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libtdevnc/libvncserver/turbo.c

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Add TurboVNC encoding support. TurboVNC is a variant of TightVNC that uses the same client/server protocol (RFB version 3.8t), and thus it is fully cross-compatible with TightVNC and TigerVNC (with one exception, which is noted below.) Both the TightVNC and TurboVNC encoders analyze each rectangle, pick out regions of solid color to send separately, and send the remaining subrectangles using mono, indexed color, JPEG, or raw encoding, depending on the number of colors in the subrectangle. However, TurboVNC uses a fundamentally different selection algorithm to determine the appropriate subencoding to use for each subrectangle. Thus, while it sends a protocol stream that can be decoded by any TightVNC-compatible viewer, the mix of subencoding types in this protocol stream will be different from those generated by a TightVNC server. The research that led to TurboVNC is described in the following report: http://www.virtualgl.org/pmwiki/uploads/About/tighttoturbo.pdf. In summary: 20 RFB captures, representing "common" 2D and 3D application workloads (the 3D workloads were run using VirtualGL), were studied using the TightVNC encoder in isolation. Some of the analysis features in the TightVNC encoder, such as smoothness detection, were found to generate a lot of CPU usage with little or no benefit in compression, so those features were disabled. JPEG encoding was accelerated using libjpeg-turbo (which achieves a 2-4x speedup over plain libjpeg on modern x86 or ARM processors.) Finally, the "palette threshold" (minimum number of colors that the subrectangle must have before it is compressed using JPEG or raw) was adjusted to account for the fact that JPEG encoding is now quite a bit faster (meaning that we can now use it more without a CPU penalty.) TurboVNC has additional optimizations, such as the ability to count colors and encode JPEG images directly from the framebuffer without first translating the pixels into RGB. The TurboVNC encoder compares quite favorably in terms of compression ratio with TightVNC and generally encodes a great deal faster (often an order of magnitude or more.) The version of the TurboVNC encoder included in this patch is roughly equivalent to the one found in version 0.6 of the Unix TurboVNC Server, with a few minor patches integrated from TurboVNC 1.1. TurboVNC 1.0 added multi-threading capabilities, which can be added in later if desired (at the expense of making libvncserver depend on libpthread.) Because TurboVNC uses a fundamentally different mix of subencodings than TightVNC, because it uses the identical protocol (and thus a viewer really has no idea whether it's talking to a TightVNC or TurboVNC server), and because it doesn't support rfbTightPng (and in fact conflicts with it-- see below), the TurboVNC and TightVNC encoders cannot be enabled simultaneously. Compatibility: In *most* cases, a TurboVNC-enabled viewer is fully compatible with a TightVNC server, and vice versa. TurboVNC supports pseudo-encodings for specifying a fine-grained (1-100) quality scale and specifying chrominance subsampling. If a TurboVNC viewer sends those to a TightVNC server, then the TightVNC server ignores them, so the TurboVNC viewer also sends the quality on a 0-9 scale that the TightVNC server can understand. Similarly, the TurboVNC server checks first for fine-grained quality and subsampling pseudo-encodings from the viewer, and failing to receive those, it then checks for the TightVNC 0-9 quality pseudo-encoding. There is one case in which the two systems are not compatible, and that is when a TightVNC or TigerVNC viewer requests compression level 0 without JPEG from a TurboVNC server. For performance reasons, this causes the TurboVNC server to send images directly to the viewer, bypassing Zlib. When the TurboVNC server does this, it also sets bits 7-4 in the compression control byte to rfbTightNoZlib (0x0A), which is unfortunately the same value as rfbTightPng. Older TightVNC viewers that don't handle PNG will assume that the stream is uncompressed but still encapsulated in a Zlib structure, whereas newer PNG-supporting TightVNC viewers will assume that the stream is PNG. In either case, the viewer will probably crash. Since most VNC viewers don't expose compression level 0 in the GUI, this is a relatively rare situation. Description of changes: configure.ac -- Added support for libjpeg-turbo. If passed an argument of --with-turbovnc, configure will now run (or, if cross-compiling, just link) a test program that determines whether the libjpeg library being used is libjpeg-turbo. libjpeg-turbo must be used when building the TurboVNC encoder, because the TurboVNC encoder relies on the libjpeg-turbo colorspace extensions in order to compress images directly out of the framebuffer (which may be, for instance, BGRA rather than RGB.) libjpeg-turbo can optionally be used with the TightVNC encoder as well, but the speedup will only be marginal (the report linked above explains why in more detail, but basically it's because of Amdahl's Law. The TightVNC encoder was designed with the assumption that JPEG had a very high CPU cost, and thus JPEG is used only sparingly.) -- Added a new configure variable, JPEG_LDFLAGS. This is necessitated by the fact that libjpeg-turbo often distributes libjpeg.a and libjpeg.so in /opt/libjpeg-turbo/lib32 or /opt/libjpeg-turbo/lib64, and many people prefer to statically link with it. Thus, more flexibility is needed than is provided by --with-jpeg. If JPEG_LDFLAGS is specified, then it overrides the changes to LDFLAGS enacted by --with-jpeg (but --with-jpeg is still used to set the include path.) The addition of JPEG_LDFLAGS necessitated replacing AC_CHECK_LIB with AC_LINK_IFELSE (because AC_CHECK_LIB automatically sets LIBS to -ljpeg, which is not what we want if we're, for instance, linking statically with libjpeg-turbo.) -- configure does not check for PNG support if TurboVNC encoding is enabled. This prevents the rfbSendRectEncodingTightPng() function from being compiled in, since the TurboVNC encoder doesn't (and can't) support it. common/turbojpeg.c, common/turbojpeg.h -- TurboJPEG is a simple API used to compress and decompress JPEG images in memory. It was originally implemented because it was desirable to use different types of underlying technologies to compress JPEG on different platforms (mediaLib on SPARC, Quicktime on PPC Macs, Intel Performance Primitives, etc.) These days, however, libjpeg-turbo is the only underlying technology used by TurboVNC, so TurboJPEG's purpose is largely just code simplicity and flexibility. Thus, since there is no real need for libvncserver to use any technology other than libjpeg-turbo for compressing JPEG, the TurboJPEG wrapper for libjpeg-turbo has been included in-tree so that libvncserver can be directly linked with libjpeg-turbo. This is convenient because many modern Linux distros (Fedora, Ubuntu, etc.) now ship libjpeg-turbo as their default libjpeg library. libvncserver/rfbserver.c -- Added logic to check for the TurboVNC fine-grained quality level and subsampling encodings and to map Tight (0-9) quality levels to appropriate fine-grained quality level and subsampling values if communicating with a TightVNC/TigerVNC viewer. libvncserver/turbo.c -- TurboVNC encoder (compiled instead of libvncserver/tight.c) rfb/rfb.h -- Added support for the TurboVNC subsampling level rfb/rfbproto.h -- Added constants for the TurboVNC fine quality level and subsampling encodings as well as the rfbTightNoZlib constant and notes on its usage.
12 years ago
/*
* turbo.c
*
* Routines to implement TurboVNC Encoding
*/
/*
* Copyright (C) 2010-2012 D. R. Commander. All Rights Reserved.
* Copyright (C) 2005-2008 Sun Microsystems, Inc. All Rights Reserved.
* Copyright (C) 2004 Landmark Graphics Corporation. All Rights Reserved.
* Copyright (C) 2000, 2001 Const Kaplinsky. All Rights Reserved.
* Copyright (C) 1999 AT&T Laboratories Cambridge. 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301,
* USA.
*/
#include <rfb/rfb.h>
#include "private.h"
#include "turbojpeg.h"
/* Note: The following constant should not be changed. */
#define TIGHT_MIN_TO_COMPRESS 12
/* The parameters below may be adjusted. */
#define MIN_SPLIT_RECT_SIZE 4096
#define MIN_SOLID_SUBRECT_SIZE 2048
#define MAX_SPLIT_TILE_SIZE 16
/*
* There is so much access of the Tight encoding static data buffers
* that we resort to using thread local storage instead of having
* per-client data.
*/
#if LIBVNCSERVER_HAVE_LIBPTHREAD && LIBVNCSERVER_HAVE_TLS && !defined(TLS) && defined(__linux__)
#define TLS __thread
#endif
#ifndef TLS
#define TLS
#endif
/* This variable is set on every rfbSendRectEncodingTight() call. */
static TLS rfbBool usePixelFormat24 = FALSE;
/* Compression level stuff. The following array contains various
encoder parameters for each of 10 compression levels (0..9).
Last three parameters correspond to JPEG quality levels (0..9). */
typedef struct TIGHT_CONF_s {
int maxRectSize, maxRectWidth;
int monoMinRectSize;
int idxZlibLevel, monoZlibLevel, rawZlibLevel;
int idxMaxColorsDivisor;
int palMaxColorsWithJPEG;
} TIGHT_CONF;
static TIGHT_CONF tightConf[3] = {
{ 65536, 2048, 6, 0, 0, 0, 4, 24 },
{ 65536, 2048, 32, 1, 1, 1, 96, 24 },
{ 65536, 2048, 32, 3, 3, 2, 96, 96 }
};
static TLS int compressLevel = 1;
static TLS int qualityLevel = 95;
static TLS int subsampLevel = TJ_444;
static const int subsampLevel2tjsubsamp[4] = {
TJ_444, TJ_420, TJ_422, TJ_GRAYSCALE
};
/* Stuff dealing with palettes. */
typedef struct COLOR_LIST_s {
struct COLOR_LIST_s *next;
int idx;
uint32_t rgb;
} COLOR_LIST;
typedef struct PALETTE_ENTRY_s {
COLOR_LIST *listNode;
int numPixels;
} PALETTE_ENTRY;
typedef struct PALETTE_s {
PALETTE_ENTRY entry[256];
COLOR_LIST *hash[256];
COLOR_LIST list[256];
} PALETTE;
/* TODO: move into rfbScreen struct */
static TLS int paletteNumColors = 0;
static TLS int paletteMaxColors = 0;
static TLS uint32_t monoBackground = 0;
static TLS uint32_t monoForeground = 0;
static TLS PALETTE palette;
/* Pointers to dynamically-allocated buffers. */
static TLS int tightBeforeBufSize = 0;
static TLS char *tightBeforeBuf = NULL;
static TLS int tightAfterBufSize = 0;
static TLS char *tightAfterBuf = NULL;
static TLS tjhandle j = NULL;
void rfbTightCleanup (rfbScreenInfoPtr screen)
{
if (tightBeforeBufSize) {
free (tightBeforeBuf);
tightBeforeBufSize = 0;
tightBeforeBuf = NULL;
}
if (tightAfterBufSize) {
free (tightAfterBuf);
tightAfterBufSize = 0;
tightAfterBuf = NULL;
}
if (j) tjDestroy(j);
}
/* Prototypes for static functions. */
static void FindBestSolidArea (rfbClientPtr cl, int x, int y, int w, int h,
uint32_t colorValue, int *w_ptr, int *h_ptr);
static void ExtendSolidArea (rfbClientPtr cl, int x, int y, int w, int h,
uint32_t colorValue,
int *x_ptr, int *y_ptr, int *w_ptr, int *h_ptr);
static rfbBool CheckSolidTile (rfbClientPtr cl, int x, int y, int w, int h,
uint32_t *colorPtr, rfbBool needSameColor);
static rfbBool CheckSolidTile8 (rfbClientPtr cl, int x, int y, int w, int h,
uint32_t *colorPtr, rfbBool needSameColor);
static rfbBool CheckSolidTile16 (rfbClientPtr cl, int x, int y, int w, int h,
uint32_t *colorPtr, rfbBool needSameColor);
static rfbBool CheckSolidTile32 (rfbClientPtr cl, int x, int y, int w, int h,
uint32_t *colorPtr, rfbBool needSameColor);
static rfbBool SendRectSimple (rfbClientPtr cl, int x, int y, int w, int h);
static rfbBool SendSubrect (rfbClientPtr cl, int x, int y, int w, int h);
static rfbBool SendTightHeader (rfbClientPtr cl, int x, int y, int w, int h);
static rfbBool SendSolidRect (rfbClientPtr cl);
static rfbBool SendMonoRect (rfbClientPtr cl, int w, int h);
static rfbBool SendIndexedRect (rfbClientPtr cl, int w, int h);
static rfbBool SendFullColorRect (rfbClientPtr cl, int w, int h);
static rfbBool CompressData (rfbClientPtr cl, int streamId, int dataLen,
int zlibLevel, int zlibStrategy);
static rfbBool SendCompressedData (rfbClientPtr cl, char *buf,
int compressedLen);
static void FillPalette8 (int count);
static void FillPalette16 (int count);
static void FillPalette32 (int count);
static void FastFillPalette16 (rfbClientPtr cl, uint16_t *data, int w,
int pitch, int h);
static void FastFillPalette32 (rfbClientPtr cl, uint32_t *data, int w,
int pitch, int h);
static void PaletteReset (void);
static int PaletteInsert (uint32_t rgb, int numPixels, int bpp);
static void Pack24 (rfbClientPtr cl, char *buf, rfbPixelFormat *fmt,
int count);
static void EncodeIndexedRect16 (uint8_t *buf, int count);
static void EncodeIndexedRect32 (uint8_t *buf, int count);
static void EncodeMonoRect8 (uint8_t *buf, int w, int h);
static void EncodeMonoRect16 (uint8_t *buf, int w, int h);
static void EncodeMonoRect32 (uint8_t *buf, int w, int h);
static rfbBool SendJpegRect (rfbClientPtr cl, int x, int y, int w, int h,
int quality);
/*
* Tight encoding implementation.
*/
int
rfbNumCodedRectsTight(rfbClientPtr cl,
int x,
int y,
int w,
int h)
{
int maxRectSize, maxRectWidth;
int subrectMaxWidth, subrectMaxHeight;
/* No matter how many rectangles we will send if LastRect markers
are used to terminate rectangle stream. */
if (cl->enableLastRectEncoding && w * h >= MIN_SPLIT_RECT_SIZE)
return 0;
maxRectSize = tightConf[compressLevel].maxRectSize;
maxRectWidth = tightConf[compressLevel].maxRectWidth;
if (w > maxRectWidth || w * h > maxRectSize) {
subrectMaxWidth = (w > maxRectWidth) ? maxRectWidth : w;
subrectMaxHeight = maxRectSize / subrectMaxWidth;
return (((w - 1) / maxRectWidth + 1) *
((h - 1) / subrectMaxHeight + 1));
} else {
return 1;
}
}
rfbBool
rfbSendRectEncodingTight(rfbClientPtr cl,
int x,
int y,
int w,
int h)
{
int nMaxRows;
uint32_t colorValue;
int dx, dy, dw, dh;
int x_best, y_best, w_best, h_best;
char *fbptr;
rfbSendUpdateBuf(cl);
compressLevel = cl->tightCompressLevel;
qualityLevel = cl->tightQualityLevel;
subsampLevel = cl->tightSubsampLevel;
/* We only allow compression levels that have a demonstrable performance
benefit. CL 0 with JPEG reduces CPU usage for workloads that have low
numbers of unique colors, but the same thing can be accomplished by
using CL 0 without JPEG (AKA "Lossless Tight.") CL 2 is a mixed bag.
It can be shown to reduce bandwidth (and commensurately increase CPU
usage) by typically 30-40% relative to CL 1, but only when it is used in
conjunction with high-quality JPEG, and only on workloads that have low
numbers of unique colors. Increasing the amount of Zlib compression
beyond CL 2 cannot be shown to provide any significant bandwidth savings
except in very rare corner cases that are not performance-critical to
begin with, and higher Zlib levels increase CPU usage exponentially. */
if (qualityLevel != -1) {
if (compressLevel < 1) compressLevel = 1;
if (compressLevel > 2) compressLevel = 2;
}
/* With JPEG disabled, increasing the Zlib compression level beyond CL 1
offers no significant bandwidth savings, and the CPU usage starts to
increase exponentially. */
else if (compressLevel > 1) compressLevel = 1;
if ( cl->format.depth == 24 && cl->format.redMax == 0xFF &&
cl->format.greenMax == 0xFF && cl->format.blueMax == 0xFF ) {
usePixelFormat24 = TRUE;
} else {
usePixelFormat24 = FALSE;
}
if (!cl->enableLastRectEncoding || w * h < MIN_SPLIT_RECT_SIZE)
return SendRectSimple(cl, x, y, w, h);
/* Make sure we can write at least one pixel into tightBeforeBuf. */
if (tightBeforeBufSize < 4) {
tightBeforeBufSize = 4;
if (tightBeforeBuf == NULL)
tightBeforeBuf = (char *)malloc(tightBeforeBufSize);
else
tightBeforeBuf = (char *)realloc(tightBeforeBuf,
tightBeforeBufSize);
}
/* Calculate maximum number of rows in one non-solid rectangle. */
{
int maxRectSize, maxRectWidth, nMaxWidth;
maxRectSize = tightConf[compressLevel].maxRectSize;
maxRectWidth = tightConf[compressLevel].maxRectWidth;
nMaxWidth = (w > maxRectWidth) ? maxRectWidth : w;
nMaxRows = maxRectSize / nMaxWidth;
}
/* Try to find large solid-color areas and send them separately. */
for (dy = y; dy < y + h; dy += MAX_SPLIT_TILE_SIZE) {
/* If a rectangle becomes too large, send its upper part now. */
if (dy - y >= nMaxRows) {
if (!SendRectSimple(cl, x, y, w, nMaxRows))
return 0;
y += nMaxRows;
h -= nMaxRows;
}
dh = (dy + MAX_SPLIT_TILE_SIZE <= y + h) ?
MAX_SPLIT_TILE_SIZE : (y + h - dy);
for (dx = x; dx < x + w; dx += MAX_SPLIT_TILE_SIZE) {
dw = (dx + MAX_SPLIT_TILE_SIZE <= x + w) ?
MAX_SPLIT_TILE_SIZE : (x + w - dx);
if (CheckSolidTile(cl, dx, dy, dw, dh, &colorValue, FALSE)) {
if (subsampLevel == TJ_GRAYSCALE && qualityLevel != -1) {
uint32_t r = (colorValue >> 16) & 0xFF;
uint32_t g = (colorValue >> 8) & 0xFF;
uint32_t b = (colorValue) & 0xFF;
double y = (0.257 * (double)r) + (0.504 * (double)g)
+ (0.098 * (double)b) + 16.;
colorValue = (int)y + (((int)y) << 8) + (((int)y) << 16);
}
/* Get dimensions of solid-color area. */
FindBestSolidArea(cl, dx, dy, w - (dx - x), h - (dy - y),
colorValue, &w_best, &h_best);
/* Make sure a solid rectangle is large enough
(or the whole rectangle is of the same color). */
if ( w_best * h_best != w * h &&
w_best * h_best < MIN_SOLID_SUBRECT_SIZE )
continue;
/* Try to extend solid rectangle to maximum size. */
x_best = dx; y_best = dy;
ExtendSolidArea(cl, x, y, w, h, colorValue,
&x_best, &y_best, &w_best, &h_best);
/* Send rectangles at top and left to solid-color area. */
if ( y_best != y &&
!SendRectSimple(cl, x, y, w, y_best-y) )
return FALSE;
if ( x_best != x &&
!rfbSendRectEncodingTight(cl, x, y_best,
x_best-x, h_best) )
return FALSE;
/* Send solid-color rectangle. */
if (!SendTightHeader(cl, x_best, y_best, w_best, h_best))
return FALSE;
fbptr = (cl->scaledScreen->frameBuffer +
(cl->scaledScreen->paddedWidthInBytes * y_best) +
(x_best * (cl->scaledScreen->bitsPerPixel / 8)));
(*cl->translateFn)(cl->translateLookupTable, &cl->screen->serverFormat,
&cl->format, fbptr, tightBeforeBuf,
cl->scaledScreen->paddedWidthInBytes, 1, 1);
if (!SendSolidRect(cl))
return FALSE;
/* Send remaining rectangles (at right and bottom). */
if ( x_best + w_best != x + w &&
!rfbSendRectEncodingTight(cl, x_best + w_best, y_best,
w - (x_best-x) - w_best, h_best) )
return FALSE;
if ( y_best + h_best != y + h &&
!rfbSendRectEncodingTight(cl, x, y_best + h_best,
w, h - (y_best-y) - h_best) )
return FALSE;
/* Return after all recursive calls are done. */
return TRUE;
}
}
}
/* No suitable solid-color rectangles found. */
return SendRectSimple(cl, x, y, w, h);
}
static void
FindBestSolidArea(rfbClientPtr cl,
int x,
int y,
int w,
int h,
uint32_t colorValue,
int *w_ptr,
int *h_ptr)
{
int dx, dy, dw, dh;
int w_prev;
int w_best = 0, h_best = 0;
w_prev = w;
for (dy = y; dy < y + h; dy += MAX_SPLIT_TILE_SIZE) {
dh = (dy + MAX_SPLIT_TILE_SIZE <= y + h) ?
MAX_SPLIT_TILE_SIZE : (y + h - dy);
dw = (w_prev > MAX_SPLIT_TILE_SIZE) ?
MAX_SPLIT_TILE_SIZE : w_prev;
if (!CheckSolidTile(cl, x, dy, dw, dh, &colorValue, TRUE))
break;
for (dx = x + dw; dx < x + w_prev;) {
dw = (dx + MAX_SPLIT_TILE_SIZE <= x + w_prev) ?
MAX_SPLIT_TILE_SIZE : (x + w_prev - dx);
if (!CheckSolidTile(cl, dx, dy, dw, dh, &colorValue, TRUE))
break;
dx += dw;
}
w_prev = dx - x;
if (w_prev * (dy + dh - y) > w_best * h_best) {
w_best = w_prev;
h_best = dy + dh - y;
}
}
*w_ptr = w_best;
*h_ptr = h_best;
}
static void
ExtendSolidArea(rfbClientPtr cl,
int x,
int y,
int w,
int h,
uint32_t colorValue,
int *x_ptr,
int *y_ptr,
int *w_ptr,
int *h_ptr)
{
int cx, cy;
/* Try to extend the area upwards. */
for ( cy = *y_ptr - 1;
cy >= y && CheckSolidTile(cl, *x_ptr, cy, *w_ptr, 1, &colorValue, TRUE);
cy-- );
*h_ptr += *y_ptr - (cy + 1);
*y_ptr = cy + 1;
/* ... downwards. */
for ( cy = *y_ptr + *h_ptr;
cy < y + h &&
CheckSolidTile(cl, *x_ptr, cy, *w_ptr, 1, &colorValue, TRUE);
cy++ );
*h_ptr += cy - (*y_ptr + *h_ptr);
/* ... to the left. */
for ( cx = *x_ptr - 1;
cx >= x && CheckSolidTile(cl, cx, *y_ptr, 1, *h_ptr, &colorValue, TRUE);
cx-- );
*w_ptr += *x_ptr - (cx + 1);
*x_ptr = cx + 1;
/* ... to the right. */
for ( cx = *x_ptr + *w_ptr;
cx < x + w &&
CheckSolidTile(cl, cx, *y_ptr, 1, *h_ptr, &colorValue, TRUE);
cx++ );
*w_ptr += cx - (*x_ptr + *w_ptr);
}
/*
* Check if a rectangle is all of the same color. If needSameColor is
* set to non-zero, then also check that its color equals to the
* *colorPtr value. The result is 1 if the test is successfull, and in
* that case new color will be stored in *colorPtr.
*/
static rfbBool CheckSolidTile(rfbClientPtr cl, int x, int y, int w, int h, uint32_t* colorPtr, rfbBool needSameColor)
{
switch(cl->screen->serverFormat.bitsPerPixel) {
case 32:
return CheckSolidTile32(cl, x, y, w, h, colorPtr, needSameColor);
case 16:
return CheckSolidTile16(cl, x, y, w, h, colorPtr, needSameColor);
default:
return CheckSolidTile8(cl, x, y, w, h, colorPtr, needSameColor);
}
}
#define DEFINE_CHECK_SOLID_FUNCTION(bpp) \
\
static rfbBool \
CheckSolidTile##bpp(rfbClientPtr cl, int x, int y, int w, int h, \
uint32_t* colorPtr, rfbBool needSameColor) \
{ \
uint##bpp##_t *fbptr; \
uint##bpp##_t colorValue; \
int dx, dy; \
\
fbptr = (uint##bpp##_t *)&cl->scaledScreen->frameBuffer \
[y * cl->scaledScreen->paddedWidthInBytes + x * (bpp/8)]; \
\
colorValue = *fbptr; \
if (needSameColor && (uint32_t)colorValue != *colorPtr) \
return FALSE; \
\
for (dy = 0; dy < h; dy++) { \
for (dx = 0; dx < w; dx++) { \
if (colorValue != fbptr[dx]) \
return FALSE; \
} \
fbptr = (uint##bpp##_t *)((uint8_t *)fbptr \
+ cl->scaledScreen->paddedWidthInBytes); \
} \
\
*colorPtr = (uint32_t)colorValue; \
return TRUE; \
}
DEFINE_CHECK_SOLID_FUNCTION(8)
DEFINE_CHECK_SOLID_FUNCTION(16)
DEFINE_CHECK_SOLID_FUNCTION(32)
static rfbBool
SendRectSimple(rfbClientPtr cl, int x, int y, int w, int h)
{
int maxBeforeSize, maxAfterSize;
int maxRectSize, maxRectWidth;
int subrectMaxWidth, subrectMaxHeight;
int dx, dy;
int rw, rh;
maxRectSize = tightConf[compressLevel].maxRectSize;
maxRectWidth = tightConf[compressLevel].maxRectWidth;
maxBeforeSize = maxRectSize * (cl->format.bitsPerPixel / 8);
maxAfterSize = maxBeforeSize + (maxBeforeSize + 99) / 100 + 12;
if (tightBeforeBufSize < maxBeforeSize) {
tightBeforeBufSize = maxBeforeSize;
if (tightBeforeBuf == NULL)
tightBeforeBuf = (char *)malloc(tightBeforeBufSize);
else
tightBeforeBuf = (char *)realloc(tightBeforeBuf,
tightBeforeBufSize);
}
if (tightAfterBufSize < maxAfterSize) {
tightAfterBufSize = maxAfterSize;
if (tightAfterBuf == NULL)
tightAfterBuf = (char *)malloc(tightAfterBufSize);
else
tightAfterBuf = (char *)realloc(tightAfterBuf,
tightAfterBufSize);
}
if (w > maxRectWidth || w * h > maxRectSize) {
subrectMaxWidth = (w > maxRectWidth) ? maxRectWidth : w;
subrectMaxHeight = maxRectSize / subrectMaxWidth;
for (dy = 0; dy < h; dy += subrectMaxHeight) {
for (dx = 0; dx < w; dx += maxRectWidth) {
rw = (dx + maxRectWidth < w) ? maxRectWidth : w - dx;
rh = (dy + subrectMaxHeight < h) ? subrectMaxHeight : h - dy;
if (!SendSubrect(cl, x + dx, y + dy, rw, rh))
return FALSE;
}
}
} else {
if (!SendSubrect(cl, x, y, w, h))
return FALSE;
}
return TRUE;
}
static rfbBool
SendSubrect(rfbClientPtr cl,
int x,
int y,
int w,
int h)
{
char *fbptr;
rfbBool success = FALSE;
/* Send pending data if there is more than 128 bytes. */
if (cl->ublen > 128) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
if (!SendTightHeader(cl, x, y, w, h))
return FALSE;
fbptr = (cl->scaledScreen->frameBuffer
+ (cl->scaledScreen->paddedWidthInBytes * y)
+ (x * (cl->scaledScreen->bitsPerPixel / 8)));
if (subsampLevel == TJ_GRAYSCALE && qualityLevel != -1)
return SendJpegRect(cl, x, y, w, h, qualityLevel);
paletteMaxColors = w * h / tightConf[compressLevel].idxMaxColorsDivisor;
if(qualityLevel != -1)
paletteMaxColors = tightConf[compressLevel].palMaxColorsWithJPEG;
if ( paletteMaxColors < 2 &&
w * h >= tightConf[compressLevel].monoMinRectSize ) {
paletteMaxColors = 2;
}
if (cl->format.bitsPerPixel == cl->screen->serverFormat.bitsPerPixel &&
cl->format.redMax == cl->screen->serverFormat.redMax &&
cl->format.greenMax == cl->screen->serverFormat.greenMax &&
cl->format.blueMax == cl->screen->serverFormat.blueMax &&
cl->format.bitsPerPixel >= 16) {
/* This is so we can avoid translating the pixels when compressing
with JPEG, since it is unnecessary */
switch (cl->format.bitsPerPixel) {
case 16:
FastFillPalette16(cl, (uint16_t *)fbptr, w,
cl->scaledScreen->paddedWidthInBytes / 2, h);
break;
default:
FastFillPalette32(cl, (uint32_t *)fbptr, w,
cl->scaledScreen->paddedWidthInBytes / 4, h);
}
if(paletteNumColors != 0 || qualityLevel == -1) {
(*cl->translateFn)(cl->translateLookupTable,
&cl->screen->serverFormat, &cl->format, fbptr,
tightBeforeBuf,
cl->scaledScreen->paddedWidthInBytes, w, h);
}
}
else {
(*cl->translateFn)(cl->translateLookupTable, &cl->screen->serverFormat,
&cl->format, fbptr, tightBeforeBuf,
cl->scaledScreen->paddedWidthInBytes, w, h);
switch (cl->format.bitsPerPixel) {
case 8:
FillPalette8(w * h);
break;
case 16:
FillPalette16(w * h);
break;
default:
FillPalette32(w * h);
}
}
switch (paletteNumColors) {
case 0:
/* Truecolor image */
if (qualityLevel != -1) {
success = SendJpegRect(cl, x, y, w, h, qualityLevel);
} else {
success = SendFullColorRect(cl, w, h);
}
break;
case 1:
/* Solid rectangle */
success = SendSolidRect(cl);
break;
case 2:
/* Two-color rectangle */
success = SendMonoRect(cl, w, h);
break;
default:
/* Up to 256 different colors */
success = SendIndexedRect(cl, w, h);
}
return success;
}
static rfbBool
SendTightHeader(rfbClientPtr cl,
int x,
int y,
int w,
int h)
{
rfbFramebufferUpdateRectHeader rect;
if (cl->ublen + sz_rfbFramebufferUpdateRectHeader > UPDATE_BUF_SIZE) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
rect.r.x = Swap16IfLE(x);
rect.r.y = Swap16IfLE(y);
rect.r.w = Swap16IfLE(w);
rect.r.h = Swap16IfLE(h);
rect.encoding = Swap32IfLE(rfbEncodingTight);
memcpy(&cl->updateBuf[cl->ublen], (char *)&rect,
sz_rfbFramebufferUpdateRectHeader);
cl->ublen += sz_rfbFramebufferUpdateRectHeader;
rfbStatRecordEncodingSent(cl, rfbEncodingTight,
sz_rfbFramebufferUpdateRectHeader,
sz_rfbFramebufferUpdateRectHeader
+ w * (cl->format.bitsPerPixel / 8) * h);
return TRUE;
}
/*
* Subencoding implementations.
*/
static rfbBool
SendSolidRect(rfbClientPtr cl)
{
int len;
if (usePixelFormat24) {
Pack24(cl, tightBeforeBuf, &cl->format, 1);
len = 3;
} else
len = cl->format.bitsPerPixel / 8;
if (cl->ublen + 1 + len > UPDATE_BUF_SIZE) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
cl->updateBuf[cl->ublen++] = (char)(rfbTightFill << 4);
memcpy (&cl->updateBuf[cl->ublen], tightBeforeBuf, len);
cl->ublen += len;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, len + 1);
return TRUE;
}
static rfbBool
SendMonoRect(rfbClientPtr cl,
int w,
int h)
{
int streamId = 1;
int paletteLen, dataLen;
if ( cl->ublen + TIGHT_MIN_TO_COMPRESS + 6 +
2 * cl->format.bitsPerPixel / 8 > UPDATE_BUF_SIZE ) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
/* Prepare tight encoding header. */
dataLen = (w + 7) / 8;
dataLen *= h;
if (tightConf[compressLevel].monoZlibLevel == 0)
cl->updateBuf[cl->ublen++] =
(char)((rfbTightNoZlib | rfbTightExplicitFilter) << 4);
else
cl->updateBuf[cl->ublen++] = (streamId | rfbTightExplicitFilter) << 4;
cl->updateBuf[cl->ublen++] = rfbTightFilterPalette;
cl->updateBuf[cl->ublen++] = 1;
/* Prepare palette, convert image. */
switch (cl->format.bitsPerPixel) {
case 32:
EncodeMonoRect32((uint8_t *)tightBeforeBuf, w, h);
((uint32_t *)tightAfterBuf)[0] = monoBackground;
((uint32_t *)tightAfterBuf)[1] = monoForeground;
if (usePixelFormat24) {
Pack24(cl, tightAfterBuf, &cl->format, 2);
paletteLen = 6;
} else
paletteLen = 8;
memcpy(&cl->updateBuf[cl->ublen], tightAfterBuf, paletteLen);
cl->ublen += paletteLen;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 3 + paletteLen);
break;
case 16:
EncodeMonoRect16((uint8_t *)tightBeforeBuf, w, h);
((uint16_t *)tightAfterBuf)[0] = (uint16_t)monoBackground;
((uint16_t *)tightAfterBuf)[1] = (uint16_t)monoForeground;
memcpy(&cl->updateBuf[cl->ublen], tightAfterBuf, 4);
cl->ublen += 4;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 7);
break;
default:
EncodeMonoRect8((uint8_t *)tightBeforeBuf, w, h);
cl->updateBuf[cl->ublen++] = (char)monoBackground;
cl->updateBuf[cl->ublen++] = (char)monoForeground;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 5);
}
return CompressData(cl, streamId, dataLen,
tightConf[compressLevel].monoZlibLevel,
Z_DEFAULT_STRATEGY);
}
static rfbBool
SendIndexedRect(rfbClientPtr cl,
int w,
int h)
{
int streamId = 2;
int i, entryLen;
if ( cl->ublen + TIGHT_MIN_TO_COMPRESS + 6 +
paletteNumColors * cl->format.bitsPerPixel / 8 >
UPDATE_BUF_SIZE ) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
/* Prepare tight encoding header. */
if (tightConf[compressLevel].idxZlibLevel == 0)
cl->updateBuf[cl->ublen++] =
(char)((rfbTightNoZlib | rfbTightExplicitFilter) << 4);
else
cl->updateBuf[cl->ublen++] = (streamId | rfbTightExplicitFilter) << 4;
cl->updateBuf[cl->ublen++] = rfbTightFilterPalette;
cl->updateBuf[cl->ublen++] = (char)(paletteNumColors - 1);
/* Prepare palette, convert image. */
switch (cl->format.bitsPerPixel) {
case 32:
EncodeIndexedRect32((uint8_t *)tightBeforeBuf, w * h);
for (i = 0; i < paletteNumColors; i++) {
((uint32_t *)tightAfterBuf)[i] =
palette.entry[i].listNode->rgb;
}
if (usePixelFormat24) {
Pack24(cl, tightAfterBuf, &cl->format, paletteNumColors);
entryLen = 3;
} else
entryLen = 4;
memcpy(&cl->updateBuf[cl->ublen], tightAfterBuf,
paletteNumColors * entryLen);
cl->ublen += paletteNumColors * entryLen;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight,
3 + paletteNumColors * entryLen);
break;
case 16:
EncodeIndexedRect16((uint8_t *)tightBeforeBuf, w * h);
for (i = 0; i < paletteNumColors; i++) {
((uint16_t *)tightAfterBuf)[i] =
(uint16_t)palette.entry[i].listNode->rgb;
}
memcpy(&cl->updateBuf[cl->ublen], tightAfterBuf, paletteNumColors * 2);
cl->ublen += paletteNumColors * 2;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight,
3 + paletteNumColors * 2);
break;
default:
return FALSE; /* Should never happen. */
}
return CompressData(cl, streamId, w * h,
tightConf[compressLevel].idxZlibLevel,
Z_DEFAULT_STRATEGY);
}
static rfbBool
SendFullColorRect(rfbClientPtr cl,
int w,
int h)
{
int streamId = 0;
int len;
if (cl->ublen + TIGHT_MIN_TO_COMPRESS + 1 > UPDATE_BUF_SIZE) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
if (tightConf[compressLevel].rawZlibLevel == 0)
cl->updateBuf[cl->ublen++] = (char)(rfbTightNoZlib << 4);
else
cl->updateBuf[cl->ublen++] = 0x00; /* stream id = 0, no flushing, no filter */
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 1);
if (usePixelFormat24) {
Pack24(cl, tightBeforeBuf, &cl->format, w * h);
len = 3;
} else
len = cl->format.bitsPerPixel / 8;
return CompressData(cl, streamId, w * h * len,
tightConf[compressLevel].rawZlibLevel,
Z_DEFAULT_STRATEGY);
}
static rfbBool
CompressData(rfbClientPtr cl,
int streamId,
int dataLen,
int zlibLevel,
int zlibStrategy)
{
z_streamp pz;
int err;
if (dataLen < TIGHT_MIN_TO_COMPRESS) {
memcpy(&cl->updateBuf[cl->ublen], tightBeforeBuf, dataLen);
cl->ublen += dataLen;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, dataLen);
return TRUE;
}
if (zlibLevel == 0)
return SendCompressedData (cl, tightBeforeBuf, dataLen);
pz = &cl->zsStruct[streamId];
/* Initialize compression stream if needed. */
if (!cl->zsActive[streamId]) {
pz->zalloc = Z_NULL;
pz->zfree = Z_NULL;
pz->opaque = Z_NULL;
err = deflateInit2 (pz, zlibLevel, Z_DEFLATED, MAX_WBITS,
MAX_MEM_LEVEL, zlibStrategy);
if (err != Z_OK)
return FALSE;
cl->zsActive[streamId] = TRUE;
cl->zsLevel[streamId] = zlibLevel;
}
/* Prepare buffer pointers. */
pz->next_in = (Bytef *)tightBeforeBuf;
pz->avail_in = dataLen;
pz->next_out = (Bytef *)tightAfterBuf;
pz->avail_out = tightAfterBufSize;
/* Change compression parameters if needed. */
if (zlibLevel != cl->zsLevel[streamId]) {
if (deflateParams (pz, zlibLevel, zlibStrategy) != Z_OK) {
return FALSE;
}
cl->zsLevel[streamId] = zlibLevel;
}
/* Actual compression. */
if (deflate(pz, Z_SYNC_FLUSH) != Z_OK ||
pz->avail_in != 0 || pz->avail_out == 0) {
return FALSE;
}
return SendCompressedData(cl, tightAfterBuf,
tightAfterBufSize - pz->avail_out);
}
static rfbBool SendCompressedData(rfbClientPtr cl, char *buf,
int compressedLen)
{
int i, portionLen;
cl->updateBuf[cl->ublen++] = compressedLen & 0x7F;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 1);
if (compressedLen > 0x7F) {
cl->updateBuf[cl->ublen-1] |= 0x80;
cl->updateBuf[cl->ublen++] = compressedLen >> 7 & 0x7F;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 1);
if (compressedLen > 0x3FFF) {
cl->updateBuf[cl->ublen-1] |= 0x80;
cl->updateBuf[cl->ublen++] = compressedLen >> 14 & 0xFF;
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 1);
}
}
portionLen = UPDATE_BUF_SIZE;
for (i = 0; i < compressedLen; i += portionLen) {
if (i + portionLen > compressedLen) {
portionLen = compressedLen - i;
}
if (cl->ublen + portionLen > UPDATE_BUF_SIZE) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
memcpy(&cl->updateBuf[cl->ublen], &buf[i], portionLen);
cl->ublen += portionLen;
}
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, compressedLen);
return TRUE;
}
/*
* Code to determine how many different colors used in rectangle.
*/
static void
FillPalette8(int count)
{
uint8_t *data = (uint8_t *)tightBeforeBuf;
uint8_t c0, c1;
int i, n0, n1;
paletteNumColors = 0;
c0 = data[0];
for (i = 1; i < count && data[i] == c0; i++);
if (i == count) {
paletteNumColors = 1;
return; /* Solid rectangle */
}
if (paletteMaxColors < 2)
return;
n0 = i;
c1 = data[i];
n1 = 0;
for (i++; i < count; i++) {
if (data[i] == c0) {
n0++;
} else if (data[i] == c1) {
n1++;
} else
break;
}
if (i == count) {
if (n0 > n1) {
monoBackground = (uint32_t)c0;
monoForeground = (uint32_t)c1;
} else {
monoBackground = (uint32_t)c1;
monoForeground = (uint32_t)c0;
}
paletteNumColors = 2; /* Two colors */
}
}
#define DEFINE_FILL_PALETTE_FUNCTION(bpp) \
\
static void \
FillPalette##bpp(int count) { \
uint##bpp##_t *data = (uint##bpp##_t *)tightBeforeBuf; \
uint##bpp##_t c0, c1, ci; \
int i, n0, n1, ni; \
\
c0 = data[0]; \
for (i = 1; i < count && data[i] == c0; i++); \
if (i >= count) { \
paletteNumColors = 1; /* Solid rectangle */ \
return; \
} \
\
if (paletteMaxColors < 2) { \
paletteNumColors = 0; /* Full-color encoding preferred */ \
return; \
} \
\
n0 = i; \
c1 = data[i]; \
n1 = 0; \
for (i++; i < count; i++) { \
ci = data[i]; \
if (ci == c0) { \
n0++; \
} else if (ci == c1) { \
n1++; \
} else \
break; \
} \
if (i >= count) { \
if (n0 > n1) { \
monoBackground = (uint32_t)c0; \
monoForeground = (uint32_t)c1; \
} else { \
monoBackground = (uint32_t)c1; \
monoForeground = (uint32_t)c0; \
} \
paletteNumColors = 2; /* Two colors */ \
return; \
} \
\
PaletteReset(); \
PaletteInsert (c0, (uint32_t)n0, bpp); \
PaletteInsert (c1, (uint32_t)n1, bpp); \
\
ni = 1; \
for (i++; i < count; i++) { \
if (data[i] == ci) { \
ni++; \
} else { \
if (!PaletteInsert (ci, (uint32_t)ni, bpp)) \
return; \
ci = data[i]; \
ni = 1; \
} \
} \
PaletteInsert (ci, (uint32_t)ni, bpp); \
}
DEFINE_FILL_PALETTE_FUNCTION(16)
DEFINE_FILL_PALETTE_FUNCTION(32)
#define DEFINE_FAST_FILL_PALETTE_FUNCTION(bpp) \
\
static void \
FastFillPalette##bpp(rfbClientPtr cl, uint##bpp##_t *data, int w, \
int pitch, int h) \
{ \
uint##bpp##_t c0, c1, ci, mask, c0t, c1t, cit; \
int i, j, i2 = 0, j2, n0, n1, ni; \
\
if (cl->translateFn != rfbTranslateNone) { \
mask = cl->screen->serverFormat.redMax \
<< cl->screen->serverFormat.redShift; \
mask |= cl->screen->serverFormat.greenMax \
<< cl->screen->serverFormat.greenShift; \
mask |= cl->screen->serverFormat.blueMax \
<< cl->screen->serverFormat.blueShift; \
} else mask = ~0; \
\
c0 = data[0] & mask; \
for (j = 0; j < h; j++) { \
for (i = 0; i < w; i++) { \
if ((data[j * pitch + i] & mask) != c0) \
goto done; \
} \
} \
done: \
if (j >= h) { \
paletteNumColors = 1; /* Solid rectangle */ \
return; \
} \
if (paletteMaxColors < 2) { \
paletteNumColors = 0; /* Full-color encoding preferred */ \
return; \
} \
\
n0 = j * w + i; \
c1 = data[j * pitch + i] & mask; \
n1 = 0; \
i++; if (i >= w) {i = 0; j++;} \
for (j2 = j; j2 < h; j2++) { \
for (i2 = i; i2 < w; i2++) { \
ci = data[j2 * pitch + i2] & mask; \
if (ci == c0) { \
n0++; \
} else if (ci == c1) { \
n1++; \
} else \
goto done2; \
} \
i = 0; \
} \
done2: \
(*cl->translateFn)(cl->translateLookupTable, \
&cl->screen->serverFormat, &cl->format, \
(char *)&c0, (char *)&c0t, bpp/8, 1, 1); \
(*cl->translateFn)(cl->translateLookupTable, \
&cl->screen->serverFormat, &cl->format, \
(char *)&c1, (char *)&c1t, bpp/8, 1, 1); \
if (j2 >= h) { \
if (n0 > n1) { \
monoBackground = (uint32_t)c0t; \
monoForeground = (uint32_t)c1t; \
} else { \
monoBackground = (uint32_t)c1t; \
monoForeground = (uint32_t)c0t; \
} \
paletteNumColors = 2; /* Two colors */ \
return; \
} \
\
PaletteReset(); \
PaletteInsert (c0t, (uint32_t)n0, bpp); \
PaletteInsert (c1t, (uint32_t)n1, bpp); \
\
ni = 1; \
i2++; if (i2 >= w) {i2 = 0; j2++;} \
for (j = j2; j < h; j++) { \
for (i = i2; i < w; i++) { \
if ((data[j * pitch + i] & mask) == ci) { \
ni++; \
} else { \
(*cl->translateFn)(cl->translateLookupTable, \
&cl->screen->serverFormat, \
&cl->format, (char *)&ci, \
(char *)&cit, bpp/8, 1, 1); \
if (!PaletteInsert (cit, (uint32_t)ni, bpp)) \
return; \
ci = data[j * pitch + i] & mask; \
ni = 1; \
} \
} \
i2 = 0; \
} \
\
(*cl->translateFn)(cl->translateLookupTable, \
&cl->screen->serverFormat, &cl->format, \
(char *)&ci, (char *)&cit, bpp/8, 1, 1); \
PaletteInsert (cit, (uint32_t)ni, bpp); \
}
DEFINE_FAST_FILL_PALETTE_FUNCTION(16)
DEFINE_FAST_FILL_PALETTE_FUNCTION(32)
/*
* Functions to operate with palette structures.
*/
#define HASH_FUNC16(rgb) ((int)((((rgb) >> 8) + (rgb)) & 0xFF))
#define HASH_FUNC32(rgb) ((int)((((rgb) >> 16) + ((rgb) >> 8)) & 0xFF))
static void
PaletteReset(void)
{
paletteNumColors = 0;
memset(palette.hash, 0, 256 * sizeof(COLOR_LIST *));
}
static int
PaletteInsert(uint32_t rgb,
int numPixels,
int bpp)
{
COLOR_LIST *pnode;
COLOR_LIST *prev_pnode = NULL;
int hash_key, idx, new_idx, count;
hash_key = (bpp == 16) ? HASH_FUNC16(rgb) : HASH_FUNC32(rgb);
pnode = palette.hash[hash_key];
while (pnode != NULL) {
if (pnode->rgb == rgb) {
/* Such palette entry already exists. */
new_idx = idx = pnode->idx;
count = palette.entry[idx].numPixels + numPixels;
if (new_idx && palette.entry[new_idx-1].numPixels < count) {
do {
palette.entry[new_idx] = palette.entry[new_idx-1];
palette.entry[new_idx].listNode->idx = new_idx;
new_idx--;
}
while (new_idx && palette.entry[new_idx-1].numPixels < count);
palette.entry[new_idx].listNode = pnode;
pnode->idx = new_idx;
}
palette.entry[new_idx].numPixels = count;
return paletteNumColors;
}
prev_pnode = pnode;
pnode = pnode->next;
}
/* Check if palette is full. */
if (paletteNumColors == 256 || paletteNumColors == paletteMaxColors) {
paletteNumColors = 0;
return 0;
}
/* Move palette entries with lesser pixel counts. */
for ( idx = paletteNumColors;
idx > 0 && palette.entry[idx-1].numPixels < numPixels;
idx-- ) {
palette.entry[idx] = palette.entry[idx-1];
palette.entry[idx].listNode->idx = idx;
}
/* Add new palette entry into the freed slot. */
pnode = &palette.list[paletteNumColors];
if (prev_pnode != NULL) {
prev_pnode->next = pnode;
} else {
palette.hash[hash_key] = pnode;
}
pnode->next = NULL;
pnode->idx = idx;
pnode->rgb = rgb;
palette.entry[idx].listNode = pnode;
palette.entry[idx].numPixels = numPixels;
return (++paletteNumColors);
}
/*
* Converting 32-bit color samples into 24-bit colors.
* Should be called only when redMax, greenMax and blueMax are 255.
* Color components assumed to be byte-aligned.
*/
static void Pack24(rfbClientPtr cl,
char *buf,
rfbPixelFormat *fmt,
int count)
{
uint32_t *buf32;
uint32_t pix;
int r_shift, g_shift, b_shift;
buf32 = (uint32_t *)buf;
if (!cl->screen->serverFormat.bigEndian == !fmt->bigEndian) {
r_shift = fmt->redShift;
g_shift = fmt->greenShift;
b_shift = fmt->blueShift;
} else {
r_shift = 24 - fmt->redShift;
g_shift = 24 - fmt->greenShift;
b_shift = 24 - fmt->blueShift;
}
while (count--) {
pix = *buf32++;
*buf++ = (char)(pix >> r_shift);
*buf++ = (char)(pix >> g_shift);
*buf++ = (char)(pix >> b_shift);
}
}
/*
* Converting truecolor samples into palette indices.
*/
#define DEFINE_IDX_ENCODE_FUNCTION(bpp) \
\
static void \
EncodeIndexedRect##bpp(uint8_t *buf, int count) { \
COLOR_LIST *pnode; \
uint##bpp##_t *src; \
uint##bpp##_t rgb; \
int rep = 0; \
\
src = (uint##bpp##_t *) buf; \
\
while (count--) { \
rgb = *src++; \
while (count && *src == rgb) { \
rep++, src++, count--; \
} \
pnode = palette.hash[HASH_FUNC##bpp(rgb)]; \
while (pnode != NULL) { \
if ((uint##bpp##_t)pnode->rgb == rgb) { \
*buf++ = (uint8_t)pnode->idx; \
while (rep) { \
*buf++ = (uint8_t)pnode->idx; \
rep--; \
} \
break; \
} \
pnode = pnode->next; \
} \
} \
}
DEFINE_IDX_ENCODE_FUNCTION(16)
DEFINE_IDX_ENCODE_FUNCTION(32)
#define DEFINE_MONO_ENCODE_FUNCTION(bpp) \
\
static void \
EncodeMonoRect##bpp(uint8_t *buf, int w, int h) { \
uint##bpp##_t *ptr; \
uint##bpp##_t bg; \
unsigned int value, mask; \
int aligned_width; \
int x, y, bg_bits; \
\
ptr = (uint##bpp##_t *) buf; \
bg = (uint##bpp##_t) monoBackground; \
aligned_width = w - w % 8; \
\
for (y = 0; y < h; y++) { \
for (x = 0; x < aligned_width; x += 8) { \
for (bg_bits = 0; bg_bits < 8; bg_bits++) { \
if (*ptr++ != bg) \
break; \
} \
if (bg_bits == 8) { \
*buf++ = 0; \
continue; \
} \
mask = 0x80 >> bg_bits; \
value = mask; \
for (bg_bits++; bg_bits < 8; bg_bits++) { \
mask >>= 1; \
if (*ptr++ != bg) { \
value |= mask; \
} \
} \
*buf++ = (uint8_t)value; \
} \
\
mask = 0x80; \
value = 0; \
if (x >= w) \
continue; \
\
for (; x < w; x++) { \
if (*ptr++ != bg) { \
value |= mask; \
} \
mask >>= 1; \
} \
*buf++ = (uint8_t)value; \
} \
}
DEFINE_MONO_ENCODE_FUNCTION(8)
DEFINE_MONO_ENCODE_FUNCTION(16)
DEFINE_MONO_ENCODE_FUNCTION(32)
/*
* JPEG compression stuff.
*/
static rfbBool
SendJpegRect(rfbClientPtr cl, int x, int y, int w, int h, int quality)
{
unsigned char *srcbuf;
int ps = cl->screen->serverFormat.bitsPerPixel / 8;
int subsamp = subsampLevel2tjsubsamp[subsampLevel];
unsigned long size = 0;
int flags = 0, pitch;
unsigned char *tmpbuf = NULL;
if (cl->screen->serverFormat.bitsPerPixel == 8)
return SendFullColorRect(cl, w, h);
if (ps < 2) {
rfbLog("Error: JPEG requires 16-bit, 24-bit, or 32-bit pixel format.\n");
return 0;
}
if (!j) {
if ((j = tjInitCompress()) == NULL) {
rfbLog("JPEG Error: %s\n", tjGetErrorStr());
return 0;
}
}
if (tightAfterBufSize < TJBUFSIZE(w, h)) {
if (tightAfterBuf == NULL)
tightAfterBuf = (char *)malloc(TJBUFSIZE(w, h));
else
tightAfterBuf = (char *)realloc(tightAfterBuf,
TJBUFSIZE(w, h));
if (!tightAfterBuf) {
rfbLog("Memory allocation failure!\n");
return 0;
}
tightAfterBufSize = TJBUFSIZE(w, h);
}
if (ps == 2) {
uint16_t *srcptr, pix;
unsigned char *dst;
int inRed, inGreen, inBlue, i, j;
if((tmpbuf = (unsigned char *)malloc(w * h * 3)) == NULL)
rfbLog("Memory allocation failure!\n");
srcptr = (uint16_t *)&cl->scaledScreen->frameBuffer
[y * cl->scaledScreen->paddedWidthInBytes + x * ps];
dst = tmpbuf;
for(j = 0; j < h; j++) {
uint16_t *srcptr2 = srcptr;
unsigned char *dst2 = dst;
for (i = 0; i < w; i++) {
pix = *srcptr2++;
inRed = (int) (pix >> cl->screen->serverFormat.redShift
& cl->screen->serverFormat.redMax);
inGreen = (int) (pix >> cl->screen->serverFormat.greenShift
& cl->screen->serverFormat.greenMax);
inBlue = (int) (pix >> cl->screen->serverFormat.blueShift
& cl->screen->serverFormat.blueMax);
*dst2++ = (uint8_t)((inRed * 255
+ cl->screen->serverFormat.redMax / 2)
/ cl->screen->serverFormat.redMax);
*dst2++ = (uint8_t)((inGreen * 255
+ cl->screen->serverFormat.greenMax / 2)
/ cl->screen->serverFormat.greenMax);
*dst2++ = (uint8_t)((inBlue * 255
+ cl->screen->serverFormat.blueMax / 2)
/ cl->screen->serverFormat.blueMax);
}
srcptr += cl->scaledScreen->paddedWidthInBytes / ps;
dst += w * 3;
}
srcbuf = tmpbuf;
pitch = w * 3;
ps = 3;
} else {
if (cl->screen->serverFormat.bigEndian && ps == 4)
flags |= TJ_ALPHAFIRST;
if (cl->screen->serverFormat.redShift == 16
&& cl->screen->serverFormat.blueShift == 0)
flags |= TJ_BGR;
if (cl->screen->serverFormat.bigEndian)
flags ^= TJ_BGR;
pitch = cl->scaledScreen->paddedWidthInBytes;
srcbuf = (unsigned char *)&cl->scaledScreen->frameBuffer
[y * pitch + x * ps];
}
if (tjCompress(j, srcbuf, w, pitch, h, ps, (unsigned char *)tightAfterBuf,
&size, subsamp, quality, flags) == -1) {
rfbLog("JPEG Error: %s\n", tjGetErrorStr());
if (tmpbuf) {
free(tmpbuf);
tmpbuf = NULL;
}
return 0;
}
if (tmpbuf) {
free(tmpbuf);
tmpbuf = NULL;
}
if (cl->ublen + TIGHT_MIN_TO_COMPRESS + 1 > UPDATE_BUF_SIZE) {
if (!rfbSendUpdateBuf(cl))
return FALSE;
}
cl->updateBuf[cl->ublen++] = (char)(rfbTightJpeg << 4);
rfbStatRecordEncodingSentAdd(cl, rfbEncodingTight, 1);
return SendCompressedData(cl, tightAfterBuf, (int)size);
}