metasploit-framework/external/source/vncdll/winvnc/vncEncodeZlib.cpp

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// Copyright (C) 2000 Tridia Corporation. All Rights Reserved.
// Copyright (C) 1999 AT&T Laboratories Cambridge. All Rights Reserved.
//
// This file is part of the VNC system.
//
// The VNC system 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.
//
// TightVNC distribution homepage on the Web: http://www.tightvnc.com/
//
// If the source code for the VNC system is not available from the place
// whence you received this file, check http://www.uk.research.att.com/vnc or contact
// the authors on vnc@uk.research.att.com for information on obtaining it.
// vncEncodeZlib
// This file implements the vncEncoder-derived vncEncodeZlib class.
// This class overrides some vncEncoder functions to produce a bitmap
// to Zlib encoder. Zlib is much more efficient than RAW format on
// most screen data and usually twice as efficient as hextile. Of
// course, zlib compression uses more CPU time on the server.
// However, over slower (64kbps or less) connections, the reduction
// in data transmitted usually outweighs the extra latency added
// while the server CPU performs the compression algorithms.
#include "vncEncodeZlib.h"
vncEncodeZlib::vncEncodeZlib()
{
m_buffer = NULL;
m_bufflen = 0;
compStreamInited = false;
}
vncEncodeZlib::~vncEncodeZlib()
{
if (m_buffer != NULL)
{
delete [] m_buffer;
m_buffer = NULL;
}
if ( compStreamInited == true )
{
deflateEnd( &compStream );
}
compStreamInited = false;
}
void
vncEncodeZlib::Init()
{
vncEncoder::Init();
}
UINT
vncEncodeZlib::RequiredBuffSize(UINT width, UINT height)
{
int result;
// The zlib library specifies a maximum compressed size of
// the raw size plus one percent plus 8 bytes. We also need
// to cover the zlib header space.
result = vncEncoder::RequiredBuffSize(width, height);
result += ((result / 100) + 8) + sz_rfbZlibHeader;
return result;
}
UINT
vncEncodeZlib::NumCodedRects(RECT &rect)
{
/******************************************************************
return 1;
******************************************************************/
const int rectW = rect.right - rect.left;
const int rectH = rect.bottom - rect.top;
// Return the number of rectangles needed to encode the given
// update. ( ZLIB_MAX_SIZE(rectW) / rectW ) is the number of lines in
// each maximum size rectangle.
return (( rectH - 1 ) / ( ZLIB_MAX_SIZE( rectW ) / rectW ) + 1 );
}
/*****************************************************************************
*
* Routines to implement zlib Encoding (LZ+Huffman compression) by calling
* the included zlib library.
*/
// Encode the rectangle using zlib compression
inline UINT
vncEncodeZlib::EncodeRect(BYTE *source, VSocket *outConn, BYTE *dest, const RECT &rect, int offx, int offy)
{
int totalSize = 0;
int partialSize = 0;
int maxLines;
int linesRemaining;
offsetx = offx;
offsety = offy;
RECT partialRect;
const int rectW = rect.right - rect.left;
const int rectH = rect.bottom - rect.top;
partialRect.right = rect.right;
partialRect.left = rect.left;
partialRect.top = rect.top;
partialRect.bottom = rect.bottom;
maxLines = ( ZLIB_MAX_SIZE(rectW) / rectW );
linesRemaining = rectH;
while ( linesRemaining > 0 ) {
int linesToComp;
if ( maxLines < linesRemaining )
linesToComp = maxLines;
else
linesToComp = linesRemaining;
partialRect.bottom = partialRect.top + linesToComp;
partialSize = EncodeOneRect( source, dest, partialRect );
totalSize += partialSize;
linesRemaining -= linesToComp;
partialRect.top += linesToComp;
if (( linesRemaining > 0 ) &&
( partialSize > 0 ))
{
// Send the encoded data
outConn->SendQueued( (char *)dest, partialSize );
transmittedSize += partialSize;
}
}
transmittedSize += partialSize;
return partialSize;
}
// Encode the rectangle using zlib compression
inline UINT
vncEncodeZlib::EncodeOneRect(BYTE *source, BYTE *dest, const RECT &rect)
{
int totalCompDataLen = 0;
int previousTotalOut;
int deflateResult;
const int rectW = rect.right - rect.left;
const int rectH = rect.bottom - rect.top;
const int rawDataSize = (rectW*rectH*m_remoteformat.bitsPerPixel / 8);
const int maxCompSize = (rawDataSize + (rawDataSize/100) + 8);
// Send as raw if the update is too small to compress.
if (rawDataSize < VNC_ENCODE_ZLIB_MIN_COMP_SIZE)
return vncEncoder::EncodeRect(source, dest, rect, offsetx, offsety);
// Create the rectangle header
rfbFramebufferUpdateRectHeader *surh=(rfbFramebufferUpdateRectHeader *)dest;
surh->r.x = (CARD16) rect.left ;
surh->r.y = (CARD16) rect.top ;
surh->r.w = (CARD16) (rectW);
surh->r.h = (CARD16) (rectH);
surh->r.x = Swap16IfLE(surh->r.x- offsetx);
surh->r.y = Swap16IfLE(surh->r.y- offsety);
surh->r.w = Swap16IfLE(surh->r.w);
surh->r.h = Swap16IfLE(surh->r.h);
surh->encoding = Swap32IfLE(rfbEncodingZlib);
dataSize += ( rectW * rectH * m_remoteformat.bitsPerPixel) / 8;
rectangleOverhead += sz_rfbFramebufferUpdateRectHeader;
// create a space big enough for the Zlib encoded pixels
if (m_bufflen < rawDataSize)
{
if (m_buffer != NULL)
{
delete [] m_buffer;
m_buffer = NULL;
}
m_buffer = new BYTE [rawDataSize+1];
if (m_buffer == NULL)
return vncEncoder::EncodeRect(source, dest, rect, offsetx, offsety);
m_bufflen = rawDataSize;
}
// Translate the data into our new buffer
Translate(source, m_buffer, rect);
// Initialize input/output buffer assignment for compressor state.
compStream.avail_in = rawDataSize;
compStream.next_in = m_buffer;
compStream.avail_out = maxCompSize;
compStream.next_out = (dest+sz_rfbFramebufferUpdateRectHeader+sz_rfbZlibHeader);
compStream.data_type = Z_BINARY;
// If necessary, the first time, initialize the compressor state.
if ( compStreamInited == false )
{
compStream.total_in = 0;
compStream.total_out = 0;
compStream.zalloc = Z_NULL;
compStream.zfree = Z_NULL;
compStream.opaque = Z_NULL;
deflateResult = deflateInit2( &compStream,
m_compresslevel,
Z_DEFLATED,
MAX_WBITS,
MAX_MEM_LEVEL,
Z_DEFAULT_STRATEGY );
if ( deflateResult != Z_OK )
{
return vncEncoder::EncodeRect(source, dest, rect, offsetx, offsety);
}
compStreamInited = true;
}
// Record previous total output size.
previousTotalOut = compStream.total_out;
// Compress the raw data into the result buffer.
deflateResult = deflate( &compStream, Z_SYNC_FLUSH );
if ( deflateResult != Z_OK )
{
return vncEncoder::EncodeRect(source, dest, rect, offsetx, offsety);
}
// Calculate size of compressed data.
totalCompDataLen = compStream.total_out - previousTotalOut;
// Format the ZlibHeader
rfbZlibHeader *zlibh=(rfbZlibHeader *)(dest+sz_rfbFramebufferUpdateRectHeader);
zlibh->nBytes = Swap32IfLE(totalCompDataLen);
// Update statistics
encodedSize += sz_rfbZlibHeader + totalCompDataLen;
// Return the amount of data sent
return sz_rfbFramebufferUpdateRectHeader +
sz_rfbZlibHeader +
totalCompDataLen;
}
/*
VOID vncEncodeZlib::UpdateZLibDictionary( AGENT_CTX * lpAgentContext )
{
if( lpAgentContext->dictionaries[0] )
setdictionary( &compStream, lpAgentContext->dictionaries[0]->bDictBuffer, lpAgentContext->dictionaries[0]->dwDictLength );
}
VOID vncEncodeZlib::DumpZLibDictionary( AGENT_CTX * lpAgentContext )
{
SendZlibDictionary( lpAgentContext, 0, &compStream );
}
*/