#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)
#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
typedef void (*filterPtrBPP)(int, CARDBPP *);
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);
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;
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;
}
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
#if (BPP == 8)
gcv.foreground = (appData.useBGR233) ?
BGR233ToPixel[fill_colour] : fill_colour;
#else
gcv.foreground = fill_colour;
#endif
XChangeGC(dpy, gc, GCForeground, &gcv);
XFillRectangle(dpy, desktopWin, gc, 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
if (comp_ctl > rfbTightMaxSubencoding) {
fprintf(stderr, "Tight encoding: bad subencoding value received.\n");
return False;
}
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;
}
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;
}
compressedLen = (int)ReadCompactLen();
if (compressedLen <= 0) {
fprintf(stderr, "Incorrect data received from the server.\n");
return False;
}
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;
}
bufferSize = BUFFER_SIZE * bitsPixel / (bitsPixel + BPP) & 0xFFFFFFFC;
buffer2 = &buffer[bufferSize];
if (rowSize > bufferSize) {
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)
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;
}
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++) {
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]);
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++) {
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]);
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
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;
}
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