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|
/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
* This file incorporates work covered by the following license notice:
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed
* with this work for additional information regarding copyright
* ownership. The ASF licenses this file to you under the Apache
* License, Version 2.0 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.apache.org/licenses/LICENSE-2.0 .
*/
#include "pdfwriter_impl.hxx"
#include <vcl/pdfextoutdevdata.hxx>
#include <vcl/virdev.hxx>
#include <vcl/gdimtf.hxx>
#include <vcl/metaact.hxx>
#include <vcl/bitmapaccess.hxx>
#include <vcl/graph.hxx>
#include <svdata.hxx>
#include <unotools/streamwrap.hxx>
#include <tools/fract.hxx>
#include <tools/stream.hxx>
#include <comphelper/fileformat.h>
#include <comphelper/hash.hxx>
#include <comphelper/processfactory.hxx>
#include <com/sun/star/beans/PropertyValue.hpp>
#include <com/sun/star/io/XSeekable.hpp>
#include <com/sun/star/graphic/GraphicProvider.hpp>
#include <com/sun/star/graphic/XGraphicProvider.hpp>
#include <cppuhelper/implbase.hxx>
#include <rtl/digest.h>
#include <sal/log.hxx>
#include <memory>
using namespace vcl;
using namespace com::sun::star;
using namespace com::sun::star::uno;
using namespace com::sun::star::beans;
static bool lcl_canUsePDFAxialShading(const Gradient& rGradient);
void PDFWriterImpl::implWriteGradient( const tools::PolyPolygon& i_rPolyPoly, const Gradient& i_rGradient,
VirtualDevice* i_pDummyVDev, const vcl::PDFWriter::PlayMetafileContext& i_rContext )
{
GDIMetaFile aTmpMtf;
i_pDummyVDev->AddGradientActions( i_rPolyPoly.GetBoundRect(), i_rGradient, aTmpMtf );
m_rOuterFace.Push();
m_rOuterFace.IntersectClipRegion( i_rPolyPoly.getB2DPolyPolygon() );
playMetafile( aTmpMtf, nullptr, i_rContext, i_pDummyVDev );
m_rOuterFace.Pop();
}
void PDFWriterImpl::implWriteBitmapEx( const Point& i_rPoint, const Size& i_rSize, const BitmapEx& i_rBitmapEx, const Graphic& i_Graphic,
VirtualDevice const * i_pDummyVDev, const vcl::PDFWriter::PlayMetafileContext& i_rContext )
{
if ( i_rBitmapEx.IsEmpty() || !i_rSize.Width() || !i_rSize.Height() )
return;
BitmapEx aBitmapEx( i_rBitmapEx );
Point aPoint( i_rPoint );
Size aSize( i_rSize );
// #i19065# Negative sizes have mirror semantics on
// OutputDevice. BitmapEx and co. have no idea about that, so
// perform that _before_ doing anything with aBitmapEx.
BmpMirrorFlags nMirrorFlags(BmpMirrorFlags::NONE);
if( aSize.Width() < 0 )
{
aSize.setWidth( aSize.Width() * -1 );
aPoint.AdjustX( -(aSize.Width()) );
nMirrorFlags |= BmpMirrorFlags::Horizontal;
}
if( aSize.Height() < 0 )
{
aSize.setHeight( aSize.Height() * -1 );
aPoint.AdjustY( -(aSize.Height()) );
nMirrorFlags |= BmpMirrorFlags::Vertical;
}
if( nMirrorFlags != BmpMirrorFlags::NONE )
{
aBitmapEx.Mirror( nMirrorFlags );
}
bool bIsJpeg = false, bIsPng = false;
if( i_Graphic.GetType() != GraphicType::NONE && i_Graphic.GetBitmapEx() == aBitmapEx )
{
GfxLinkType eType = i_Graphic.GetGfxLink().GetType();
bIsJpeg = (eType == GfxLinkType::NativeJpg);
bIsPng = (eType == GfxLinkType::NativePng);
}
if( i_rContext.m_nMaxImageResolution > 50 )
{
// do downsampling if necessary
const Size aDstSizeTwip( i_pDummyVDev->PixelToLogic(i_pDummyVDev->LogicToPixel(aSize), MapMode(MapUnit::MapTwip)) );
const Size aBmpSize( aBitmapEx.GetSizePixel() );
const double fBmpPixelX = aBmpSize.Width();
const double fBmpPixelY = aBmpSize.Height();
const double fMaxPixelX = aDstSizeTwip.Width() * i_rContext.m_nMaxImageResolution / 1440.0;
const double fMaxPixelY = aDstSizeTwip.Height() * i_rContext.m_nMaxImageResolution / 1440.0;
// check, if the bitmap DPI exceeds the maximum DPI (allow 4 pixel rounding tolerance)
if( ( ( fBmpPixelX > ( fMaxPixelX + 4 ) ) ||
( fBmpPixelY > ( fMaxPixelY + 4 ) ) ) &&
( fBmpPixelY > 0.0 ) && ( fMaxPixelY > 0.0 ) )
{
// do scaling
Size aNewBmpSize;
const double fBmpWH = fBmpPixelX / fBmpPixelY;
const double fMaxWH = fMaxPixelX / fMaxPixelY;
if( fBmpWH < fMaxWH )
{
aNewBmpSize.setWidth( FRound( fMaxPixelY * fBmpWH ) );
aNewBmpSize.setHeight( FRound( fMaxPixelY ) );
}
else if( fBmpWH > 0.0 )
{
aNewBmpSize.setWidth( FRound( fMaxPixelX ) );
aNewBmpSize.setHeight( FRound( fMaxPixelX / fBmpWH) );
}
if( aNewBmpSize.Width() && aNewBmpSize.Height() )
{
// #i121233# Use best quality for PDF exports
aBitmapEx.Scale( aNewBmpSize, BmpScaleFlag::BestQuality );
}
else
{
aBitmapEx.SetEmpty();
}
}
}
const Size aSizePixel( aBitmapEx.GetSizePixel() );
if ( aSizePixel.Width() && aSizePixel.Height() )
{
if( m_aContext.ColorMode == PDFWriter::DrawGreyscale )
{
BmpConversion eConv = BmpConversion::N8BitGreys;
int nDepth = aBitmapEx.GetBitmap().GetBitCount();
if( nDepth <= 4 )
eConv = BmpConversion::N4BitGreys;
if( nDepth > 1 )
aBitmapEx.Convert( eConv );
}
bool bUseJPGCompression = !i_rContext.m_bOnlyLosslessCompression;
if ( bIsPng || ( aSizePixel.Width() < 32 ) || ( aSizePixel.Height() < 32 ) )
bUseJPGCompression = false;
SvMemoryStream aStrm;
Bitmap aMask;
bool bTrueColorJPG = true;
if ( bUseJPGCompression )
{
sal_uInt32 nZippedFileSize = 0; // sj: we will calculate the filesize of a zipped bitmap
if ( !bIsJpeg ) // to determine if jpeg compression is useful
{
SvMemoryStream aTemp;
aTemp.SetCompressMode( aTemp.GetCompressMode() | SvStreamCompressFlags::ZBITMAP );
aTemp.SetVersion( SOFFICE_FILEFORMAT_40 ); // sj: up from version 40 our bitmap stream operator
WriteDIBBitmapEx(aBitmapEx, aTemp); // is capable of zlib stream compression
aTemp.Seek( STREAM_SEEK_TO_END );
nZippedFileSize = aTemp.Tell();
}
if ( aBitmapEx.IsTransparent() )
{
if ( aBitmapEx.IsAlpha() )
aMask = aBitmapEx.GetAlpha().GetBitmap();
else
aMask = aBitmapEx.GetMask();
}
Graphic aGraphic( aBitmapEx.GetBitmap() );
Sequence< PropertyValue > aFilterData( 2 );
aFilterData[ 0 ].Name = "Quality";
aFilterData[ 0 ].Value <<= sal_Int32(i_rContext.m_nJPEGQuality);
aFilterData[ 1 ].Name = "ColorMode";
aFilterData[ 1 ].Value <<= sal_Int32(0);
try
{
uno::Reference < io::XStream > xStream = new utl::OStreamWrapper( aStrm );
uno::Reference< io::XSeekable > xSeekable( xStream, UNO_QUERY_THROW );
uno::Reference< uno::XComponentContext > xContext( comphelper::getProcessComponentContext() );
uno::Reference< graphic::XGraphicProvider > xGraphicProvider( graphic::GraphicProvider::create(xContext) );
uno::Reference< graphic::XGraphic > xGraphic( aGraphic.GetXGraphic() );
uno::Reference < io::XOutputStream > xOut( xStream->getOutputStream() );
uno::Sequence< beans::PropertyValue > aOutMediaProperties( 3 );
aOutMediaProperties[0].Name = "OutputStream";
aOutMediaProperties[0].Value <<= xOut;
aOutMediaProperties[1].Name = "MimeType";
aOutMediaProperties[1].Value <<= OUString("image/jpeg");
aOutMediaProperties[2].Name = "FilterData";
aOutMediaProperties[2].Value <<= aFilterData;
xGraphicProvider->storeGraphic( xGraphic, aOutMediaProperties );
xOut->flush();
if ( !bIsJpeg && xSeekable->getLength() > nZippedFileSize )
{
bUseJPGCompression = false;
}
else
{
aStrm.Seek( STREAM_SEEK_TO_END );
xSeekable->seek( 0 );
Sequence< PropertyValue > aArgs( 1 );
aArgs[ 0 ].Name = "InputStream";
aArgs[ 0 ].Value <<= xStream;
uno::Reference< XPropertySet > xPropSet( xGraphicProvider->queryGraphicDescriptor( aArgs ) );
if ( xPropSet.is() )
{
sal_Int16 nBitsPerPixel = 24;
if ( xPropSet->getPropertyValue("BitsPerPixel") >>= nBitsPerPixel )
{
bTrueColorJPG = nBitsPerPixel != 8;
}
}
}
}
catch( uno::Exception& )
{
bUseJPGCompression = false;
}
}
if ( bUseJPGCompression )
m_rOuterFace.DrawJPGBitmap( aStrm, bTrueColorJPG, aSizePixel, tools::Rectangle( aPoint, aSize ), aMask, i_Graphic );
else if ( aBitmapEx.IsTransparent() )
m_rOuterFace.DrawBitmapEx( aPoint, aSize, aBitmapEx );
else
m_rOuterFace.DrawBitmap( aPoint, aSize, aBitmapEx.GetBitmap(), i_Graphic );
}
}
void PDFWriterImpl::playMetafile( const GDIMetaFile& i_rMtf, vcl::PDFExtOutDevData* i_pOutDevData, const vcl::PDFWriter::PlayMetafileContext& i_rContext, VirtualDevice* pDummyVDev )
{
bool bAssertionFired( false );
ScopedVclPtr<VirtualDevice> xPrivateDevice;
if( ! pDummyVDev )
{
xPrivateDevice.disposeAndReset(VclPtr<VirtualDevice>::Create());
pDummyVDev = xPrivateDevice.get();
pDummyVDev->EnableOutput( false );
pDummyVDev->SetMapMode( i_rMtf.GetPrefMapMode() );
}
GDIMetaFile aMtf( i_rMtf );
for( sal_uInt32 i = 0, nCount = aMtf.GetActionSize(); i < nCount; )
{
if ( !i_pOutDevData || !i_pOutDevData->PlaySyncPageAct( m_rOuterFace, i, aMtf ) )
{
const MetaAction* pAction = aMtf.GetAction( i );
const MetaActionType nType = pAction->GetType();
switch( nType )
{
case MetaActionType::PIXEL:
{
const MetaPixelAction* pA = static_cast<const MetaPixelAction*>(pAction);
m_rOuterFace.DrawPixel( pA->GetPoint(), pA->GetColor() );
}
break;
case MetaActionType::POINT:
{
const MetaPointAction* pA = static_cast<const MetaPointAction*>(pAction);
m_rOuterFace.DrawPixel( pA->GetPoint() );
}
break;
case MetaActionType::LINE:
{
const MetaLineAction* pA = static_cast<const MetaLineAction*>(pAction);
if ( pA->GetLineInfo().IsDefault() )
m_rOuterFace.DrawLine( pA->GetStartPoint(), pA->GetEndPoint() );
else
m_rOuterFace.DrawLine( pA->GetStartPoint(), pA->GetEndPoint(), pA->GetLineInfo() );
}
break;
case MetaActionType::RECT:
{
const MetaRectAction* pA = static_cast<const MetaRectAction*>(pAction);
m_rOuterFace.DrawRect( pA->GetRect() );
}
break;
case MetaActionType::ROUNDRECT:
{
const MetaRoundRectAction* pA = static_cast<const MetaRoundRectAction*>(pAction);
m_rOuterFace.DrawRect( pA->GetRect(), pA->GetHorzRound(), pA->GetVertRound() );
}
break;
case MetaActionType::ELLIPSE:
{
const MetaEllipseAction* pA = static_cast<const MetaEllipseAction*>(pAction);
m_rOuterFace.DrawEllipse( pA->GetRect() );
}
break;
case MetaActionType::ARC:
{
const MetaArcAction* pA = static_cast<const MetaArcAction*>(pAction);
m_rOuterFace.DrawArc( pA->GetRect(), pA->GetStartPoint(), pA->GetEndPoint() );
}
break;
case MetaActionType::PIE:
{
const MetaArcAction* pA = static_cast<const MetaArcAction*>(pAction);
m_rOuterFace.DrawPie( pA->GetRect(), pA->GetStartPoint(), pA->GetEndPoint() );
}
break;
case MetaActionType::CHORD:
{
const MetaChordAction* pA = static_cast<const MetaChordAction*>(pAction);
m_rOuterFace.DrawChord( pA->GetRect(), pA->GetStartPoint(), pA->GetEndPoint() );
}
break;
case MetaActionType::POLYGON:
{
const MetaPolygonAction* pA = static_cast<const MetaPolygonAction*>(pAction);
m_rOuterFace.DrawPolygon( pA->GetPolygon() );
}
break;
case MetaActionType::POLYLINE:
{
const MetaPolyLineAction* pA = static_cast<const MetaPolyLineAction*>(pAction);
if ( pA->GetLineInfo().IsDefault() )
m_rOuterFace.DrawPolyLine( pA->GetPolygon() );
else
m_rOuterFace.DrawPolyLine( pA->GetPolygon(), pA->GetLineInfo() );
}
break;
case MetaActionType::POLYPOLYGON:
{
const MetaPolyPolygonAction* pA = static_cast<const MetaPolyPolygonAction*>(pAction);
m_rOuterFace.DrawPolyPolygon( pA->GetPolyPolygon() );
}
break;
case MetaActionType::GRADIENT:
{
const MetaGradientAction* pA = static_cast<const MetaGradientAction*>(pAction);
const Gradient& rGradient = pA->GetGradient();
if (lcl_canUsePDFAxialShading(rGradient))
{
m_rOuterFace.DrawGradient( pA->GetRect(), rGradient );
}
else
{
const tools::PolyPolygon aPolyPoly( pA->GetRect() );
implWriteGradient( aPolyPoly, rGradient, pDummyVDev, i_rContext );
}
}
break;
case MetaActionType::GRADIENTEX:
{
const MetaGradientExAction* pA = static_cast<const MetaGradientExAction*>(pAction);
const Gradient& rGradient = pA->GetGradient();
if (lcl_canUsePDFAxialShading(rGradient))
m_rOuterFace.DrawGradient( pA->GetPolyPolygon(), rGradient );
else
implWriteGradient( pA->GetPolyPolygon(), rGradient, pDummyVDev, i_rContext );
}
break;
case MetaActionType::HATCH:
{
const MetaHatchAction* pA = static_cast<const MetaHatchAction*>(pAction);
m_rOuterFace.DrawHatch( pA->GetPolyPolygon(), pA->GetHatch() );
}
break;
case MetaActionType::Transparent:
{
const MetaTransparentAction* pA = static_cast<const MetaTransparentAction*>(pAction);
m_rOuterFace.DrawTransparent( pA->GetPolyPolygon(), pA->GetTransparence() );
}
break;
case MetaActionType::FLOATTRANSPARENT:
{
const MetaFloatTransparentAction* pA = static_cast<const MetaFloatTransparentAction*>(pAction);
GDIMetaFile aTmpMtf( pA->GetGDIMetaFile() );
const Point& rPos = pA->GetPoint();
const Size& rSize= pA->GetSize();
const Gradient& rTransparenceGradient = pA->GetGradient();
// special case constant alpha value
if( rTransparenceGradient.GetStartColor() == rTransparenceGradient.GetEndColor() )
{
const Color aTransCol( rTransparenceGradient.GetStartColor() );
const sal_uInt16 nTransPercent = aTransCol.GetLuminance() * 100 / 255;
m_rOuterFace.BeginTransparencyGroup();
playMetafile( aTmpMtf, nullptr, i_rContext, pDummyVDev );
m_rOuterFace.EndTransparencyGroup( tools::Rectangle( rPos, rSize ), nTransPercent );
}
else
{
const Size aDstSizeTwip( pDummyVDev->PixelToLogic(pDummyVDev->LogicToPixel(rSize), MapMode(MapUnit::MapTwip)) );
// i#115962# Always use at least 300 DPI for bitmap conversion of transparence gradients,
// else the quality is not acceptable (see bugdoc as example)
sal_Int32 nMaxBmpDPI(300);
if( i_rContext.m_nMaxImageResolution > 50 )
{
if ( nMaxBmpDPI > i_rContext.m_nMaxImageResolution )
nMaxBmpDPI = i_rContext.m_nMaxImageResolution;
}
const sal_Int32 nPixelX = static_cast<sal_Int32>(static_cast<double>(aDstSizeTwip.Width()) * static_cast<double>(nMaxBmpDPI) / 1440.0);
const sal_Int32 nPixelY = static_cast<sal_Int32>(static_cast<double>(aDstSizeTwip.Height()) * static_cast<double>(nMaxBmpDPI) / 1440.0);
if ( nPixelX && nPixelY )
{
Size aDstSizePixel( nPixelX, nPixelY );
ScopedVclPtrInstance<VirtualDevice> xVDev;
if( xVDev->SetOutputSizePixel( aDstSizePixel ) )
{
Bitmap aPaint, aMask;
AlphaMask aAlpha;
Point aPoint;
MapMode aMapMode( pDummyVDev->GetMapMode() );
aMapMode.SetOrigin( aPoint );
xVDev->SetMapMode( aMapMode );
Size aDstSize( xVDev->PixelToLogic( aDstSizePixel ) );
Point aMtfOrigin( aTmpMtf.GetPrefMapMode().GetOrigin() );
if ( aMtfOrigin.X() || aMtfOrigin.Y() )
aTmpMtf.Move( -aMtfOrigin.X(), -aMtfOrigin.Y() );
double fScaleX = static_cast<double>(aDstSize.Width()) / static_cast<double>(aTmpMtf.GetPrefSize().Width());
double fScaleY = static_cast<double>(aDstSize.Height()) / static_cast<double>(aTmpMtf.GetPrefSize().Height());
if( fScaleX != 1.0 || fScaleY != 1.0 )
aTmpMtf.Scale( fScaleX, fScaleY );
aTmpMtf.SetPrefMapMode( aMapMode );
// create paint bitmap
aTmpMtf.WindStart();
aTmpMtf.Play( xVDev.get(), aPoint, aDstSize );
aTmpMtf.WindStart();
xVDev->EnableMapMode( false );
aPaint = xVDev->GetBitmap( aPoint, aDstSizePixel );
xVDev->EnableMapMode();
// create mask bitmap
xVDev->SetLineColor( COL_BLACK );
xVDev->SetFillColor( COL_BLACK );
xVDev->DrawRect( tools::Rectangle( aPoint, aDstSize ) );
xVDev->SetDrawMode( DrawModeFlags::WhiteLine | DrawModeFlags::WhiteFill | DrawModeFlags::WhiteText |
DrawModeFlags::WhiteBitmap | DrawModeFlags::WhiteGradient );
aTmpMtf.WindStart();
aTmpMtf.Play( xVDev.get(), aPoint, aDstSize );
aTmpMtf.WindStart();
xVDev->EnableMapMode( false );
aMask = xVDev->GetBitmap( aPoint, aDstSizePixel );
xVDev->EnableMapMode();
// create alpha mask from gradient
xVDev->SetDrawMode( DrawModeFlags::GrayGradient );
xVDev->DrawGradient( tools::Rectangle( aPoint, aDstSize ), rTransparenceGradient );
xVDev->SetDrawMode( DrawModeFlags::Default );
xVDev->EnableMapMode( false );
xVDev->DrawMask( aPoint, aDstSizePixel, aMask, COL_WHITE );
aAlpha = xVDev->GetBitmap( aPoint, aDstSizePixel );
Graphic aGraphic = i_pOutDevData ? i_pOutDevData->GetCurrentGraphic() : Graphic();
implWriteBitmapEx( rPos, rSize, BitmapEx( aPaint, aAlpha ), aGraphic, pDummyVDev, i_rContext );
}
}
}
}
break;
case MetaActionType::EPS:
{
const MetaEPSAction* pA = static_cast<const MetaEPSAction*>(pAction);
const GDIMetaFile aSubstitute( pA->GetSubstitute() );
m_rOuterFace.Push();
pDummyVDev->Push();
MapMode aMapMode( aSubstitute.GetPrefMapMode() );
Size aOutSize( OutputDevice::LogicToLogic( pA->GetSize(), pDummyVDev->GetMapMode(), aMapMode ) );
aMapMode.SetScaleX( Fraction( aOutSize.Width(), aSubstitute.GetPrefSize().Width() ) );
aMapMode.SetScaleY( Fraction( aOutSize.Height(), aSubstitute.GetPrefSize().Height() ) );
aMapMode.SetOrigin( OutputDevice::LogicToLogic( pA->GetPoint(), pDummyVDev->GetMapMode(), aMapMode ) );
m_rOuterFace.SetMapMode( aMapMode );
pDummyVDev->SetMapMode( aMapMode );
playMetafile( aSubstitute, nullptr, i_rContext, pDummyVDev );
pDummyVDev->Pop();
m_rOuterFace.Pop();
}
break;
case MetaActionType::COMMENT:
if( ! i_rContext.m_bTransparenciesWereRemoved )
{
const MetaCommentAction* pA = static_cast<const MetaCommentAction*>(pAction);
if( pA->GetComment().equalsIgnoreAsciiCase("XGRAD_SEQ_BEGIN"))
{
const MetaGradientExAction* pGradAction = nullptr;
bool bDone = false;
while( !bDone && ( ++i < nCount ) )
{
pAction = aMtf.GetAction( i );
if( pAction->GetType() == MetaActionType::GRADIENTEX )
pGradAction = static_cast<const MetaGradientExAction*>(pAction);
else if( ( pAction->GetType() == MetaActionType::COMMENT ) &&
( static_cast<const MetaCommentAction*>(pAction)->GetComment().equalsIgnoreAsciiCase("XGRAD_SEQ_END")) )
{
bDone = true;
}
}
if( pGradAction )
{
if (lcl_canUsePDFAxialShading(pGradAction->GetGradient()))
{
m_rOuterFace.DrawGradient( pGradAction->GetPolyPolygon(), pGradAction->GetGradient() );
}
else
{
implWriteGradient( pGradAction->GetPolyPolygon(), pGradAction->GetGradient(), pDummyVDev, i_rContext );
}
}
}
else
{
const sal_uInt8* pData = pA->GetData();
if ( pData )
{
SvMemoryStream aMemStm( const_cast<sal_uInt8 *>(pData), pA->GetDataSize(), StreamMode::READ );
bool bSkipSequence = false;
OString sSeqEnd;
if( pA->GetComment() == "XPATHSTROKE_SEQ_BEGIN" )
{
sSeqEnd = OString("XPATHSTROKE_SEQ_END");
SvtGraphicStroke aStroke;
ReadSvtGraphicStroke( aMemStm, aStroke );
tools::Polygon aPath;
aStroke.getPath( aPath );
tools::PolyPolygon aStartArrow;
tools::PolyPolygon aEndArrow;
double fTransparency( aStroke.getTransparency() );
double fStrokeWidth( aStroke.getStrokeWidth() );
SvtGraphicStroke::DashArray aDashArray;
aStroke.getStartArrow( aStartArrow );
aStroke.getEndArrow( aEndArrow );
aStroke.getDashArray( aDashArray );
bSkipSequence = true;
if ( aStartArrow.Count() || aEndArrow.Count() )
bSkipSequence = false;
if ( aDashArray.size() && ( fStrokeWidth != 0.0 ) && ( fTransparency == 0.0 ) )
bSkipSequence = false;
if ( bSkipSequence )
{
PDFWriter::ExtLineInfo aInfo;
aInfo.m_fLineWidth = fStrokeWidth;
aInfo.m_fTransparency = fTransparency;
aInfo.m_fMiterLimit = aStroke.getMiterLimit();
switch( aStroke.getCapType() )
{
default:
case SvtGraphicStroke::capButt: aInfo.m_eCap = PDFWriter::capButt;break;
case SvtGraphicStroke::capRound: aInfo.m_eCap = PDFWriter::capRound;break;
case SvtGraphicStroke::capSquare: aInfo.m_eCap = PDFWriter::capSquare;break;
}
switch( aStroke.getJoinType() )
{
default:
case SvtGraphicStroke::joinMiter: aInfo.m_eJoin = PDFWriter::joinMiter;break;
case SvtGraphicStroke::joinRound: aInfo.m_eJoin = PDFWriter::joinRound;break;
case SvtGraphicStroke::joinBevel: aInfo.m_eJoin = PDFWriter::joinBevel;break;
case SvtGraphicStroke::joinNone:
aInfo.m_eJoin = PDFWriter::joinMiter;
aInfo.m_fMiterLimit = 0.0;
break;
}
aInfo.m_aDashArray = aDashArray;
if(SvtGraphicStroke::joinNone == aStroke.getJoinType()
&& fStrokeWidth > 0.0)
{
// emulate no edge rounding by handling single edges
const sal_uInt16 nPoints(aPath.GetSize());
const bool bCurve(aPath.HasFlags());
for(sal_uInt16 a(0); a + 1 < nPoints; a++)
{
if(bCurve
&& PolyFlags::Normal != aPath.GetFlags(a + 1)
&& a + 2 < nPoints
&& PolyFlags::Normal != aPath.GetFlags(a + 2)
&& a + 3 < nPoints)
{
const tools::Polygon aSnippet(4,
aPath.GetConstPointAry() + a,
aPath.GetConstFlagAry() + a);
m_rOuterFace.DrawPolyLine( aSnippet, aInfo );
a += 2;
}
else
{
const tools::Polygon aSnippet(2,
aPath.GetConstPointAry() + a);
m_rOuterFace.DrawPolyLine( aSnippet, aInfo );
}
}
}
else
{
m_rOuterFace.DrawPolyLine( aPath, aInfo );
}
}
}
else if ( pA->GetComment() == "XPATHFILL_SEQ_BEGIN" )
{
sSeqEnd = OString("XPATHFILL_SEQ_END");
SvtGraphicFill aFill;
ReadSvtGraphicFill( aMemStm, aFill );
if ( ( aFill.getFillType() == SvtGraphicFill::fillSolid ) && ( aFill.getFillRule() == SvtGraphicFill::fillEvenOdd ) )
{
double fTransparency = aFill.getTransparency();
if ( fTransparency == 0.0 )
{
tools::PolyPolygon aPath;
aFill.getPath( aPath );
bSkipSequence = true;
m_rOuterFace.DrawPolyPolygon( aPath );
}
else if ( fTransparency == 1.0 )
bSkipSequence = true;
}
/* #i81548# removing optimization for fill textures, because most of the texture settings are not
exported properly. In OpenOffice 3.1 the drawing layer will support graphic primitives, then it
will not be a problem to optimize the filltexture export. But for wysiwyg is more important than
filesize.
else if( aFill.getFillType() == SvtGraphicFill::fillTexture && aFill.isTiling() )
{
sal_Int32 nPattern = mnCachePatternId;
Graphic aPatternGraphic;
aFill.getGraphic( aPatternGraphic );
bool bUseCache = false;
SvtGraphicFill::Transform aPatTransform;
aFill.getTransform( aPatTransform );
if( mnCachePatternId >= 0 )
{
SvtGraphicFill::Transform aCacheTransform;
maCacheFill.getTransform( aCacheTransform );
if( aCacheTransform.matrix[0] == aPatTransform.matrix[0] &&
aCacheTransform.matrix[1] == aPatTransform.matrix[1] &&
aCacheTransform.matrix[2] == aPatTransform.matrix[2] &&
aCacheTransform.matrix[3] == aPatTransform.matrix[3] &&
aCacheTransform.matrix[4] == aPatTransform.matrix[4] &&
aCacheTransform.matrix[5] == aPatTransform.matrix[5]
)
{
Graphic aCacheGraphic;
maCacheFill.getGraphic( aCacheGraphic );
if( aCacheGraphic == aPatternGraphic )
bUseCache = true;
}
}
if( ! bUseCache )
{
// paint graphic to metafile
GDIMetaFile aPattern;
pDummyVDev->SetConnectMetaFile( &aPattern );
pDummyVDev->Push();
pDummyVDev->SetMapMode( aPatternGraphic.GetPrefMapMode() );
aPatternGraphic.Draw( &rDummyVDev, Point( 0, 0 ) );
pDummyVDev->Pop();
pDummyVDev->SetConnectMetaFile( NULL );
aPattern.WindStart();
MapMode aPatternMapMode( aPatternGraphic.GetPrefMapMode() );
// prepare pattern from metafile
Size aPrefSize( aPatternGraphic.GetPrefSize() );
// FIXME: this magic -1 shouldn't be necessary
aPrefSize.Width() -= 1;
aPrefSize.Height() -= 1;
aPrefSize = m_rOuterFace.GetReferenceDevice()->
LogicToLogic( aPrefSize,
&aPatternMapMode,
&m_rOuterFace.GetReferenceDevice()->GetMapMode() );
// build bounding rectangle of pattern
Rectangle aBound( Point( 0, 0 ), aPrefSize );
m_rOuterFace.BeginPattern( aBound );
m_rOuterFace.Push();
pDummyVDev->Push();
m_rOuterFace.SetMapMode( aPatternMapMode );
pDummyVDev->SetMapMode( aPatternMapMode );
ImplWriteActions( m_rOuterFace, NULL, aPattern, rDummyVDev );
pDummyVDev->Pop();
m_rOuterFace.Pop();
nPattern = m_rOuterFace.EndPattern( aPatTransform );
// try some caching and reuse pattern
mnCachePatternId = nPattern;
maCacheFill = aFill;
}
// draw polypolygon with pattern fill
tools::PolyPolygon aPath;
aFill.getPath( aPath );
m_rOuterFace.DrawPolyPolygon( aPath, nPattern, aFill.getFillRule() == SvtGraphicFill::fillEvenOdd );
bSkipSequence = true;
}
*/
}
if ( bSkipSequence )
{
while( ++i < nCount )
{
pAction = aMtf.GetAction( i );
if ( pAction->GetType() == MetaActionType::COMMENT )
{
OString sComment( static_cast<const MetaCommentAction*>(pAction)->GetComment() );
if (sComment == sSeqEnd)
break;
}
// #i44496#
// the replacement action for stroke is a filled rectangle
// the set fillcolor of the replacement is part of the graphics
// state and must not be skipped
else if( pAction->GetType() == MetaActionType::FILLCOLOR )
{
const MetaFillColorAction* pMA = static_cast<const MetaFillColorAction*>(pAction);
if( pMA->IsSetting() )
m_rOuterFace.SetFillColor( pMA->GetColor() );
else
m_rOuterFace.SetFillColor();
}
}
}
}
}
}
break;
case MetaActionType::BMP:
{
const MetaBmpAction* pA = static_cast<const MetaBmpAction*>(pAction);
BitmapEx aBitmapEx( pA->GetBitmap() );
Size aSize( OutputDevice::LogicToLogic( aBitmapEx.GetPrefSize(),
aBitmapEx.GetPrefMapMode(), pDummyVDev->GetMapMode() ) );
if( ! ( aSize.Width() && aSize.Height() ) )
aSize = pDummyVDev->PixelToLogic( aBitmapEx.GetSizePixel() );
Graphic aGraphic = i_pOutDevData ? i_pOutDevData->GetCurrentGraphic() : Graphic();
implWriteBitmapEx( pA->GetPoint(), aSize, aBitmapEx, aGraphic, pDummyVDev, i_rContext );
}
break;
case MetaActionType::BMPSCALE:
{
const MetaBmpScaleAction* pA = static_cast<const MetaBmpScaleAction*>(pAction);
Graphic aGraphic = i_pOutDevData ? i_pOutDevData->GetCurrentGraphic() : Graphic();
implWriteBitmapEx( pA->GetPoint(), pA->GetSize(), BitmapEx( pA->GetBitmap() ), aGraphic, pDummyVDev, i_rContext );
}
break;
case MetaActionType::BMPSCALEPART:
{
const MetaBmpScalePartAction* pA = static_cast<const MetaBmpScalePartAction*>(pAction);
BitmapEx aBitmapEx( pA->GetBitmap() );
aBitmapEx.Crop( tools::Rectangle( pA->GetSrcPoint(), pA->GetSrcSize() ) );
Graphic aGraphic = i_pOutDevData ? i_pOutDevData->GetCurrentGraphic() : Graphic();
implWriteBitmapEx( pA->GetDestPoint(), pA->GetDestSize(), aBitmapEx, aGraphic, pDummyVDev, i_rContext );
}
break;
case MetaActionType::BMPEX:
{
const MetaBmpExAction* pA = static_cast<const MetaBmpExAction*>(pAction);
BitmapEx aBitmapEx( pA->GetBitmapEx() );
Size aSize( OutputDevice::LogicToLogic( aBitmapEx.GetPrefSize(),
aBitmapEx.GetPrefMapMode(), pDummyVDev->GetMapMode() ) );
Graphic aGraphic = i_pOutDevData ? i_pOutDevData->GetCurrentGraphic() : Graphic();
implWriteBitmapEx( pA->GetPoint(), aSize, aBitmapEx, aGraphic, pDummyVDev, i_rContext );
}
break;
case MetaActionType::BMPEXSCALE:
{
const MetaBmpExScaleAction* pA = static_cast<const MetaBmpExScaleAction*>(pAction);
Graphic aGraphic = i_pOutDevData ? i_pOutDevData->GetCurrentGraphic() : Graphic();
implWriteBitmapEx( pA->GetPoint(), pA->GetSize(), pA->GetBitmapEx(), aGraphic, pDummyVDev, i_rContext );
}
break;
case MetaActionType::BMPEXSCALEPART:
{
const MetaBmpExScalePartAction* pA = static_cast<const MetaBmpExScalePartAction*>(pAction);
BitmapEx aBitmapEx( pA->GetBitmapEx() );
aBitmapEx.Crop( tools::Rectangle( pA->GetSrcPoint(), pA->GetSrcSize() ) );
Graphic aGraphic = i_pOutDevData ? i_pOutDevData->GetCurrentGraphic() : Graphic();
implWriteBitmapEx( pA->GetDestPoint(), pA->GetDestSize(), aBitmapEx, aGraphic, pDummyVDev, i_rContext );
}
break;
case MetaActionType::MASK:
case MetaActionType::MASKSCALE:
case MetaActionType::MASKSCALEPART:
{
SAL_WARN( "vcl", "MetaMask...Action not supported yet" );
}
break;
case MetaActionType::TEXT:
{
const MetaTextAction* pA = static_cast<const MetaTextAction*>(pAction);
m_rOuterFace.DrawText( pA->GetPoint(), pA->GetText().copy( pA->GetIndex(), std::min<sal_Int32>(pA->GetText().getLength() - pA->GetIndex(), pA->GetLen()) ) );
}
break;
case MetaActionType::TEXTRECT:
{
const MetaTextRectAction* pA = static_cast<const MetaTextRectAction*>(pAction);
m_rOuterFace.DrawText( pA->GetRect(), pA->GetText(), pA->GetStyle() );
}
break;
case MetaActionType::TEXTARRAY:
{
const MetaTextArrayAction* pA = static_cast<const MetaTextArrayAction*>(pAction);
m_rOuterFace.DrawTextArray( pA->GetPoint(), pA->GetText(), pA->GetDXArray(), pA->GetIndex(), pA->GetLen() );
}
break;
case MetaActionType::STRETCHTEXT:
{
const MetaStretchTextAction* pA = static_cast<const MetaStretchTextAction*>(pAction);
m_rOuterFace.DrawStretchText( pA->GetPoint(), pA->GetWidth(), pA->GetText(), pA->GetIndex(), pA->GetLen() );
}
break;
case MetaActionType::TEXTLINE:
{
const MetaTextLineAction* pA = static_cast<const MetaTextLineAction*>(pAction);
m_rOuterFace.DrawTextLine( pA->GetStartPoint(), pA->GetWidth(), pA->GetStrikeout(), pA->GetUnderline(), pA->GetOverline() );
}
break;
case MetaActionType::CLIPREGION:
{
const MetaClipRegionAction* pA = static_cast<const MetaClipRegionAction*>(pAction);
if( pA->IsClipping() )
{
if( pA->GetRegion().IsEmpty() )
m_rOuterFace.SetClipRegion( basegfx::B2DPolyPolygon() );
else
{
vcl::Region aReg( pA->GetRegion() );
m_rOuterFace.SetClipRegion( aReg.GetAsB2DPolyPolygon() );
}
}
else
m_rOuterFace.SetClipRegion();
}
break;
case MetaActionType::ISECTRECTCLIPREGION:
{
const MetaISectRectClipRegionAction* pA = static_cast<const MetaISectRectClipRegionAction*>(pAction);
m_rOuterFace.IntersectClipRegion( pA->GetRect() );
}
break;
case MetaActionType::ISECTREGIONCLIPREGION:
{
const MetaISectRegionClipRegionAction* pA = static_cast<const MetaISectRegionClipRegionAction*>(pAction);
vcl::Region aReg( pA->GetRegion() );
m_rOuterFace.IntersectClipRegion( aReg.GetAsB2DPolyPolygon() );
}
break;
case MetaActionType::MOVECLIPREGION:
{
const MetaMoveClipRegionAction* pA = static_cast<const MetaMoveClipRegionAction*>(pAction);
m_rOuterFace.MoveClipRegion( pA->GetHorzMove(), pA->GetVertMove() );
}
break;
case MetaActionType::MAPMODE:
{
const_cast< MetaAction* >( pAction )->Execute( pDummyVDev );
m_rOuterFace.SetMapMode( pDummyVDev->GetMapMode() );
}
break;
case MetaActionType::LINECOLOR:
{
const MetaLineColorAction* pA = static_cast<const MetaLineColorAction*>(pAction);
if( pA->IsSetting() )
m_rOuterFace.SetLineColor( pA->GetColor() );
else
m_rOuterFace.SetLineColor();
}
break;
case MetaActionType::FILLCOLOR:
{
const MetaFillColorAction* pA = static_cast<const MetaFillColorAction*>(pAction);
if( pA->IsSetting() )
m_rOuterFace.SetFillColor( pA->GetColor() );
else
m_rOuterFace.SetFillColor();
}
break;
case MetaActionType::TEXTLINECOLOR:
{
const MetaTextLineColorAction* pA = static_cast<const MetaTextLineColorAction*>(pAction);
if( pA->IsSetting() )
m_rOuterFace.SetTextLineColor( pA->GetColor() );
else
m_rOuterFace.SetTextLineColor();
}
break;
case MetaActionType::OVERLINECOLOR:
{
const MetaOverlineColorAction* pA = static_cast<const MetaOverlineColorAction*>(pAction);
if( pA->IsSetting() )
m_rOuterFace.SetOverlineColor( pA->GetColor() );
else
m_rOuterFace.SetOverlineColor();
}
break;
case MetaActionType::TEXTFILLCOLOR:
{
const MetaTextFillColorAction* pA = static_cast<const MetaTextFillColorAction*>(pAction);
if( pA->IsSetting() )
m_rOuterFace.SetTextFillColor( pA->GetColor() );
else
m_rOuterFace.SetTextFillColor();
}
break;
case MetaActionType::TEXTCOLOR:
{
const MetaTextColorAction* pA = static_cast<const MetaTextColorAction*>(pAction);
m_rOuterFace.SetTextColor( pA->GetColor() );
}
break;
case MetaActionType::TEXTALIGN:
{
const MetaTextAlignAction* pA = static_cast<const MetaTextAlignAction*>(pAction);
m_rOuterFace.SetTextAlign( pA->GetTextAlign() );
}
break;
case MetaActionType::FONT:
{
const MetaFontAction* pA = static_cast<const MetaFontAction*>(pAction);
m_rOuterFace.SetFont( pA->GetFont() );
}
break;
case MetaActionType::PUSH:
{
const MetaPushAction* pA = static_cast<const MetaPushAction*>(pAction);
pDummyVDev->Push( pA->GetFlags() );
m_rOuterFace.Push( pA->GetFlags() );
}
break;
case MetaActionType::POP:
{
pDummyVDev->Pop();
m_rOuterFace.Pop();
}
break;
case MetaActionType::LAYOUTMODE:
{
const MetaLayoutModeAction* pA = static_cast<const MetaLayoutModeAction*>(pAction);
m_rOuterFace.SetLayoutMode( pA->GetLayoutMode() );
}
break;
case MetaActionType::TEXTLANGUAGE:
{
const MetaTextLanguageAction* pA = static_cast<const MetaTextLanguageAction*>(pAction);
m_rOuterFace.SetDigitLanguage( pA->GetTextLanguage() );
}
break;
case MetaActionType::WALLPAPER:
{
const MetaWallpaperAction* pA = static_cast<const MetaWallpaperAction*>(pAction);
m_rOuterFace.DrawWallpaper( pA->GetRect(), pA->GetWallpaper() );
}
break;
case MetaActionType::RASTEROP:
{
// !!! >>> we don't want to support this actions
}
break;
case MetaActionType::REFPOINT:
{
// !!! >>> we don't want to support this actions
}
break;
default:
// #i24604# Made assertion fire only once per
// metafile. The asserted actions here are all
// deprecated
if( !bAssertionFired )
{
bAssertionFired = true;
SAL_WARN( "vcl", "PDFExport::ImplWriteActions: deprecated and unsupported MetaAction encountered " << static_cast<int>(nType) );
}
break;
}
i++;
}
}
}
// Encryption methods
/* a crutch to transport a ::comphelper::Hash safely though UNO API
this is needed for the PDF export dialog, which otherwise would have to pass
clear text passwords down till they can be used in PDFWriter. Unfortunately
the MD5 sum of the password (which is needed to create the PDF encryption key)
is not sufficient, since an MD5 digest cannot be created in an arbitrary state
which would be needed in PDFWriterImpl::computeEncryptionKey.
*/
class EncHashTransporter : public cppu::WeakImplHelper < css::beans::XMaterialHolder >
{
::std::unique_ptr<::comphelper::Hash> m_pDigest;
sal_IntPtr maID;
std::vector< sal_uInt8 > maOValue;
static std::map< sal_IntPtr, EncHashTransporter* > sTransporters;
public:
EncHashTransporter()
: m_pDigest(new ::comphelper::Hash(::comphelper::HashType::MD5))
{
maID = reinterpret_cast< sal_IntPtr >(this);
while( sTransporters.find( maID ) != sTransporters.end() ) // paranoia mode
maID++;
sTransporters[ maID ] = this;
}
virtual ~EncHashTransporter() override
{
sTransporters.erase( maID );
SAL_INFO( "vcl", "EncHashTransporter freed" );
}
::comphelper::Hash* getUDigest() { return m_pDigest.get(); };
std::vector< sal_uInt8 >& getOValue() { return maOValue; }
void invalidate()
{
m_pDigest.reset();
}
// XMaterialHolder
virtual uno::Any SAL_CALL getMaterial() override
{
return uno::makeAny( sal_Int64(maID) );
}
static EncHashTransporter* getEncHashTransporter( const uno::Reference< beans::XMaterialHolder >& );
};
std::map< sal_IntPtr, EncHashTransporter* > EncHashTransporter::sTransporters;
EncHashTransporter* EncHashTransporter::getEncHashTransporter( const uno::Reference< beans::XMaterialHolder >& xRef )
{
EncHashTransporter* pResult = nullptr;
if( xRef.is() )
{
uno::Any aMat( xRef->getMaterial() );
sal_Int64 nMat = 0;
if( aMat >>= nMat )
{
std::map< sal_IntPtr, EncHashTransporter* >::iterator it = sTransporters.find( static_cast<sal_IntPtr>(nMat) );
if( it != sTransporters.end() )
pResult = it->second;
}
}
return pResult;
}
bool PDFWriterImpl::checkEncryptionBufferSize( sal_Int32 newSize )
{
if( m_nEncryptionBufferSize < newSize )
{
/* reallocate the buffer */
m_pEncryptionBuffer = static_cast<sal_uInt8*>(std::realloc( m_pEncryptionBuffer, newSize ));
if( m_pEncryptionBuffer )
m_nEncryptionBufferSize = newSize;
else
m_nEncryptionBufferSize = 0;
}
return ( m_nEncryptionBufferSize != 0 );
}
void PDFWriterImpl::checkAndEnableStreamEncryption( sal_Int32 nObject )
{
if( m_aContext.Encryption.Encrypt() )
{
m_bEncryptThisStream = true;
sal_Int32 i = m_nKeyLength;
m_aContext.Encryption.EncryptionKey[i++] = static_cast<sal_uInt8>(nObject);
m_aContext.Encryption.EncryptionKey[i++] = static_cast<sal_uInt8>( nObject >> 8 );
m_aContext.Encryption.EncryptionKey[i++] = static_cast<sal_uInt8>( nObject >> 16 );
// the other location of m_nEncryptionKey is already set to 0, our fixed generation number
// do the MD5 hash
::std::vector<unsigned char> const nMD5Sum(::comphelper::Hash::calculateHash(
&m_aContext.Encryption.EncryptionKey[0], i+2, ::comphelper::HashType::MD5));
// the i+2 to take into account the generation number, always zero
// initialize the RC4 with the key
// key length: see algorithm 3.1, step 4: (N+5) max 16
rtl_cipher_initARCFOUR( m_aCipher, rtl_Cipher_DirectionEncode, nMD5Sum.data(), m_nRC4KeyLength, nullptr, 0 );
}
}
void PDFWriterImpl::enableStringEncryption( sal_Int32 nObject )
{
if( m_aContext.Encryption.Encrypt() )
{
sal_Int32 i = m_nKeyLength;
m_aContext.Encryption.EncryptionKey[i++] = static_cast<sal_uInt8>(nObject);
m_aContext.Encryption.EncryptionKey[i++] = static_cast<sal_uInt8>( nObject >> 8 );
m_aContext.Encryption.EncryptionKey[i++] = static_cast<sal_uInt8>( nObject >> 16 );
// the other location of m_nEncryptionKey is already set to 0, our fixed generation number
// do the MD5 hash
// the i+2 to take into account the generation number, always zero
::std::vector<unsigned char> const nMD5Sum(::comphelper::Hash::calculateHash(
&m_aContext.Encryption.EncryptionKey[0], i+2, ::comphelper::HashType::MD5));
// initialize the RC4 with the key
// key length: see algorithm 3.1, step 4: (N+5) max 16
rtl_cipher_initARCFOUR( m_aCipher, rtl_Cipher_DirectionEncode, nMD5Sum.data(), m_nRC4KeyLength, nullptr, 0 );
}
}
/* init the encryption engine
1. init the document id, used both for building the document id and for building the encryption key(s)
2. build the encryption key following algorithms described in the PDF specification
*/
uno::Reference< beans::XMaterialHolder > PDFWriterImpl::initEncryption( const OUString& i_rOwnerPassword,
const OUString& i_rUserPassword
)
{
uno::Reference< beans::XMaterialHolder > xResult;
if( !i_rOwnerPassword.isEmpty() || !i_rUserPassword.isEmpty() )
{
EncHashTransporter* pTransporter = new EncHashTransporter;
xResult = pTransporter;
// get padded passwords
sal_uInt8 aPadUPW[ENCRYPTED_PWD_SIZE], aPadOPW[ENCRYPTED_PWD_SIZE];
padPassword( i_rOwnerPassword.isEmpty() ? i_rUserPassword : i_rOwnerPassword, aPadOPW );
padPassword( i_rUserPassword, aPadUPW );
if( computeODictionaryValue( aPadOPW, aPadUPW, pTransporter->getOValue(), SECUR_128BIT_KEY ) )
{
pTransporter->getUDigest()->update(aPadUPW, ENCRYPTED_PWD_SIZE);
}
else
xResult.clear();
// trash temporary padded cleartext PWDs
rtl_secureZeroMemory (aPadOPW, sizeof(aPadOPW));
rtl_secureZeroMemory (aPadUPW, sizeof(aPadUPW));
}
return xResult;
}
bool PDFWriterImpl::prepareEncryption( const uno::Reference< beans::XMaterialHolder >& xEnc )
{
bool bSuccess = false;
EncHashTransporter* pTransporter = EncHashTransporter::getEncHashTransporter( xEnc );
if( pTransporter )
{
sal_Int32 nKeyLength = 0, nRC4KeyLength = 0;
sal_Int32 nAccessPermissions = computeAccessPermissions( m_aContext.Encryption, nKeyLength, nRC4KeyLength );
m_aContext.Encryption.OValue = pTransporter->getOValue();
bSuccess = computeUDictionaryValue( pTransporter, m_aContext.Encryption, nKeyLength, nAccessPermissions );
}
if( ! bSuccess )
{
m_aContext.Encryption.OValue.clear();
m_aContext.Encryption.UValue.clear();
m_aContext.Encryption.EncryptionKey.clear();
}
return bSuccess;
}
sal_Int32 PDFWriterImpl::computeAccessPermissions( const vcl::PDFWriter::PDFEncryptionProperties& i_rProperties,
sal_Int32& o_rKeyLength, sal_Int32& o_rRC4KeyLength )
{
/*
2) compute the access permissions, in numerical form
the default value depends on the revision 2 (40 bit) or 3 (128 bit security):
- for 40 bit security the unused bit must be set to 1, since they are not used
- for 128 bit security the same bit must be preset to 0 and set later if needed
according to the table 3.15, pdf v 1.4 */
sal_Int32 nAccessPermissions = 0xfffff0c0;
/* check permissions for 40 bit security case */
nAccessPermissions |= ( i_rProperties.CanPrintTheDocument ) ? 1 << 2 : 0;
nAccessPermissions |= ( i_rProperties.CanModifyTheContent ) ? 1 << 3 : 0;
nAccessPermissions |= ( i_rProperties.CanCopyOrExtract ) ? 1 << 4 : 0;
nAccessPermissions |= ( i_rProperties.CanAddOrModify ) ? 1 << 5 : 0;
o_rKeyLength = SECUR_40BIT_KEY;
o_rRC4KeyLength = SECUR_40BIT_KEY+5; // for this value see PDF spec v 1.4, algorithm 3.1 step 4, where n is 5
o_rKeyLength = SECUR_128BIT_KEY;
o_rRC4KeyLength = 16; // for this value see PDF spec v 1.4, algorithm 3.1 step 4, where n is 16, thus maximum
// permitted value is 16
nAccessPermissions |= ( i_rProperties.CanFillInteractive ) ? 1 << 8 : 0;
nAccessPermissions |= ( i_rProperties.CanExtractForAccessibility ) ? 1 << 9 : 0;
nAccessPermissions |= ( i_rProperties.CanAssemble ) ? 1 << 10 : 0;
nAccessPermissions |= ( i_rProperties.CanPrintFull ) ? 1 << 11 : 0;
return nAccessPermissions;
}
/*************************************************************
begin i12626 methods
Implements Algorithm 3.2, step 1 only
*/
void PDFWriterImpl::padPassword( const OUString& i_rPassword, sal_uInt8* o_pPaddedPW )
{
// get ansi-1252 version of the password string CHECKIT ! i12626
OString aString( OUStringToOString( i_rPassword, RTL_TEXTENCODING_MS_1252 ) );
//copy the string to the target
sal_Int32 nToCopy = ( aString.getLength() < ENCRYPTED_PWD_SIZE ) ? aString.getLength() : ENCRYPTED_PWD_SIZE;
sal_Int32 nCurrentChar;
for( nCurrentChar = 0; nCurrentChar < nToCopy; nCurrentChar++ )
o_pPaddedPW[nCurrentChar] = static_cast<sal_uInt8>( aString[nCurrentChar] );
//pad it with standard byte string
sal_Int32 i,y;
for( i = nCurrentChar, y = 0 ; i < ENCRYPTED_PWD_SIZE; i++, y++ )
o_pPaddedPW[i] = s_nPadString[y];
}
/**********************************
Algorithm 3.2 Compute the encryption key used
step 1 should already be done before calling, the paThePaddedPassword parameter should contain
the padded password and must be 32 byte long, the encryption key is returned into the paEncryptionKey parameter,
it will be 16 byte long for 128 bit security; for 40 bit security only the first 5 bytes are used
TODO: in pdf ver 1.5 and 1.6 the step 6 is different, should be implemented. See spec.
*/
bool PDFWriterImpl::computeEncryptionKey( EncHashTransporter* i_pTransporter, vcl::PDFWriter::PDFEncryptionProperties& io_rProperties, sal_Int32 i_nAccessPermissions )
{
bool bSuccess = true;
::std::vector<unsigned char> nMD5Sum;
// transporter contains an MD5 digest with the padded user password already
::comphelper::Hash *const pDigest = i_pTransporter->getUDigest();
if (pDigest)
{
//step 3
if( ! io_rProperties.OValue.empty() )
pDigest->update(&io_rProperties.OValue[0], io_rProperties.OValue.size());
else
bSuccess = false;
//Step 4
sal_uInt8 nPerm[4];
nPerm[0] = static_cast<sal_uInt8>(i_nAccessPermissions);
nPerm[1] = static_cast<sal_uInt8>( i_nAccessPermissions >> 8 );
nPerm[2] = static_cast<sal_uInt8>( i_nAccessPermissions >> 16 );
nPerm[3] = static_cast<sal_uInt8>( i_nAccessPermissions >> 24 );
pDigest->update(nPerm, sizeof(nPerm));
//step 5, get the document ID, binary form
pDigest->update(&io_rProperties.DocumentIdentifier[0], io_rProperties.DocumentIdentifier.size());
//get the digest
nMD5Sum = pDigest->finalize();
//step 6, only if 128 bit
for (sal_Int32 i = 0; i < 50; i++)
{
nMD5Sum = ::comphelper::Hash::calculateHash(nMD5Sum.data(), nMD5Sum.size(), ::comphelper::HashType::MD5);
}
}
else
bSuccess = false;
i_pTransporter->invalidate();
//Step 7
if( bSuccess )
{
io_rProperties.EncryptionKey.resize( MAXIMUM_RC4_KEY_LENGTH );
for( sal_Int32 i = 0; i < MD5_DIGEST_SIZE; i++ )
io_rProperties.EncryptionKey[i] = nMD5Sum[i];
}
else
io_rProperties.EncryptionKey.clear();
return bSuccess;
}
/**********************************
Algorithm 3.3 Compute the encryption dictionary /O value, save into the class data member
the step numbers down here correspond to the ones in PDF v.1.4 specification
*/
bool PDFWriterImpl::computeODictionaryValue( const sal_uInt8* i_pPaddedOwnerPassword,
const sal_uInt8* i_pPaddedUserPassword,
std::vector< sal_uInt8 >& io_rOValue,
sal_Int32 i_nKeyLength
)
{
bool bSuccess = true;
io_rOValue.resize( ENCRYPTED_PWD_SIZE );
rtlCipher aCipher = rtl_cipher_createARCFOUR( rtl_Cipher_ModeStream );
if (aCipher)
{
//step 1 already done, data is in i_pPaddedOwnerPassword
//step 2
::std::vector<unsigned char> nMD5Sum(::comphelper::Hash::calculateHash(
i_pPaddedOwnerPassword, ENCRYPTED_PWD_SIZE, ::comphelper::HashType::MD5));
//step 3, only if 128 bit
if (i_nKeyLength == SECUR_128BIT_KEY)
{
sal_Int32 i;
for (i = 0; i < 50; i++)
{
nMD5Sum = ::comphelper::Hash::calculateHash(nMD5Sum.data(), nMD5Sum.size(), ::comphelper::HashType::MD5);
}
}
//Step 4, the key is in nMD5Sum
//step 5 already done, data is in i_pPaddedUserPassword
//step 6
if (rtl_cipher_initARCFOUR( aCipher, rtl_Cipher_DirectionEncode,
nMD5Sum.data(), i_nKeyLength , nullptr, 0 )
== rtl_Cipher_E_None)
{
// encrypt the user password using the key set above
rtl_cipher_encodeARCFOUR( aCipher, i_pPaddedUserPassword, ENCRYPTED_PWD_SIZE, // the data to be encrypted
&io_rOValue[0], sal_Int32(io_rOValue.size()) ); //encrypted data
//Step 7, only if 128 bit
if( i_nKeyLength == SECUR_128BIT_KEY )
{
sal_uInt32 i, y;
sal_uInt8 nLocalKey[ SECUR_128BIT_KEY ]; // 16 = 128 bit key
for( i = 1; i <= 19; i++ ) // do it 19 times, start with 1
{
for( y = 0; y < sizeof( nLocalKey ); y++ )
nLocalKey[y] = static_cast<sal_uInt8>( nMD5Sum[y] ^ i );
if (rtl_cipher_initARCFOUR( aCipher, rtl_Cipher_DirectionEncode,
nLocalKey, SECUR_128BIT_KEY, nullptr, 0 ) //destination data area, on init can be NULL
!= rtl_Cipher_E_None)
{
bSuccess = false;
break;
}
rtl_cipher_encodeARCFOUR( aCipher, &io_rOValue[0], sal_Int32(io_rOValue.size()), // the data to be encrypted
&io_rOValue[0], sal_Int32(io_rOValue.size()) ); // encrypted data, can be the same as the input, encrypt "in place"
//step 8, store in class data member
}
}
}
else
bSuccess = false;
}
else
bSuccess = false;
if( aCipher )
rtl_cipher_destroyARCFOUR( aCipher );
if( ! bSuccess )
io_rOValue.clear();
return bSuccess;
}
/**********************************
Algorithms 3.4 and 3.5 Compute the encryption dictionary /U value, save into the class data member, revision 2 (40 bit) or 3 (128 bit)
*/
bool PDFWriterImpl::computeUDictionaryValue( EncHashTransporter* i_pTransporter,
vcl::PDFWriter::PDFEncryptionProperties& io_rProperties,
sal_Int32 i_nKeyLength,
sal_Int32 i_nAccessPermissions
)
{
bool bSuccess = true;
io_rProperties.UValue.resize( ENCRYPTED_PWD_SIZE );
::comphelper::Hash aDigest(::comphelper::HashType::MD5);
rtlCipher aCipher = rtl_cipher_createARCFOUR( rtl_Cipher_ModeStream );
if (aCipher)
{
//step 1, common to both 3.4 and 3.5
if( computeEncryptionKey( i_pTransporter, io_rProperties, i_nAccessPermissions ) )
{
// prepare encryption key for object
for( sal_Int32 i = i_nKeyLength, y = 0; y < 5 ; y++ )
io_rProperties.EncryptionKey[i++] = 0;
//or 3.5, for 128 bit security
//step6, initialize the last 16 bytes of the encrypted user password to 0
for(sal_uInt32 i = MD5_DIGEST_SIZE; i < sal_uInt32(io_rProperties.UValue.size()); i++)
io_rProperties.UValue[i] = 0;
//steps 2 and 3
aDigest.update(s_nPadString, sizeof(s_nPadString));
aDigest.update(&io_rProperties.DocumentIdentifier[0], io_rProperties.DocumentIdentifier.size());
::std::vector<unsigned char> const nMD5Sum(aDigest.finalize());
//Step 4
rtl_cipher_initARCFOUR( aCipher, rtl_Cipher_DirectionEncode,
&io_rProperties.EncryptionKey[0], SECUR_128BIT_KEY, nullptr, 0 ); //destination data area
rtl_cipher_encodeARCFOUR( aCipher, nMD5Sum.data(), nMD5Sum.size(), // the data to be encrypted
&io_rProperties.UValue[0], SECUR_128BIT_KEY ); //encrypted data, stored in class data member
//step 5
sal_uInt32 i, y;
sal_uInt8 nLocalKey[SECUR_128BIT_KEY];
for( i = 1; i <= 19; i++ ) // do it 19 times, start with 1
{
for( y = 0; y < sizeof( nLocalKey ) ; y++ )
nLocalKey[y] = static_cast<sal_uInt8>( io_rProperties.EncryptionKey[y] ^ i );
rtl_cipher_initARCFOUR( aCipher, rtl_Cipher_DirectionEncode,
nLocalKey, SECUR_128BIT_KEY, // key and key length
nullptr, 0 ); //destination data area, on init can be NULL
rtl_cipher_encodeARCFOUR( aCipher, &io_rProperties.UValue[0], SECUR_128BIT_KEY, // the data to be encrypted
&io_rProperties.UValue[0], SECUR_128BIT_KEY ); // encrypted data, can be the same as the input, encrypt "in place"
}
}
else
bSuccess = false;
}
else
bSuccess = false;
if( aCipher )
rtl_cipher_destroyARCFOUR( aCipher );
if( ! bSuccess )
io_rProperties.UValue.clear();
return bSuccess;
}
/* end i12626 methods */
static const long unsetRun[256] =
{
8, 7, 6, 6, 5, 5, 5, 5, 4, 4, 4, 4, 4, 4, 4, 4, /* 0x00 - 0x0f */
3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, /* 0x10 - 0x1f */
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 0x20 - 0x2f */
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 0x30 - 0x3f */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x40 - 0x4f */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x50 - 0x5f */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x60 - 0x6f */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x70 - 0x7f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x80 - 0x8f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x90 - 0x9f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0xa0 - 0xaf */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0xb0 - 0xbf */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0xc0 - 0xcf */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0xd0 - 0xdf */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0xe0 - 0xef */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0xf0 - 0xff */
};
static const long setRun[256] =
{
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x00 - 0x0f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x10 - 0x1f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x20 - 0x2f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x30 - 0x3f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x40 - 0x4f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x50 - 0x5f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x60 - 0x6f */
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x70 - 0x7f */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x80 - 0x8f */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0x90 - 0x9f */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0xa0 - 0xaf */
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 0xb0 - 0xbf */
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 0xc0 - 0xcf */
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, /* 0xd0 - 0xdf */
3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, /* 0xe0 - 0xef */
4, 4, 4, 4, 4, 4, 4, 4, 5, 5, 5, 5, 6, 6, 7, 8, /* 0xf0 - 0xff */
};
inline bool isSet( const Scanline i_pLine, long i_nIndex )
{
return (i_pLine[ i_nIndex/8 ] & (0x80 >> (i_nIndex&7))) != 0;
}
long findBitRunImpl( const Scanline i_pLine, long i_nStartIndex, long i_nW, bool i_bSet )
{
long nIndex = i_nStartIndex;
if( nIndex < i_nW )
{
const sal_uInt8 * pByte = i_pLine + (nIndex/8);
sal_uInt8 nByte = *pByte;
// run up to byte boundary
long nBitInByte = (nIndex & 7);
if( nBitInByte )
{
sal_uInt8 nMask = 0x80 >> nBitInByte;
while( nBitInByte != 8 )
{
if( (nByte & nMask) != (i_bSet ? nMask : 0) )
return std::min(nIndex, i_nW);
nMask = nMask >> 1;
nBitInByte++;
nIndex++;
}
if( nIndex < i_nW )
{
pByte++;
nByte = *pByte;
}
}
sal_uInt8 nRunByte;
const long* pRunTable;
if( i_bSet )
{
nRunByte = 0xff;
pRunTable = setRun;
}
else
{
nRunByte = 0;
pRunTable = unsetRun;
}
if( nIndex < i_nW )
{
while( nByte == nRunByte )
{
nIndex += 8;
if (nIndex >= i_nW)
break;
pByte++;
nByte = *pByte;
}
}
if( nIndex < i_nW )
{
nIndex += pRunTable[nByte];
}
}
return std::min(nIndex, i_nW);
}
long findBitRun(const Scanline i_pLine, long i_nStartIndex, long i_nW, bool i_bSet)
{
if (i_nStartIndex < 0)
return i_nW;
return findBitRunImpl(i_pLine, i_nStartIndex, i_nW, i_bSet);
}
long findBitRun(const Scanline i_pLine, long i_nStartIndex, long i_nW)
{
if (i_nStartIndex < 0)
return i_nW;
const bool bSet = i_nStartIndex < i_nW && isSet(i_pLine, i_nStartIndex);
return findBitRunImpl(i_pLine, i_nStartIndex, i_nW, bSet);
}
struct BitStreamState
{
sal_uInt8 mnBuffer;
sal_uInt32 mnNextBitPos;
BitStreamState()
: mnBuffer( 0 )
, mnNextBitPos( 8 )
{
}
const sal_uInt8& getByte() const { return mnBuffer; }
void flush() { mnNextBitPos = 8; mnBuffer = 0; }
};
void PDFWriterImpl::putG4Bits( sal_uInt32 i_nLength, sal_uInt32 i_nCode, BitStreamState& io_rState )
{
while( i_nLength > io_rState.mnNextBitPos )
{
io_rState.mnBuffer |= static_cast<sal_uInt8>( i_nCode >> (i_nLength - io_rState.mnNextBitPos) );
i_nLength -= io_rState.mnNextBitPos;
writeBuffer( &io_rState.getByte(), 1 );
io_rState.flush();
}
assert(i_nLength < 9);
static const unsigned int msbmask[9] = { 0x00, 0x01, 0x03, 0x07, 0x0f, 0x1f, 0x3f, 0x7f, 0xff };
io_rState.mnBuffer |= static_cast<sal_uInt8>( (i_nCode & msbmask[i_nLength]) << (io_rState.mnNextBitPos - i_nLength) );
io_rState.mnNextBitPos -= i_nLength;
if( io_rState.mnNextBitPos == 0 )
{
writeBuffer( &io_rState.getByte(), 1 );
io_rState.flush();
}
}
struct PixelCode
{
sal_uInt32 const mnEncodedPixels;
sal_uInt32 const mnCodeBits;
sal_uInt32 const mnCode;
};
static const PixelCode WhitePixelCodes[] =
{
{ 0, 8, 0x35 }, // 0011 0101
{ 1, 6, 0x7 }, // 0001 11
{ 2, 4, 0x7 }, // 0111
{ 3, 4, 0x8 }, // 1000
{ 4, 4, 0xB }, // 1011
{ 5, 4, 0xC }, // 1100
{ 6, 4, 0xE }, // 1110
{ 7, 4, 0xF }, // 1111
{ 8, 5, 0x13 }, // 1001 1
{ 9, 5, 0x14 }, // 1010 0
{ 10, 5, 0x7 }, // 0011 1
{ 11, 5, 0x8 }, // 0100 0
{ 12, 6, 0x8 }, // 0010 00
{ 13, 6, 0x3 }, // 0000 11
{ 14, 6, 0x34 }, // 1101 00
{ 15, 6, 0x35 }, // 1101 01
{ 16, 6, 0x2A }, // 1010 10
{ 17, 6, 0x2B }, // 1010 11
{ 18, 7, 0x27 }, // 0100 111
{ 19, 7, 0xC }, // 0001 100
{ 20, 7, 0x8 }, // 0001 000
{ 21, 7, 0x17 }, // 0010 111
{ 22, 7, 0x3 }, // 0000 011
{ 23, 7, 0x4 }, // 0000 100
{ 24, 7, 0x28 }, // 0101 000
{ 25, 7, 0x2B }, // 0101 011
{ 26, 7, 0x13 }, // 0010 011
{ 27, 7, 0x24 }, // 0100 100
{ 28, 7, 0x18 }, // 0011 000
{ 29, 8, 0x2 }, // 0000 0010
{ 30, 8, 0x3 }, // 0000 0011
{ 31, 8, 0x1A }, // 0001 1010
{ 32, 8, 0x1B }, // 0001 1011
{ 33, 8, 0x12 }, // 0001 0010
{ 34, 8, 0x13 }, // 0001 0011
{ 35, 8, 0x14 }, // 0001 0100
{ 36, 8, 0x15 }, // 0001 0101
{ 37, 8, 0x16 }, // 0001 0110
{ 38, 8, 0x17 }, // 0001 0111
{ 39, 8, 0x28 }, // 0010 1000
{ 40, 8, 0x29 }, // 0010 1001
{ 41, 8, 0x2A }, // 0010 1010
{ 42, 8, 0x2B }, // 0010 1011
{ 43, 8, 0x2C }, // 0010 1100
{ 44, 8, 0x2D }, // 0010 1101
{ 45, 8, 0x4 }, // 0000 0100
{ 46, 8, 0x5 }, // 0000 0101
{ 47, 8, 0xA }, // 0000 1010
{ 48, 8, 0xB }, // 0000 1011
{ 49, 8, 0x52 }, // 0101 0010
{ 50, 8, 0x53 }, // 0101 0011
{ 51, 8, 0x54 }, // 0101 0100
{ 52, 8, 0x55 }, // 0101 0101
{ 53, 8, 0x24 }, // 0010 0100
{ 54, 8, 0x25 }, // 0010 0101
{ 55, 8, 0x58 }, // 0101 1000
{ 56, 8, 0x59 }, // 0101 1001
{ 57, 8, 0x5A }, // 0101 1010
{ 58, 8, 0x5B }, // 0101 1011
{ 59, 8, 0x4A }, // 0100 1010
{ 60, 8, 0x4B }, // 0100 1011
{ 61, 8, 0x32 }, // 0011 0010
{ 62, 8, 0x33 }, // 0011 0011
{ 63, 8, 0x34 }, // 0011 0100
{ 64, 5, 0x1B }, // 1101 1
{ 128, 5, 0x12 }, // 1001 0
{ 192, 6, 0x17 }, // 0101 11
{ 256, 7, 0x37 }, // 0110 111
{ 320, 8, 0x36 }, // 0011 0110
{ 384, 8, 0x37 }, // 0011 0111
{ 448, 8, 0x64 }, // 0110 0100
{ 512, 8, 0x65 }, // 0110 0101
{ 576, 8, 0x68 }, // 0110 1000
{ 640, 8, 0x67 }, // 0110 0111
{ 704, 9, 0xCC }, // 0110 0110 0
{ 768, 9, 0xCD }, // 0110 0110 1
{ 832, 9, 0xD2 }, // 0110 1001 0
{ 896, 9, 0xD3 }, // 0110 1001 1
{ 960, 9, 0xD4 }, // 0110 1010 0
{ 1024, 9, 0xD5 }, // 0110 1010 1
{ 1088, 9, 0xD6 }, // 0110 1011 0
{ 1152, 9, 0xD7 }, // 0110 1011 1
{ 1216, 9, 0xD8 }, // 0110 1100 0
{ 1280, 9, 0xD9 }, // 0110 1100 1
{ 1344, 9, 0xDA }, // 0110 1101 0
{ 1408, 9, 0xDB }, // 0110 1101 1
{ 1472, 9, 0x98 }, // 0100 1100 0
{ 1536, 9, 0x99 }, // 0100 1100 1
{ 1600, 9, 0x9A }, // 0100 1101 0
{ 1664, 6, 0x18 }, // 0110 00
{ 1728, 9, 0x9B }, // 0100 1101 1
{ 1792, 11, 0x8 }, // 0000 0001 000
{ 1856, 11, 0xC }, // 0000 0001 100
{ 1920, 11, 0xD }, // 0000 0001 101
{ 1984, 12, 0x12 }, // 0000 0001 0010
{ 2048, 12, 0x13 }, // 0000 0001 0011
{ 2112, 12, 0x14 }, // 0000 0001 0100
{ 2176, 12, 0x15 }, // 0000 0001 0101
{ 2240, 12, 0x16 }, // 0000 0001 0110
{ 2304, 12, 0x17 }, // 0000 0001 0111
{ 2368, 12, 0x1C }, // 0000 0001 1100
{ 2432, 12, 0x1D }, // 0000 0001 1101
{ 2496, 12, 0x1E }, // 0000 0001 1110
{ 2560, 12, 0x1F } // 0000 0001 1111
};
static const PixelCode BlackPixelCodes[] =
{
{ 0, 10, 0x37 }, // 0000 1101 11
{ 1, 3, 0x2 }, // 010
{ 2, 2, 0x3 }, // 11
{ 3, 2, 0x2 }, // 10
{ 4, 3, 0x3 }, // 011
{ 5, 4, 0x3 }, // 0011
{ 6, 4, 0x2 }, // 0010
{ 7, 5, 0x3 }, // 0001 1
{ 8, 6, 0x5 }, // 0001 01
{ 9, 6, 0x4 }, // 0001 00
{ 10, 7, 0x4 }, // 0000 100
{ 11, 7, 0x5 }, // 0000 101
{ 12, 7, 0x7 }, // 0000 111
{ 13, 8, 0x4 }, // 0000 0100
{ 14, 8, 0x7 }, // 0000 0111
{ 15, 9, 0x18 }, // 0000 1100 0
{ 16, 10, 0x17 }, // 0000 0101 11
{ 17, 10, 0x18 }, // 0000 0110 00
{ 18, 10, 0x8 }, // 0000 0010 00
{ 19, 11, 0x67 }, // 0000 1100 111
{ 20, 11, 0x68 }, // 0000 1101 000
{ 21, 11, 0x6C }, // 0000 1101 100
{ 22, 11, 0x37 }, // 0000 0110 111
{ 23, 11, 0x28 }, // 0000 0101 000
{ 24, 11, 0x17 }, // 0000 0010 111
{ 25, 11, 0x18 }, // 0000 0011 000
{ 26, 12, 0xCA }, // 0000 1100 1010
{ 27, 12, 0xCB }, // 0000 1100 1011
{ 28, 12, 0xCC }, // 0000 1100 1100
{ 29, 12, 0xCD }, // 0000 1100 1101
{ 30, 12, 0x68 }, // 0000 0110 1000
{ 31, 12, 0x69 }, // 0000 0110 1001
{ 32, 12, 0x6A }, // 0000 0110 1010
{ 33, 12, 0x6B }, // 0000 0110 1011
{ 34, 12, 0xD2 }, // 0000 1101 0010
{ 35, 12, 0xD3 }, // 0000 1101 0011
{ 36, 12, 0xD4 }, // 0000 1101 0100
{ 37, 12, 0xD5 }, // 0000 1101 0101
{ 38, 12, 0xD6 }, // 0000 1101 0110
{ 39, 12, 0xD7 }, // 0000 1101 0111
{ 40, 12, 0x6C }, // 0000 0110 1100
{ 41, 12, 0x6D }, // 0000 0110 1101
{ 42, 12, 0xDA }, // 0000 1101 1010
{ 43, 12, 0xDB }, // 0000 1101 1011
{ 44, 12, 0x54 }, // 0000 0101 0100
{ 45, 12, 0x55 }, // 0000 0101 0101
{ 46, 12, 0x56 }, // 0000 0101 0110
{ 47, 12, 0x57 }, // 0000 0101 0111
{ 48, 12, 0x64 }, // 0000 0110 0100
{ 49, 12, 0x65 }, // 0000 0110 0101
{ 50, 12, 0x52 }, // 0000 0101 0010
{ 51, 12, 0x53 }, // 0000 0101 0011
{ 52, 12, 0x24 }, // 0000 0010 0100
{ 53, 12, 0x37 }, // 0000 0011 0111
{ 54, 12, 0x38 }, // 0000 0011 1000
{ 55, 12, 0x27 }, // 0000 0010 0111
{ 56, 12, 0x28 }, // 0000 0010 1000
{ 57, 12, 0x58 }, // 0000 0101 1000
{ 58, 12, 0x59 }, // 0000 0101 1001
{ 59, 12, 0x2B }, // 0000 0010 1011
{ 60, 12, 0x2C }, // 0000 0010 1100
{ 61, 12, 0x5A }, // 0000 0101 1010
{ 62, 12, 0x66 }, // 0000 0110 0110
{ 63, 12, 0x67 }, // 0000 0110 0111
{ 64, 10, 0xF }, // 0000 0011 11
{ 128, 12, 0xC8 }, // 0000 1100 1000
{ 192, 12, 0xC9 }, // 0000 1100 1001
{ 256, 12, 0x5B }, // 0000 0101 1011
{ 320, 12, 0x33 }, // 0000 0011 0011
{ 384, 12, 0x34 }, // 0000 0011 0100
{ 448, 12, 0x35 }, // 0000 0011 0101
{ 512, 13, 0x6C }, // 0000 0011 0110 0
{ 576, 13, 0x6D }, // 0000 0011 0110 1
{ 640, 13, 0x4A }, // 0000 0010 0101 0
{ 704, 13, 0x4B }, // 0000 0010 0101 1
{ 768, 13, 0x4C }, // 0000 0010 0110 0
{ 832, 13, 0x4D }, // 0000 0010 0110 1
{ 896, 13, 0x72 }, // 0000 0011 1001 0
{ 960, 13, 0x73 }, // 0000 0011 1001 1
{ 1024, 13, 0x74 }, // 0000 0011 1010 0
{ 1088, 13, 0x75 }, // 0000 0011 1010 1
{ 1152, 13, 0x76 }, // 0000 0011 1011 0
{ 1216, 13, 0x77 }, // 0000 0011 1011 1
{ 1280, 13, 0x52 }, // 0000 0010 1001 0
{ 1344, 13, 0x53 }, // 0000 0010 1001 1
{ 1408, 13, 0x54 }, // 0000 0010 1010 0
{ 1472, 13, 0x55 }, // 0000 0010 1010 1
{ 1536, 13, 0x5A }, // 0000 0010 1101 0
{ 1600, 13, 0x5B }, // 0000 0010 1101 1
{ 1664, 13, 0x64 }, // 0000 0011 0010 0
{ 1728, 13, 0x65 }, // 0000 0011 0010 1
{ 1792, 11, 0x8 }, // 0000 0001 000
{ 1856, 11, 0xC }, // 0000 0001 100
{ 1920, 11, 0xD }, // 0000 0001 101
{ 1984, 12, 0x12 }, // 0000 0001 0010
{ 2048, 12, 0x13 }, // 0000 0001 0011
{ 2112, 12, 0x14 }, // 0000 0001 0100
{ 2176, 12, 0x15 }, // 0000 0001 0101
{ 2240, 12, 0x16 }, // 0000 0001 0110
{ 2304, 12, 0x17 }, // 0000 0001 0111
{ 2368, 12, 0x1C }, // 0000 0001 1100
{ 2432, 12, 0x1D }, // 0000 0001 1101
{ 2496, 12, 0x1E }, // 0000 0001 1110
{ 2560, 12, 0x1F } // 0000 0001 1111
};
void PDFWriterImpl::putG4Span( long i_nSpan, bool i_bWhitePixel, BitStreamState& io_rState )
{
const PixelCode* pTable = i_bWhitePixel ? WhitePixelCodes : BlackPixelCodes;
// maximum encoded span is 2560 consecutive pixels
while( i_nSpan > 2623 )
{
// write 2560 bits, that is entry (63 + (2560 >> 6)) == 103 in the appropriate table
putG4Bits( pTable[103].mnCodeBits, pTable[103].mnCode, io_rState );
i_nSpan -= pTable[103].mnEncodedPixels;
}
// write multiples of 64 pixels up to 2560
if( i_nSpan > 63 )
{
sal_uInt32 nTabIndex = 63 + (i_nSpan >> 6);
OSL_ASSERT( pTable[nTabIndex].mnEncodedPixels == static_cast<sal_uInt32>(64*(i_nSpan >> 6)) );
putG4Bits( pTable[nTabIndex].mnCodeBits, pTable[nTabIndex].mnCode, io_rState );
i_nSpan -= pTable[nTabIndex].mnEncodedPixels;
}
putG4Bits( pTable[i_nSpan].mnCodeBits, pTable[i_nSpan].mnCode, io_rState );
}
void PDFWriterImpl::writeG4Stream( BitmapReadAccess const * i_pBitmap )
{
long nW = i_pBitmap->Width();
long nH = i_pBitmap->Height();
if( nW <= 0 || nH <= 0 )
return;
if( i_pBitmap->GetBitCount() != 1 )
return;
BitStreamState aBitState;
// the first reference line is virtual and completely empty
const Scanline pFirstRefLine = static_cast<Scanline>(rtl_allocateZeroMemory( nW/8 + 1 ));
Scanline pRefLine = pFirstRefLine;
for( long nY = 0; nY < nH; nY++ )
{
const Scanline pCurLine = i_pBitmap->GetScanline( nY );
long nLineIndex = 0;
bool bRunSet = (*pCurLine & 0x80) != 0;
bool bRefSet = (*pRefLine & 0x80) != 0;
long nRunIndex1 = bRunSet ? 0 : findBitRun( pCurLine, 0, nW, bRunSet );
long nRefIndex1 = bRefSet ? 0 : findBitRun( pRefLine, 0, nW, bRefSet );
for( ; nLineIndex < nW; )
{
long nRefIndex2 = findBitRun( pRefLine, nRefIndex1, nW );
if( nRefIndex2 >= nRunIndex1 )
{
long nDiff = nRefIndex1 - nRunIndex1;
if( -3 <= nDiff && nDiff <= 3 )
{ // vertical coding
static const struct
{
sal_uInt32 const mnCodeBits;
sal_uInt32 const mnCode;
} VerticalCodes[7] = {
{ 7, 0x03 }, // 0000 011
{ 6, 0x03 }, // 0000 11
{ 3, 0x03 }, // 011
{ 1, 0x1 }, // 1
{ 3, 0x2 }, // 010
{ 6, 0x02 }, // 0000 10
{ 7, 0x02 } // 0000 010
};
// convert to index
nDiff += 3;
// emit diff code
putG4Bits( VerticalCodes[nDiff].mnCodeBits, VerticalCodes[nDiff].mnCode, aBitState );
nLineIndex = nRunIndex1;
}
else
{ // difference too large, horizontal coding
// emit horz code 001
putG4Bits( 3, 0x1, aBitState );
long nRunIndex2 = findBitRun( pCurLine, nRunIndex1, nW );
bool bWhiteFirst = ( nLineIndex + nRunIndex1 == 0 || ! isSet( pCurLine, nLineIndex ) );
putG4Span( nRunIndex1 - nLineIndex, bWhiteFirst, aBitState );
putG4Span( nRunIndex2 - nRunIndex1, ! bWhiteFirst, aBitState );
nLineIndex = nRunIndex2;
}
}
else
{ // emit pass code 0001
putG4Bits( 4, 0x1, aBitState );
nLineIndex = nRefIndex2;
}
if( nLineIndex < nW )
{
bool bSet = isSet( pCurLine, nLineIndex );
nRunIndex1 = findBitRun( pCurLine, nLineIndex, nW, bSet );
nRefIndex1 = findBitRun( pRefLine, nLineIndex, nW, ! bSet );
nRefIndex1 = findBitRun( pRefLine, nRefIndex1, nW, bSet );
}
}
// the current line is the reference for the next line
pRefLine = pCurLine;
}
// terminate strip with EOFB
putG4Bits( 12, 1, aBitState );
putG4Bits( 12, 1, aBitState );
if( aBitState.mnNextBitPos != 8 )
{
writeBuffer( &aBitState.getByte(), 1 );
aBitState.flush();
}
std::free( pFirstRefLine );
}
static bool lcl_canUsePDFAxialShading(const Gradient& rGradient) {
switch (rGradient.GetStyle())
{
case GradientStyle::Linear:
case GradientStyle::Axial:
break;
default:
return false;
}
// TODO: handle step count
return rGradient.GetSteps() <= 0;
}
/* vim:set shiftwidth=4 softtabstop=4 expandtab: */
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