///////////////////////////////////////////////////////////// // Flash Plugin and Player // Copyright (C) 1998 Olivier Debon // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License // as published by the Free Software Foundation; either version 2 // of the License, or (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. // /////////////////////////////////////////////////////////////// // Author : Olivier Debon // #include "swf.h" #ifdef RCSID static char *rcsid = "$Id: bitmap.cc,v 1.1.1.1 2002/01/25 22:14:58 kergoth Exp $"; #endif static unsigned char *inputData; // Class variables int Bitmap::haveTables = 0; struct jpeg_decompress_struct Bitmap::jpegObject; struct jpeg_source_mgr Bitmap::jpegSourceManager; MyErrorHandler Bitmap::jpegErrorMgr; Bitmap::Bitmap(long id, int level) : Character(BitmapType, id ) { pixels = NULL; alpha_buf = NULL; colormap = NULL; nbColors = 0; defLevel = level; } Bitmap::~Bitmap() { if (pixels) { delete[] pixels; } if (alpha_buf) { delete[] alpha_buf; } if (colormap) { delete colormap; } if (haveTables) { jpeg_destroy_decompress(&jpegObject); haveTables = 0; } } static void errorExit(j_common_ptr info) { (*info->err->output_message) (info); longjmp(((MyErrorHandler *)info->err)->setjmp_buffer, 1); } // Methods for Source data manager static void initSource(struct jpeg_decompress_struct *cInfo) { cInfo->src->bytes_in_buffer = 0; } static boolean fillInputBuffer(struct jpeg_decompress_struct *cInfo) { cInfo->src->next_input_byte = inputData; cInfo->src->bytes_in_buffer = 1; inputData++; return 1; } static void skipInputData(struct jpeg_decompress_struct *cInfo, long count) { cInfo->src->bytes_in_buffer = 0; inputData += count; } static boolean resyncToRestart(struct jpeg_decompress_struct *cInfo, int desired) { return jpeg_resync_to_restart(cInfo, desired); } static void termSource(struct jpeg_decompress_struct *cInfo) { } long Bitmap::getWidth() { return width; } long Bitmap::getHeight() { return height; } Color * Bitmap::getColormap(long *n) { if (n) *n = nbColors; return colormap; } unsigned char * Bitmap::getPixels() { return pixels; } // Read Tables and Compressed data to produce an image static int buildJpegAlpha(Bitmap *b, unsigned char *buffer) { z_stream stream; int status; unsigned char *data; data = new unsigned char[b->width*b->height]; if (data == NULL) return -1; stream.next_in = buffer; stream.avail_in = 1; stream.next_out = data; stream.avail_out = b->width*b->height; stream.zalloc = Z_NULL; stream.zfree = Z_NULL; status = inflateInit(&stream); while (1) { status = inflate(&stream, Z_SYNC_FLUSH) ; if (status == Z_STREAM_END) { break; } if (status != Z_OK) { printf("Zlib data error : %s\n", stream.msg); delete data; return -1; } stream.avail_in = 1; } inflateEnd(&stream); b->alpha_buf = data; return 0; } int Bitmap::buildFromJpegInterchangeData(unsigned char *stream, int read_alpha, long offset) { struct jpeg_decompress_struct cInfo; struct jpeg_source_mgr mySrcMgr; MyErrorHandler errorMgr; JSAMPROW buffer[1]; unsigned char *ptrPix; int stride; long n; #if PRINT&1 printf("flash: loading jpeg (interchange)\n"); #endif // Kludge to correct some corrupted files if (stream[1] == 0xd9 && stream[3] == 0xd8) { stream[3] = 0xd9; stream[1] = 0xd8; } // Setup error handler cInfo.err = jpeg_std_error(&errorMgr.pub); errorMgr.pub.error_exit = errorExit; if (setjmp(errorMgr.setjmp_buffer)) { // JPEG data Error jpeg_destroy_decompress(&cInfo); if (pixels) { delete[] pixels; pixels = NULL; } return -1; } // Set current stream pointer to stream inputData = stream; // Here it's Ok jpeg_create_decompress(&cInfo); // Setup source manager structure mySrcMgr.init_source = initSource; mySrcMgr.fill_input_buffer = fillInputBuffer; mySrcMgr.skip_input_data = skipInputData; mySrcMgr.resync_to_restart = resyncToRestart; mySrcMgr.term_source = termSource; // Set default source manager cInfo.src = &mySrcMgr; jpeg_read_header(&cInfo, FALSE); jpeg_read_header(&cInfo, TRUE); cInfo.quantize_colors = TRUE; // Create colormapped image jpeg_start_decompress(&cInfo); // Set objet dimensions height = cInfo.output_height; width = cInfo.output_width; bpl = width; pixels = new unsigned char [height*width]; if (pixels == NULL) { jpeg_finish_decompress(&cInfo); jpeg_destroy_decompress(&cInfo); return -1; } ptrPix = pixels; stride = cInfo.output_width * cInfo.output_components; buffer[0] = (JSAMPROW)malloc(stride); while (cInfo.output_scanline < cInfo.output_height) { jpeg_read_scanlines(&cInfo, buffer, 1); memcpy(ptrPix,buffer[0],stride); ptrPix+= stride; } free(buffer[0]); colormap = new Color[cInfo.actual_number_of_colors]; if (colormap == NULL) { delete pixels; jpeg_finish_decompress(&cInfo); jpeg_destroy_decompress(&cInfo); return -1; } nbColors = cInfo.actual_number_of_colors; for(n=0; n < nbColors; n++) { colormap[n].red = cInfo.colormap[0][n]; colormap[n].green = cInfo.colormap[1][n]; colormap[n].blue = cInfo.colormap[2][n]; } jpeg_finish_decompress(&cInfo); jpeg_destroy_decompress(&cInfo); if (read_alpha) { if (buildJpegAlpha(this, stream + offset) < 0) { return -1; } } return 0; } // Read JPEG image using pre-loaded Tables int Bitmap::buildFromJpegAbbreviatedData(unsigned char *stream) { JSAMPROW buffer[1]; unsigned char *ptrPix; int stride; long n; int status; #if PRINT&1 printf("flash: loading jpeg (abbreviated)\n"); #endif // Set current stream pointer to stream inputData = stream; // Error handler if (setjmp(jpegErrorMgr.setjmp_buffer)) { // JPEG data Error //jpeg_destroy_decompress(&jpegObject); if (pixels) { delete[] pixels; pixels = NULL; } return -1; } // Here it's ok jpeg_read_header(&jpegObject, TRUE); jpegObject.quantize_colors = TRUE; // Create colormapped image jpeg_start_decompress(&jpegObject); // Set objet dimensions height = jpegObject.output_height; width = jpegObject.output_width; bpl = width; pixels = new unsigned char [height*width]; if (pixels == NULL) { jpeg_finish_decompress(&jpegObject); return -1; } ptrPix = pixels; stride = jpegObject.output_width * jpegObject.output_components; buffer[0] = (JSAMPROW)malloc(stride); while (jpegObject.output_scanline < jpegObject.output_height) { status = jpeg_read_scanlines(&jpegObject, buffer, 1); memcpy(ptrPix,buffer[0],stride); ptrPix+= stride; } free(buffer[0]); colormap = new Color[jpegObject.actual_number_of_colors]; if (colormap == NULL) { jpeg_finish_decompress(&jpegObject); delete pixels; return -1; } nbColors = jpegObject.actual_number_of_colors; for(n=0; n < nbColors; n++) { colormap[n].red = jpegObject.colormap[0][n]; colormap[n].green = jpegObject.colormap[1][n]; colormap[n].blue = jpegObject.colormap[2][n]; } status = jpeg_finish_decompress(&jpegObject); return 0; } // Just init JPEG object and read JPEG Tables int Bitmap::readJpegTables(unsigned char *stream) { if (haveTables) { //Error, it has already been initialized return -1; } // Setup error handler jpegObject.err = jpeg_std_error(&jpegErrorMgr.pub); jpegErrorMgr.pub.error_exit = errorExit; if (setjmp(jpegErrorMgr.setjmp_buffer)) { // JPEG data Error jpeg_destroy_decompress(&jpegObject); return -1; } // Set current stream pointer to stream inputData = stream; // Here it's Ok jpeg_create_decompress(&jpegObject); // Setup source manager structure jpegSourceManager.init_source = initSource; jpegSourceManager.fill_input_buffer = fillInputBuffer; jpegSourceManager.skip_input_data = skipInputData; jpegSourceManager.resync_to_restart = resyncToRestart; jpegSourceManager.term_source = termSource; // Set default source manager jpegObject.src = &jpegSourceManager; jpeg_read_header(&jpegObject, FALSE); haveTables = 1; return 0; } int Bitmap::buildFromZlibData(unsigned char *buffer, int width, int height, int format, int tableSize, int tableHasAlpha) { z_stream stream; int status; unsigned char *data; int elementSize; #if PRINT&1 printf("flash: loading with zlib\n"); #endif this->width = width; this->height = height; this->bpl = width; if (tableHasAlpha) { elementSize = 4; // Cmap is RGBA } else { elementSize = 3; // Cmap is RGB } stream.next_in = buffer; stream.avail_in = 1; stream.zalloc = Z_NULL; stream.zfree = Z_NULL; tableSize++; // Uncompress Color Table if (format == 3) { unsigned char *colorTable; long n; // Ajust width for 32 bit padding width = (width+3)/4*4; this->width = width; this->bpl = width; depth = 1; colorTable = new unsigned char[tableSize*elementSize]; if (colorTable == NULL) { return -1; } stream.next_out = colorTable; stream.avail_out = tableSize*elementSize; inflateInit(&stream); while (1) { status = inflate(&stream, Z_SYNC_FLUSH); if (status == Z_STREAM_END) { break; } if (status != Z_OK) { printf("Zlib cmap error : %s\n", stream.msg); return -1; } stream.avail_in = 1; // Colormap if full if (stream.avail_out == 0) { break; } } nbColors = tableSize; colormap = new Color[nbColors]; if (colormap == NULL) { delete colorTable; return -1; } for(n=0; n < nbColors; n++) { colormap[n].red = colorTable[n*elementSize+0]; colormap[n].green = colorTable[n*elementSize+1]; colormap[n].blue = colorTable[n*elementSize+2]; if (tableHasAlpha) { colormap[n].alpha = colorTable[n*elementSize+3]; } } delete colorTable; } else if (format == 4) { depth = 2; width = (width+1)/2*2; this->bpl = width; } else if (format == 5) { depth = 4; } data = new unsigned char[depth*width*height]; if (data == NULL) { if (colormap) delete colormap; return -1; } stream.next_out = data; stream.avail_out = depth*width*height; if (format != 3) { status = inflateInit(&stream); } while (1) { status = inflate(&stream, Z_SYNC_FLUSH) ; if (status == Z_STREAM_END) { break; } if (status != Z_OK) { printf("Zlib data error : %s\n", stream.msg); delete data; return -1; } stream.avail_in = 1; } inflateEnd(&stream); pixels = new unsigned char [height*width]; if (pixels == NULL) { if (colormap) delete colormap; delete data; return -1; } if (format != 3) { int n,c; unsigned char r,g,b,a; unsigned char *ptr; r = g = b = a = 0; /* to supress warnings */ nbColors = 0; colormap = new Color[256]; if (colormap == NULL) { delete data; delete pixels; return -1; } memset(colormap, 0, 256 * sizeof(Color)); ptr = pixels; for(n=0; n < width*height*depth; n+=depth,ptr++) { switch (format) { case 4: a = 1; r = (data[n] & 0x78)<<1; g = ((data[n] & 0x03)<<6) | (data[n+1] & 0xc0)>>2; b = (data[n+1] & 0x1e)<<3; break; case 5: a = data[n]; // Reduce color dynamic range r = data[n+1]&0xe0; g = data[n+2]&0xe0; b = data[n+3]&0xe0; break; } for(c=0; c < nbColors; c++) { if (r == colormap[c].red && g == colormap[c].green && b == colormap[c].blue) { *ptr = c; break; } } if (c == nbColors) { if (nbColors == 256) continue; nbColors++; if (nbColors == 256) { //printf("Colormap entries exhausted. After %d scanned pixels\n", n/4); } colormap[c].alpha = a; colormap[c].red = r; colormap[c].green = g; colormap[c].blue = b; *ptr = c; } } } else { memcpy(pixels, data, width*height); if (tableHasAlpha) { int n; unsigned char *ptr, *alpha; alpha_buf = (unsigned char *)malloc(width*height); ptr = data; alpha = alpha_buf; for(n=0; n < width*height; n++, ptr++, alpha++) { *alpha = colormap[*ptr].alpha; } } } delete data; return 0; }