & 0xFF) << 8) | ((infoHeader[10] & 0xFF) << 16) | ((infoHeader[11] & 0xFF) << 24); int bitCount = (infoHeader[14] & 0xFF) | ((infoHeader[15] & 0xFF) << 8); PaletteData palette = loadPalette(infoHeader); if (inputStream.getPosition() < fileHeader[4]) { // Seek to the specified offset try { inputStream.skip(fileHeader[4] - inputStream.getPosition()); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } } byte[] data = loadData(infoHeader); this.compression = (infoHeader[16] & 0xFF) | ((infoHeader[17] & 0xFF) << 8) | ((infoHeader[18] & 0xFF) << 16) | ((infoHeader[19] & 0xFF) << 24); this.importantColors = (infoHeader[36] & 0xFF) | ((infoHeader[37] & 0xFF) << 8) | ((infoHeader[38] & 0xFF) << 16) | ((infoHeader[39] & 0xFF) << 24); // int xPelsPerMeter = (infoHeader[24] & 0xFF) | ((infoHeader[25] & 0xFF) << 8) | ((infoHeader[26] & 0xFF) << 16) | ((infoHeader[27] & 0xFF) << 24); // int yPelsPerMeter = (infoHeader[28] & 0xFF) | ((infoHeader[29] & 0xFF) << 8) | ((infoHeader[30] & 0xFF) << 16) | ((infoHeader[31] & 0xFF) << 24); int type = (this.compression == 1 /*BMP_RLE8_COMPRESSION*/) || (this.compression == 2 /*BMP_RLE4_COMPRESSION*/) ? SWT.IMAGE_BMP_RLE : SWT.IMAGE_BMP; return new ImageData[] { ImageData.internal_new( width, height, bitCount, palette, 4, data, 0, null, null, -1, -1, type, 0, 0, 0, 0) }; } PaletteData loadPalette(byte[] infoHeader) { int depth = (infoHeader[14] & 0xFF) | ((infoHeader[15] & 0xFF) << 8); if (depth <= 8) { int numColors = (infoHeader[32] & 0xFF) | ((infoHeader[33] & 0xFF) << 8) | ((infoHeader[34] & 0xFF) << 16) | ((infoHeader[35] & 0xFF) << 24); if (numColors == 0) { numColors = 1 << depth; } else { if (numColors > 256) numColors = 256; } byte[] buf = new byte[numColors * 4]; try { if (inputStream.read(buf) != buf.length) SWT.error(SWT.ERROR_INVALID_IMAGE); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } return paletteFromBytes(buf, numColors); } if (depth == 16) return new PaletteData(0x7C00, 0x3E0, 0x1F); if (depth == 24) return new PaletteData(0xFF, 0xFF00, 0xFF0000); return new PaletteData(0xFF00, 0xFF0000, 0xFF000000); } PaletteData paletteFromBytes(byte[] bytes, int numColors) { int bytesOffset = 0; RGB[] colors = new RGB[numColors]; for (int i = 0; i < numColors; i++) { colors[i] = new RGB(bytes[bytesOffset + 2] & 0xFF, bytes[bytesOffset + 1] & 0xFF, bytes[bytesOffset] & 0xFF); bytesOffset += 4; } return new PaletteData(colors); } /** * Answer a byte array containing the BMP representation of * the given device independent palette. */ static byte[] paletteToBytes(PaletteData pal) { int n = pal.colors == null ? 0 : (pal.colors.length < 256 ? pal.colors.length : 256); byte[] bytes = new byte[n * 4]; int offset = 0; for (int i = 0; i < n; i++) { RGB col = pal.colors[i]; bytes[offset] = (byte)col.blue; bytes[offset + 1] = (byte)col.green; bytes[offset + 2] = (byte)col.red; offset += 4; } return bytes; } void flipScanLines(byte[] data, int stride, int height) { int i1 = 0; int i2 = (height - 1) * stride; for (int i = 0; i < height / 2; i++) { for (int index = 0; index < stride; index++) { byte b = data[index + i1]; data[index + i1] = data[index + i2]; data[index + i2] = b; } i1 += stride; i2 -= stride; } } } static class WinICOFileFormat extends FileFormat { static final byte[] convertPad(byte[] data, int width, int height, int depth, int pad, int newPad) { if (pad == newPad) return data; int stride = (width * depth + 7) / 8; int bpl = (stride + (pad - 1)) / pad * pad; int newBpl = (stride + (newPad - 1)) / newPad * newPad; byte[] newData = new byte[height * newBpl]; int srcIndex = 0, destIndex = 0; for (int y = 0; y < height; y++) { System.arraycopy(data, srcIndex, newData, destIndex, newBpl); srcIndex += bpl; destIndex += newBpl; } return newData; } /** * Answer the size in bytes of the file representation of the given * icon */ int iconSize(ImageData i) { int shapeDataStride = (i.width * i.depth + 31) / 32 * 4; int maskDataStride = (i.width + 31) / 32 * 4; int dataSize = (shapeDataStride + maskDataStride) * i.height; int paletteSize = i.palette.colors != null ? i.palette.colors.length * 4 : 0; return WinBMPFileFormat.BMPHeaderFixedSize + paletteSize + dataSize; } @Override boolean isFileFormat(LEDataInputStream stream) { try { byte[] header = new byte[4]; stream.read(header); stream.unread(header); return header[0] == 0 && header[1] == 0 && header[2] == 1 && header[3] == 0; } catch (Exception e) { return false; } } boolean isValidIcon(ImageData i) { switch (i.depth) { case 1: case 4: case 8: if (i.palette.isDirect) return false; int size = i.palette.colors.length; return size == 2 || size == 16 || size == 32 || size == 256; case 24: case 32: return i.palette.isDirect; } return false; } int loadFileHeader(LEDataInputStream byteStream) { int[] fileHeader = new int[3]; try { fileHeader[0] = byteStream.readShort(); fileHeader[1] = byteStream.readShort(); fileHeader[2] = byteStream.readShort(); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } if ((fileHeader[0] != 0) || (fileHeader[1] != 1)) SWT.error(SWT.ERROR_INVALID_IMAGE); int numIcons = fileHeader[2]; if (numIcons <= 0) SWT.error(SWT.ERROR_INVALID_IMAGE); return numIcons; } int loadFileHeader(LEDataInputStream byteStream, boolean hasHeader) { int[] fileHeader = new int[3]; try { if (hasHeader) { fileHeader[0] = byteStream.readShort(); fileHeader[1] = byteStream.readShort(); } else { fileHeader[0] = 0; fileHeader[1] = 1; } fileHeader[2] = byteStream.readShort(); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } if ((fileHeader[0] != 0) || (fileHeader[1] != 1)) SWT.error(SWT.ERROR_INVALID_IMAGE); int numIcons = fileHeader[2]; if (numIcons <= 0) SWT.error(SWT.ERROR_INVALID_IMAGE); return numIcons; } @Override ImageData[] loadFromByteStream() { int numIcons = loadFileHeader(inputStream); int[][] headers = loadIconHeaders(numIcons); ImageData[] icons = new ImageData[headers.length]; for (int i = 0; i < icons.length; i++) { icons[i] = loadIcon(headers[i]); } return icons; } /** * Load one icon from the byte stream. */ ImageData loadIcon(int[] iconHeader) { byte[] infoHeader = loadInfoHeader(iconHeader); WinBMPFileFormat bmpFormat = new WinBMPFileFormat(); bmpFormat.inputStream = inputStream; PaletteData palette = bmpFormat.loadPalette(infoHeader); byte[] shapeData = bmpFormat.loadData(infoHeader); int width = (infoHeader[4] & 0xFF) | ((infoHeader[5] & 0xFF) << 8) | ((infoHeader[6] & 0xFF) << 16) | ((infoHeader[7] & 0xFF) << 24); int height = (infoHeader[8] & 0xFF) | ((infoHeader[9] & 0xFF) << 8) | ((infoHeader[10] & 0xFF) << 16) | ((infoHeader[11] & 0xFF) << 24); int depth = (infoHeader[14] & 0xFF) | ((infoHeader[15] & 0xFF) << 8); infoHeader[14] = 1; infoHeader[15] = 0; byte[] maskData = bmpFormat.loadData(infoHeader); maskData = convertPad(maskData, width, height, 1, 4, 2); bitInvertData(maskData, 0, maskData.length); return ImageData.internal_new( width, height, depth, palette, 4, shapeData, 2, maskData, null, -1, -1, SWT.IMAGE_ICO, 0, 0, 0, 0); } int[][] loadIconHeaders(int numIcons) { int[][] headers = new int[numIcons][7]; try { for (int i = 0; i < numIcons; i++) { headers[i][0] = inputStream.read(); headers[i][1] = inputStream.read(); headers[i][2] = inputStream.readShort(); headers[i][3] = inputStream.readShort(); headers[i][4] = inputStream.readShort(); headers[i][5] = inputStream.readInt(); headers[i][6] = inputStream.readInt(); } } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } return headers; } byte[] loadInfoHeader(int[] iconHeader) { int width = iconHeader[0]; int height = iconHeader[1]; int numColors = iconHeader[2]; // the number of colors is in the low byte, but the high byte must be 0 if (numColors == 0) numColors = 256; // this is specified: '00' represents '256' (0x100) colors if ((numColors != 2) && (numColors != 8) && (numColors != 16) && (numColors != 32) && (numColors != 256)) SWT.error(SWT.ERROR_INVALID_IMAGE); if (inputStream.getPosition() < iconHeader[6]) { // Seek to the specified offset try { inputStream.skip(iconHeader[6] - inputStream.getPosition()); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); return null; } } byte[] infoHeader = new byte[WinBMPFileFormat.BMPHeaderFixedSize]; try { inputStream.read(infoHeader); } catch (IOException e) { SWT.error(SWT.ERROR_IO, e); } if (((infoHeader[12] & 0xFF) | ((infoHeader[13] & 0xFF) << 8)) != 1) SWT.error(SWT.ERROR_INVALID_IMAGE); int infoWidth = (infoHeader[4] & 0xFF) | ((infoHeader[5] & 0xFF) << 8) | ((infoHeader[6] & 0xFF) << 16) | ((infoHeader[7] & 0xFF) << 24); int infoHeight = (infoHeader[8] & 0xFF) | ((infoHeader[9] & 0xFF) << 8) | ((infoHeader[10] & 0xFF) << 16) | ((infoHeader[11] & 0xFF) << 24); int bitCount = (infoHeader[14] & 0xFF) | ((infoHeader[15] & 0xFF) << 8); if (height == infoHeight && bitCount == 1) height /= 2; if (!((width == infoWidth) && (height * 2 == infoHeight) && (bitCount == 1 || bitCount == 4 || bitCount == 8 || bitCount == 24 || bitCount == 32))) SWT.error(SWT.ERROR_INVALID_IMAGE); infoHeader[8] = (byte)(height & 0xFF); infoHeader[9] = (byte)((height >> 8) & 0xFF); infoHeader[10] = (byte)((height >> 16) & 0xFF); infoHeader[11] = (byte)((height >> 24) & 0xFF); return infoHeader; } } static class SWT { public static final int IMAGE_ICO = 3; public static final int ERROR_IO = 39; public static final int ERROR_INVALID_IMAGE = 40; public static final int ERROR_NULL_ARGUMENT = 4; public static final int ERROR_INVALID_ARGUMENT = 5; public static final int ERROR_CANNOT_BE_ZERO = 7; public static final int IMAGE_UNDEFINED = -1; public static final int ERROR_UNSUPPORTED_DEPTH = 38; public static final int TRANSPARENCY_MASK = 1 << 1; public static final int ERROR_UNSUPPORTED_FORMAT = 42; public static final int TRANSPARENCY_ALPHA = 1 << 0; public static final int TRANSPARENCY_NONE = 0x0; public static final int TRANSPARENCY_PIXEL = 1 << 2; public static final int IMAGE_BMP = 0; public static final int IMAGE_BMP_RLE = 1; public static void error(int code) { throw new RuntimeException("Error "+code); } public static void error(int code, Throwable t) { throw new RuntimeException(t); } } }