/* * Copyright (C) 2000, 2001 Const Kaplinsky. All Rights Reserved. * * This 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 software 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 software; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, * USA. */ /* * tight.c - handle ``tight'' encoding. * * This file shouldn't be compiled directly. It is included multiple * times by rfbproto.c, each time with a different definition of the * macro BPP. For each value of BPP, this file defines a function * which handles a tight-encoded rectangle with BPP bits per pixel. * */ #define TIGHT_MIN_TO_COMPRESS 12 #define CARDBPP CONCAT2E(CARD,BPP) #define filterPtrBPP CONCAT2E(filterPtr,BPP) #define HandleTightBPP CONCAT2E(HandleTight,BPP) #define InitFilterCopyBPP CONCAT2E(InitFilterCopy,BPP) #define InitFilterPaletteBPP CONCAT2E(InitFilterPalette,BPP) #define InitFilterGradientBPP CONCAT2E(InitFilterGradient,BPP) #define FilterCopyBPP CONCAT2E(FilterCopy,BPP) #define FilterPaletteBPP CONCAT2E(FilterPalette,BPP) #define FilterGradientBPP CONCAT2E(FilterGradient,BPP) #define FillRectangleBPP CONCAT2E(FillRectangle,BPP) #if BPP != 8 #define DecompressJpegRectBPP CONCAT2E(DecompressJpegRect,BPP) #endif #ifndef RGB_TO_PIXEL #define RGB_TO_PIXEL(bpp,r,g,b) \ (((CARD##bpp)(r) & myFormat.redMax) << myFormat.redShift | \ ((CARD##bpp)(g) & myFormat.greenMax) << myFormat.greenShift | \ ((CARD##bpp)(b) & myFormat.blueMax) << myFormat.blueShift) #define RGB24_TO_PIXEL(bpp,r,g,b) \ ((((CARD##bpp)(r) & 0xFF) * myFormat.redMax + 127) / 255 \ << myFormat.redShift | \ (((CARD##bpp)(g) & 0xFF) * myFormat.greenMax + 127) / 255 \ << myFormat.greenShift | \ (((CARD##bpp)(b) & 0xFF) * myFormat.blueMax + 127) / 255 \ << myFormat.blueShift) #define RGB24_TO_PIXEL32(r,g,b) \ (((CARD32)(r) & 0xFF) << myFormat.redShift | \ ((CARD32)(g) & 0xFF) << myFormat.greenShift | \ ((CARD32)(b) & 0xFF) << myFormat.blueShift) #endif /* Type declarations */ typedef void (*filterPtrBPP)(int, CARDBPP *); /* Prototypes */ static int InitFilterCopyBPP (int rw, int rh); static int InitFilterPaletteBPP (int rw, int rh); static int InitFilterGradientBPP (int rw, int rh); static void FilterCopyBPP (int numRows, CARDBPP *destBuffer); static void FilterPaletteBPP (int numRows, CARDBPP *destBuffer); static void FilterGradientBPP (int numRows, CARDBPP *destBuffer); static Bool DecompressJpegRectBPP(int x, int y, int w, int h); /* Definitions */ static Bool HandleTightBPP (int rx, int ry, int rw, int rh) { CARDBPP fill_colour; XGCValues gcv; CARD8 comp_ctl; CARD8 filter_id; filterPtrBPP filterFn; z_streamp zs; char *buffer2; int err, stream_id, compressedLen, bitsPixel; int bufferSize, rowSize, numRows, portionLen, rowsProcessed, extraBytes; CARDBPP *rawData; if (!ReadFromRFBServer((char *)&comp_ctl, 1)) return False; /* Flush zlib streams if we are told by the server to do so. */ for (stream_id = 0; stream_id < 4; stream_id++) { if ((comp_ctl & 1) && zlibStreamActive[stream_id]) { if (inflateEnd (&zlibStream[stream_id]) != Z_OK && zlibStream[stream_id].msg != NULL) fprintf(stderr, "inflateEnd: %s\n", zlibStream[stream_id].msg); zlibStreamActive[stream_id] = False; } comp_ctl >>= 1; } /* Handle solid rectangles. */ if (comp_ctl == rfbTightFill) { #if BPP == 32 if (myFormat.depth == 24 && myFormat.redMax == 0xFF && myFormat.greenMax == 0xFF && myFormat.blueMax == 0xFF) { if (!ReadFromRFBServer(buffer, 3)) return False; fill_colour = RGB24_TO_PIXEL32(buffer[0], buffer[1], buffer[2]); } else { if (!ReadFromRFBServer((char*)&fill_colour, sizeof(fill_colour))) return False; } #else if (!ReadFromRFBServer((char*)&fill_colour, sizeof(fill_colour))) return False; #endif LockFramebuffer(); FillRectangleBPP(fill_colour, rx, ry, rw, rh); UnlockFramebuffer(); SyncScreenRegion(rx, ry, rw, rh); return True; } #if BPP == 8 if (comp_ctl == rfbTightJpeg) { fprintf(stderr, "Tight encoding: JPEG is not supported in 8 bpp mode.\n"); return False; } #else if (comp_ctl == rfbTightJpeg) { return DecompressJpegRectBPP(rx, ry, rw, rh); } #endif /* Quit on unsupported subencoding value. */ if (comp_ctl > rfbTightMaxSubencoding) { fprintf(stderr, "Tight encoding: bad subencoding value received.\n"); return False; } /* * Here primary compression mode handling begins. * Data was processed with optional filter + zlib compression. */ /* First, we should identify a filter to use. */ if ((comp_ctl & rfbTightExplicitFilter) != 0) { if (!ReadFromRFBServer((char*)&filter_id, 1)) return False; switch (filter_id) { case rfbTightFilterCopy: filterFn = FilterCopyBPP; bitsPixel = InitFilterCopyBPP(rw, rh); break; case rfbTightFilterPalette: filterFn = FilterPaletteBPP; bitsPixel = InitFilterPaletteBPP(rw, rh); break; case rfbTightFilterGradient: filterFn = FilterGradientBPP; bitsPixel = InitFilterGradientBPP(rw, rh); break; default: fprintf(stderr, "Tight encoding: unknown filter code received.\n"); return False; } } else { filterFn = FilterCopyBPP; bitsPixel = InitFilterCopyBPP(rw, rh); } if (bitsPixel == 0) { fprintf(stderr, "Tight encoding: error receiving palette.\n"); return False; } /* Determine if the data should be decompressed or just copied. */ rowSize = (rw * bitsPixel + 7) / 8; if (rh * rowSize < TIGHT_MIN_TO_COMPRESS) { if (!ReadFromRFBServer((char*)buffer, rh * rowSize)) return False; buffer2 = &buffer[TIGHT_MIN_TO_COMPRESS * 4]; filterFn(rh, (CARDBPP *)buffer2); CopyDataToScreen(buffer2, rx, ry, rw, rh); return True; } /* Read the length (1..3 bytes) of compressed data following. */ compressedLen = (int)ReadCompactLen(); if (compressedLen <= 0) { fprintf(stderr, "Incorrect data received from the server.\n"); return False; } /* Now let's initialize compression stream if needed. */ stream_id = comp_ctl & 0x03; zs = &zlibStream[stream_id]; if (!zlibStreamActive[stream_id]) { zs->zalloc = Z_NULL; zs->zfree = Z_NULL; zs->opaque = Z_NULL; err = inflateInit(zs); if (err != Z_OK) { if (zs->msg != NULL) fprintf(stderr, "InflateInit error: %s.\n", zs->msg); return False; } zlibStreamActive[stream_id] = True; } /* Read, decode and draw actual pixel data in a loop. */ bufferSize = BUFFER_SIZE * bitsPixel / (bitsPixel + BPP) & 0xFFFFFFFC; buffer2 = &buffer[bufferSize]; if (rowSize > bufferSize) { /* Should be impossible when BUFFER_SIZE >= 16384 */ fprintf(stderr, "Internal error: incorrect buffer size.\n"); return False; } rowsProcessed = 0; extraBytes = 0; while (compressedLen > 0) { if (compressedLen > ZLIB_BUFFER_SIZE) portionLen = ZLIB_BUFFER_SIZE; else portionLen = compressedLen; if (!ReadFromRFBServer((char*)zlib_buffer, portionLen)) return False; compressedLen -= portionLen; zs->next_in = (Bytef *)zlib_buffer; zs->avail_in = portionLen; do { zs->next_out = (Bytef *)&buffer[extraBytes]; zs->avail_out = bufferSize - extraBytes; err = inflate(zs, Z_SYNC_FLUSH); if (err == Z_BUF_ERROR) /* Input exhausted -- no problem. */ break; if (err != Z_OK && err != Z_STREAM_END) { if (zs->msg != NULL) { fprintf(stderr, "Inflate error: %s.\n", zs->msg); } else { fprintf(stderr, "Inflate error: %d.\n", err); } return False; } numRows = (bufferSize - zs->avail_out) / rowSize; filterFn(numRows, (CARDBPP *)buffer2); extraBytes = bufferSize - zs->avail_out - numRows * rowSize; if (extraBytes > 0) memcpy(buffer, &buffer[numRows * rowSize], extraBytes); CopyDataToScreen(buffer2, rx, ry + rowsProcessed, rw, numRows); rowsProcessed += numRows; } while (zs->avail_out == 0); } if (rowsProcessed != rh) { fprintf(stderr, "Incorrect number of scan lines after decompression.\n"); return False; } return True; } /*---------------------------------------------------------------------------- * * Filter stuff. * */ /* The following variables are defined in rfbproto.c: static Bool cutZeros; static int rectWidth, rectColors; static CARD8 tightPalette[256*4]; static CARD8 tightPrevRow[2048*3*sizeof(CARD16)]; */ static int InitFilterCopyBPP (int rw, int rh) { rectWidth = rw; #if BPP == 32 if (myFormat.depth == 24 && myFormat.redMax == 0xFF && myFormat.greenMax == 0xFF && myFormat.blueMax == 0xFF) { cutZeros = True; return 24; } else { cutZeros = False; } #endif return BPP; } static void FilterCopyBPP (int numRows, CARDBPP *dst) { #if BPP == 32 int x, y; if (cutZeros) { for (y = 0; y < numRows; y++) { for (x = 0; x < rectWidth; x++) { dst[y*rectWidth+x] = RGB24_TO_PIXEL32(buffer[(y*rectWidth+x)*3], buffer[(y*rectWidth+x)*3+1], buffer[(y*rectWidth+x)*3+2]); } } return; } #endif memcpy (dst, buffer, numRows * rectWidth * (BPP / 8)); } static int InitFilterGradientBPP (int rw, int rh) { int bits; bits = InitFilterCopyBPP(rw, rh); if (cutZeros) memset(tightPrevRow, 0, rw * 3); else memset(tightPrevRow, 0, rw * 3 * sizeof(CARD16)); return bits; } #if BPP == 32 static void FilterGradient24 (int numRows, CARD32 *dst) { int x, y, c; CARD8 thisRow[2048*3]; CARD8 pix[3]; int est[3]; for (y = 0; y < numRows; y++) { /* First pixel in a row */ for (c = 0; c < 3; c++) { pix[c] = tightPrevRow[c] + buffer[y*rectWidth*3+c]; thisRow[c] = pix[c]; } dst[y*rectWidth] = RGB24_TO_PIXEL32(pix[0], pix[1], pix[2]); /* Remaining pixels of a row */ for (x = 1; x < rectWidth; x++) { for (c = 0; c < 3; c++) { est[c] = (int)tightPrevRow[x*3+c] + (int)pix[c] - (int)tightPrevRow[(x-1)*3+c]; if (est[c] > 0xFF) { est[c] = 0xFF; } else if (est[c] < 0x00) { est[c] = 0x00; } pix[c] = (CARD8)est[c] + buffer[(y*rectWidth+x)*3+c]; thisRow[x*3+c] = pix[c]; } dst[y*rectWidth+x] = RGB24_TO_PIXEL32(pix[0], pix[1], pix[2]); } memcpy(tightPrevRow, thisRow, rectWidth * 3); } } #endif static void FilterGradientBPP (int numRows, CARDBPP *dst) { int x, y, c; CARDBPP *src = (CARDBPP *)buffer; CARD16 *thatRow = (CARD16 *)tightPrevRow; CARD16 thisRow[2048*3]; CARD16 pix[3]; CARD16 max[3]; int shift[3]; int est[3]; #if BPP == 32 if (cutZeros) { FilterGradient24(numRows, dst); return; } #endif max[0] = myFormat.redMax; max[1] = myFormat.greenMax; max[2] = myFormat.blueMax; shift[0] = myFormat.redShift; shift[1] = myFormat.greenShift; shift[2] = myFormat.blueShift; for (y = 0; y < numRows; y++) { /* First pixel in a row */ for (c = 0; c < 3; c++) { pix[c] = (CARD16)((src[y*rectWidth] >> shift[c]) + thatRow[c] & max[c]); thisRow[c] = pix[c]; } dst[y*rectWidth] = RGB_TO_PIXEL(BPP, pix[0], pix[1], pix[2]); /* Remaining pixels of a row */ for (x = 1; x < rectWidth; x++) { for (c = 0; c < 3; c++) { est[c] = (int)thatRow[x*3+c] + (int)pix[c] - (int)thatRow[(x-1)*3+c]; if (est[c] > (int)max[c]) { est[c] = (int)max[c]; } else if (est[c] < 0) { est[c] = 0; } pix[c] = (CARD16)((src[y*rectWidth+x] >> shift[c]) + est[c] & max[c]); thisRow[x*3+c] = pix[c]; } dst[y*rectWidth+x] = RGB_TO_PIXEL(BPP, pix[0], pix[1], pix[2]); } memcpy(thatRow, thisRow, rectWidth * 3 * sizeof(CARD16)); } } static int InitFilterPaletteBPP (int rw, int rh) { int i; CARD8 numColors; CARDBPP *palette = (CARDBPP *)tightPalette; rectWidth = rw; if (!ReadFromRFBServer((char*)&numColors, 1)) return 0; rectColors = (int)numColors; if (++rectColors < 2) return 0; #if BPP == 32 if (myFormat.depth == 24 && myFormat.redMax == 0xFF && myFormat.greenMax == 0xFF && myFormat.blueMax == 0xFF) { if (!ReadFromRFBServer((char*)&tightPalette, rectColors * 3)) return 0; for (i = rectColors - 1; i >= 0; i--) { palette[i] = RGB24_TO_PIXEL32(tightPalette[i*3], tightPalette[i*3+1], tightPalette[i*3+2]); } return (rectColors == 2) ? 1 : 8; } #endif if (!ReadFromRFBServer((char*)&tightPalette, rectColors * (BPP / 8))) return 0; return (rectColors == 2) ? 1 : 8; } static void FilterPaletteBPP (int numRows, CARDBPP *dst) { int x, y, b, w; CARD8 *src = (CARD8 *)buffer; CARDBPP *palette = (CARDBPP *)tightPalette; if (rectColors == 2) { w = (rectWidth + 7) / 8; for (y = 0; y < numRows; y++) { for (x = 0; x < rectWidth / 8; x++) { for (b = 7; b >= 0; b--) dst[y*rectWidth+x*8+7-b] = palette[src[y*w+x] >> b & 1]; } for (b = 7; b >= 8 - rectWidth % 8; b--) { dst[y*rectWidth+x*8+7-b] = palette[src[y*w+x] >> b & 1]; } } } else { for (y = 0; y < numRows; y++) for (x = 0; x < rectWidth; x++) dst[y*rectWidth+x] = palette[(int)src[y*rectWidth+x]]; } } #if BPP != 8 /*---------------------------------------------------------------------------- * * JPEG decompression. * */ /* The following variables are defined in rfbproto.c: static Bool jpegError; static struct jpeg_source_mgr jpegSrcManager; static JOCTET *jpegBufferPtr; static size_t *jpegBufferLen; */ static Bool DecompressJpegRectBPP(int x, int y, int w, int h) { struct jpeg_decompress_struct cinfo; struct jpeg_error_mgr jerr; int compressedLen; CARD8 *compressedData; CARDBPP *pixelPtr; JSAMPROW rowPointer[1]; int dx, dy; compressedLen = (int)ReadCompactLen(); if (compressedLen <= 0) { fprintf(stderr, "Incorrect data received from the server.\n"); return False; } if (compressedLen > MAX_JPEG_SIZE) { fprintf(stderr, "To large data announced by the server.\n"); return False; } compressedData = malloc(compressedLen); if (compressedData == NULL) { fprintf(stderr, "Memory allocation error.\n"); return False; } if (!ReadFromRFBServer((char*)compressedData, compressedLen)) { free(compressedData); return False; } cinfo.err = jpeg_std_error(&jerr); jpeg_create_decompress(&cinfo); JpegSetSrcManager(&cinfo, compressedData, compressedLen); jpeg_read_header(&cinfo, TRUE); cinfo.out_color_space = JCS_RGB; jpeg_start_decompress(&cinfo); if (cinfo.output_width != w || cinfo.output_height != h || cinfo.output_components != 3) { fprintf(stderr, "Tight Encoding: Wrong JPEG data received.\n"); jpeg_destroy_decompress(&cinfo); free(compressedData); return False; } rowPointer[0] = (JSAMPROW)buffer; dy = 0; while (cinfo.output_scanline < cinfo.output_height) { jpeg_read_scanlines(&cinfo, rowPointer, 1); if (jpegError) { break; } pixelPtr = (CARDBPP *)&buffer[BUFFER_SIZE / 2]; for (dx = 0; dx < w; dx++) { *pixelPtr++ = RGB24_TO_PIXEL(BPP, buffer[dx*3], buffer[dx*3+1], buffer[dx*3+2]); } CopyDataToScreen(&buffer[BUFFER_SIZE / 2], x, y + dy, w, 1); dy++; } if (!jpegError) jpeg_finish_decompress(&cinfo); jpeg_destroy_decompress(&cinfo); free(compressedData); return !jpegError; } #endif