/************************************************************** * * 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 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. * *************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_sdext.hxx" #include "pdfiprocessor.hxx" #include "xmlemitter.hxx" #include "pdfihelper.hxx" #include "imagecontainer.hxx" #include "style.hxx" #include "drawtreevisiting.hxx" #include "genericelements.hxx" #include "basegfx/polygon/b2dpolypolygontools.hxx" #include "basegfx/range/b2drange.hxx" #include "com/sun/star/i18n/XBreakIterator.hpp" #include "com/sun/star/lang/XMultiServiceFactory.hpp" #include "comphelper/processfactory.hxx" #include "com/sun/star/i18n/ScriptType.hpp" #include "com/sun/star/i18n/DirectionProperty.hpp" #include using namespace ::com::sun::star; using namespace ::com::sun::star; using namespace ::com::sun::star::lang; using namespace ::com::sun::star::i18n; using namespace ::com::sun::star::uno; namespace pdfi { const ::com::sun::star::uno::Reference< ::com::sun::star::i18n::XBreakIterator >& DrawXmlOptimizer::GetBreakIterator() { if ( !mxBreakIter.is() ) { Reference< XComponentContext > xContext( this->m_rProcessor.m_xContext, uno::UNO_SET_THROW ); Reference< XMultiComponentFactory > xMSF( xContext->getServiceManager(), uno::UNO_SET_THROW ); Reference < XInterface > xInterface = xMSF->createInstanceWithContext(::rtl::OUString::createFromAscii("com.sun.star.i18n.BreakIterator"), xContext); mxBreakIter = uno::Reference< i18n::XBreakIterator >( xInterface, uno::UNO_QUERY ); } return mxBreakIter; } const ::com::sun::star::uno::Reference< ::com::sun::star::i18n::XBreakIterator >& DrawXmlEmitter::GetBreakIterator() { if ( !mxBreakIter.is() ) { Reference< XComponentContext > xContext( m_rEmitContext.m_xContext, uno::UNO_SET_THROW ); Reference< XMultiComponentFactory > xMSF( xContext->getServiceManager(), uno::UNO_SET_THROW ); Reference < XInterface > xInterface = xMSF->createInstanceWithContext(::rtl::OUString::createFromAscii("com.sun.star.i18n.BreakIterator"), xContext); mxBreakIter = uno::Reference< i18n::XBreakIterator >( xInterface, uno::UNO_QUERY ); } return mxBreakIter; } const ::com::sun::star::uno::Reference< ::com::sun::star::i18n::XCharacterClassification >& DrawXmlEmitter::GetCharacterClassification() { if ( !mxCharClass.is() ) { Reference< XComponentContext > xContext( m_rEmitContext.m_xContext, uno::UNO_SET_THROW ); Reference< XMultiComponentFactory > xMSF( xContext->getServiceManager(), uno::UNO_SET_THROW ); Reference < XInterface > xInterface = xMSF->createInstanceWithContext(::rtl::OUString::createFromAscii("com.sun.star.i18n.CharacterClassification"), xContext); mxCharClass = uno::Reference< i18n::XCharacterClassification >( xInterface, uno::UNO_QUERY ); } return mxCharClass; } void DrawXmlEmitter::visit( HyperlinkElement& elem, const std::list< Element* >::const_iterator& ) { if( elem.Children.empty() ) return; const char* pType = dynamic_cast(elem.Children.front()) ? "draw:a" : "text:a"; PropertyMap aProps; aProps[ USTR( "xlink:type" ) ] = USTR( "simple" ); aProps[ USTR( "xlink:href" ) ] = elem.URI; aProps[ USTR( "office:target-frame-name" ) ] = USTR( "_blank" ); aProps[ USTR( "xlink:show" ) ] = USTR( "new" ); m_rEmitContext.rEmitter.beginTag( pType, aProps ); std::list< Element* >::iterator this_it = elem.Children.begin(); while( this_it !=elem.Children.end() && *this_it != &elem ) { (*this_it)->visitedBy( *this, this_it ); this_it++; } m_rEmitContext.rEmitter.endTag( pType ); } void DrawXmlEmitter::visit( TextElement& elem, const std::list< Element* >::const_iterator& ) { if( ! elem.Text.getLength() ) return; rtl::OUString strSpace(32); rtl::OUString strNbSpace(160); rtl::OUString tabSpace(0x09); PropertyMap aProps; if( elem.StyleId != -1 ) { aProps[ rtl::OUString( RTL_CONSTASCII_USTRINGPARAM( "text:style-name" ) ) ] = m_rEmitContext.rStyles.getStyleName( elem.StyleId ); } rtl::OUString str(elem.Text.getStr()); // Check for RTL bool isRTL = false; Reference< i18n::XCharacterClassification > xCC( GetCharacterClassification() ); if( xCC.is() ) { for(int i=1; i< elem.Text.getLength(); i++) { sal_Int16 nType = xCC->getCharacterDirection( str, i ); if ( nType == ::com::sun::star::i18n::DirectionProperty_RIGHT_TO_LEFT || nType == ::com::sun::star::i18n::DirectionProperty_RIGHT_TO_LEFT_ARABIC || nType == ::com::sun::star::i18n::DirectionProperty_RIGHT_TO_LEFT_EMBEDDING || nType == ::com::sun::star::i18n::DirectionProperty_RIGHT_TO_LEFT_OVERRIDE ) isRTL = true; } } if (isRTL) // If so, reverse string str = m_rProcessor.mirrorString( str ); m_rEmitContext.rEmitter.beginTag( "text:span", aProps ); for(int i=0; i< elem.Text.getLength(); i++) { rtl::OUString strToken= str.copy(i,1) ; if( strSpace.equals(strToken) || strNbSpace.equals(strToken)) { aProps[ USTR( "text:c" ) ] = USTR( "1" ); m_rEmitContext.rEmitter.beginTag( "text:s", aProps ); m_rEmitContext.rEmitter.endTag( "text:s"); } else { if( tabSpace.equals(strToken) ) { m_rEmitContext.rEmitter.beginTag( "text:tab", aProps ); m_rEmitContext.rEmitter.endTag( "text:tab"); } else { m_rEmitContext.rEmitter.write( strToken ); } } } std::list< Element* >::iterator this_it = elem.Children.begin(); while( this_it !=elem.Children.end() && *this_it != &elem ) { (*this_it)->visitedBy( *this, this_it ); this_it++; } m_rEmitContext.rEmitter.endTag( "text:span" ); } void DrawXmlEmitter::visit( ParagraphElement& elem, const std::list< Element* >::const_iterator& ) { PropertyMap aProps; if( elem.StyleId != -1 ) { aProps[ USTR( "text:style-name" ) ] = m_rEmitContext.rStyles.getStyleName( elem.StyleId ); } const char* pTagType = "text:p"; if( elem.Type == elem.Headline ) pTagType = "text:h"; m_rEmitContext.rEmitter.beginTag( pTagType, aProps ); std::list< Element* >::iterator this_it = elem.Children.begin(); while( this_it !=elem.Children.end() && *this_it != &elem ) { (*this_it)->visitedBy( *this, this_it ); this_it++; } m_rEmitContext.rEmitter.endTag( pTagType ); } void DrawXmlEmitter::fillFrameProps( DrawElement& rElem, PropertyMap& rProps, const EmitContext& rEmitContext, bool bWasTransformed ) { double rel_x = rElem.x, rel_y = rElem.y; rProps[ USTR( "draw:z-index" ) ] = rtl::OUString::valueOf( rElem.ZOrder ); rProps[ USTR( "draw:style-name" )] = rEmitContext.rStyles.getStyleName( rElem.StyleId ); rProps[ USTR( "svg:width" ) ] = convertPixelToUnitString( rElem.w ); rProps[ USTR( "svg:height" ) ] = convertPixelToUnitString( rElem.h ); const GraphicsContext& rGC = rEmitContext.rProcessor.getGraphicsContext( rElem.GCId ); if( rGC.Transformation.isIdentity() || bWasTransformed ) { rProps[ USTR( "svg:x" ) ] = convertPixelToUnitString( rel_x ); rProps[ USTR( "svg:y" ) ] = convertPixelToUnitString( rel_y ); } else { basegfx::B2DTuple aScale, aTranslation; double fRotate, fShearX; rGC.Transformation.decompose( aScale, aTranslation, fRotate, fShearX ); rtl::OUStringBuffer aBuf( 256 ); // TODO(F2): general transformation case missing; if implemented, note // that ODF rotation is oriented the other way // vertical mirroring is done by horizontally mirroring and rotaing 180 degree // quaint ! if( rElem.MirrorVertical ) fRotate += M_PI; // build transformation string if( fShearX != 0.0 ) { aBuf.appendAscii( "skewX( " ); aBuf.append( fShearX ); aBuf.appendAscii( " )" ); } if( fRotate != 0.0 ) { if( aBuf.getLength() > 0 ) aBuf.append( sal_Unicode(' ') ); aBuf.appendAscii( "rotate( " ); aBuf.append( -fRotate ); aBuf.appendAscii( " )" ); } if( aBuf.getLength() > 0 ) aBuf.append( sal_Unicode(' ') ); aBuf.appendAscii( "translate( " ); aBuf.append( convertPixelToUnitString( rel_x ) ); aBuf.append( sal_Unicode(' ') ); aBuf.append( convertPixelToUnitString( rel_y ) ); aBuf.appendAscii( " )" ); rProps[ USTR( "draw:transform" ) ] = aBuf.makeStringAndClear(); } } void DrawXmlEmitter::visit( FrameElement& elem, const std::list< Element* >::const_iterator& ) { if( elem.Children.empty() ) return; bool bTextBox = (dynamic_cast(elem.Children.front()) != NULL); PropertyMap aFrameProps; fillFrameProps( elem, aFrameProps, m_rEmitContext ); m_rEmitContext.rEmitter.beginTag( "draw:frame", aFrameProps ); if( bTextBox ) m_rEmitContext.rEmitter.beginTag( "draw:text-box", PropertyMap() ); std::list< Element* >::iterator this_it = elem.Children.begin(); while( this_it !=elem.Children.end() && *this_it != &elem ) { (*this_it)->visitedBy( *this, this_it ); this_it++; } if( bTextBox ) m_rEmitContext.rEmitter.endTag( "draw:text-box" ); m_rEmitContext.rEmitter.endTag( "draw:frame" ); } void DrawXmlEmitter::visit( PolyPolyElement& elem, const std::list< Element* >::const_iterator& ) { elem.updateGeometry(); /* note: * aw recommends using 100dth of mm in all respects since the xml import * (a) is buggy (see issue 37213) * (b) is optimized for 100dth of mm and does not scale itself then, * this does not gain us speed but makes for smaller rounding errors since * the xml importer coordinates are integer based */ for (sal_uInt32 i = 0; i< elem.PolyPoly.count(); i++) { basegfx::B2DPolygon b2dPolygon; b2dPolygon = elem.PolyPoly.getB2DPolygon( i ); for ( sal_uInt32 j = 0; j< b2dPolygon.count(); j++ ) { basegfx::B2DPoint point; basegfx::B2DPoint nextPoint; point = b2dPolygon.getB2DPoint( j ); basegfx::B2DPoint prevPoint; prevPoint = b2dPolygon.getPrevControlPoint( j ) ; point.setX( convPx2mmPrec2( point.getX() )*100.0 ); point.setY( convPx2mmPrec2( point.getY() )*100.0 ); if ( b2dPolygon.isPrevControlPointUsed( j ) ) { prevPoint.setX( convPx2mmPrec2( prevPoint.getX() )*100.0 ); prevPoint.setY( convPx2mmPrec2( prevPoint.getY() )*100.0 ); } if ( b2dPolygon.isNextControlPointUsed( j ) ) { nextPoint = b2dPolygon.getNextControlPoint( j ) ; nextPoint.setX( convPx2mmPrec2( nextPoint.getX() )*100.0 ); nextPoint.setY( convPx2mmPrec2( nextPoint.getY() )*100.0 ); } b2dPolygon.setB2DPoint( j, point ); if ( b2dPolygon.isPrevControlPointUsed( j ) ) b2dPolygon.setPrevControlPoint( j , prevPoint ) ; if ( b2dPolygon.isNextControlPointUsed( j ) ) b2dPolygon.setNextControlPoint( j , nextPoint ) ; } elem.PolyPoly.setB2DPolygon( i, b2dPolygon ); } PropertyMap aProps; // PDFIProcessor transforms geometrical objects, not images and text // so we need to tell fillFrameProps here that the transformation for // a PolyPolyElement was already applied (aside form translation) fillFrameProps( elem, aProps, m_rEmitContext, true ); rtl::OUStringBuffer aBuf( 64 ); aBuf.appendAscii( "0 0 " ); aBuf.append( convPx2mmPrec2(elem.w)*100.0 ); aBuf.append( sal_Unicode(' ') ); aBuf.append( convPx2mmPrec2(elem.h)*100.0 ); aProps[ USTR( "svg:viewBox" ) ] = aBuf.makeStringAndClear(); aProps[ USTR( "svg:d" ) ] = basegfx::tools::exportToSvgD( elem.PolyPoly ); m_rEmitContext.rEmitter.beginTag( "draw:path", aProps ); m_rEmitContext.rEmitter.endTag( "draw:path" ); } void DrawXmlEmitter::visit( ImageElement& elem, const std::list< Element* >::const_iterator& ) { PropertyMap aImageProps; m_rEmitContext.rEmitter.beginTag( "draw:image", aImageProps ); m_rEmitContext.rEmitter.beginTag( "office:binary-data", PropertyMap() ); m_rEmitContext.rImages.writeBase64EncodedStream( elem.Image, m_rEmitContext); m_rEmitContext.rEmitter.endTag( "office:binary-data" ); m_rEmitContext.rEmitter.endTag( "draw:image" ); } void DrawXmlEmitter::visit( PageElement& elem, const std::list< Element* >::const_iterator& ) { PropertyMap aPageProps; aPageProps[ USTR( "draw:master-page-name" ) ] = m_rEmitContext.rStyles.getStyleName( elem.StyleId ); m_rEmitContext.rEmitter.beginTag("draw:page", aPageProps); if( m_rEmitContext.xStatusIndicator.is() ) m_rEmitContext.xStatusIndicator->setValue( elem.PageNumber ); std::list< Element* >::iterator this_it = elem.Children.begin(); while( this_it !=elem.Children.end() && *this_it != &elem ) { (*this_it)->visitedBy( *this, this_it ); this_it++; } m_rEmitContext.rEmitter.endTag("draw:page"); } void DrawXmlEmitter::visit( DocumentElement& elem, const std::list< Element* >::const_iterator&) { m_rEmitContext.rEmitter.beginTag( "office:body", PropertyMap() ); m_rEmitContext.rEmitter.beginTag( m_bWriteDrawDocument ? "office:drawing" : "office:presentation", PropertyMap() ); std::list< Element* >::iterator this_it = elem.Children.begin(); while( this_it !=elem.Children.end() && *this_it != &elem ) { (*this_it)->visitedBy( *this, this_it ); this_it++; } m_rEmitContext.rEmitter.endTag( m_bWriteDrawDocument ? "office:drawing" : "office:presentation" ); m_rEmitContext.rEmitter.endTag( "office:body" ); } ///////////////////////////////////////////////////////////////// void DrawXmlOptimizer::visit( HyperlinkElement&, const std::list< Element* >::const_iterator& ) { } void DrawXmlOptimizer::visit( TextElement&, const std::list< Element* >::const_iterator&) { } void DrawXmlOptimizer::visit( FrameElement& elem, const std::list< Element* >::const_iterator& ) { elem.applyToChildren(*this); } void DrawXmlOptimizer::visit( ImageElement&, const std::list< Element* >::const_iterator& ) { } void DrawXmlOptimizer::visit( PolyPolyElement& elem, const std::list< Element* >::const_iterator& ) { /* note: optimize two consecutive PolyPolyElements that * have the same path but one of which is a stroke while * the other is a fill */ if( elem.Parent ) { // find following PolyPolyElement in parent's children list std::list< Element* >::iterator this_it = elem.Parent->Children.begin(); while( this_it != elem.Parent->Children.end() && *this_it != &elem ) ++this_it; if( this_it != elem.Parent->Children.end() ) { std::list< Element* >::iterator next_it = this_it; if( ++next_it != elem.Parent->Children.end() ) { PolyPolyElement* pNext = dynamic_cast(*next_it); // TODO(F2): this comparison fails for OOo-generated polygons with beziers. if( pNext && pNext->PolyPoly == elem.PolyPoly ) { const GraphicsContext& rNextGC = m_rProcessor.getGraphicsContext( pNext->GCId ); const GraphicsContext& rThisGC = m_rProcessor.getGraphicsContext( elem.GCId ); if( rThisGC.BlendMode == rNextGC.BlendMode && rThisGC.Flatness == rNextGC.Flatness && rThisGC.Transformation == rNextGC.Transformation && rThisGC.Clip == rNextGC.Clip && rThisGC.FillColor.Red == rNextGC.FillColor.Red && rThisGC.FillColor.Green== rNextGC.FillColor.Green && rThisGC.FillColor.Blue == rNextGC.FillColor.Blue && rThisGC.FillColor.Alpha== rNextGC.FillColor.Alpha && pNext->Action == PATH_STROKE && (elem.Action == PATH_FILL || elem.Action == PATH_EOFILL) ) { GraphicsContext aGC = rThisGC; aGC.LineJoin = rNextGC.LineJoin; aGC.LineCap = rNextGC.LineCap; aGC.LineWidth = rNextGC.LineWidth; aGC.MiterLimit= rNextGC.MiterLimit; aGC.DashArray = rNextGC.DashArray; aGC.LineColor = rNextGC.LineColor; elem.GCId = m_rProcessor.getGCId( aGC ); elem.Action |= pNext->Action; elem.Children.splice( elem.Children.end(), pNext->Children ); elem.Parent->Children.erase( next_it ); delete pNext; } } } } } } void DrawXmlOptimizer::visit( ParagraphElement& elem, const std::list< Element* >::const_iterator& ) { optimizeTextElements( elem ); elem.applyToChildren(*this); } void DrawXmlOptimizer::visit( PageElement& elem, const std::list< Element* >::const_iterator& ) { if( m_rProcessor.getStatusIndicator().is() ) m_rProcessor.getStatusIndicator()->setValue( elem.PageNumber ); // resolve hyperlinks elem.resolveHyperlinks(); elem.resolveFontStyles( m_rProcessor ); // underlines and such // FIXME: until hyperlinks and font effects are adjusted for // geometrical search handle them before sorting m_rProcessor.sortElements( &elem ); // find paragraphs in text ParagraphElement* pCurPara = NULL; std::list< Element* >::iterator page_element, next_page_element; next_page_element = elem.Children.begin(); double fCurLineHeight = 0.0; // average height of text items in current para int nCurLineElements = 0; // number of line contributing elements in current para double line_left = elem.w, line_right = 0.0; double column_width = elem.w*0.75; // estimate text width // TODO: guess columns while( next_page_element != elem.Children.end() ) { page_element = next_page_element++; ParagraphElement* pPagePara = dynamic_cast(*page_element); if( pPagePara ) { pCurPara = pPagePara; // adjust line height and text items fCurLineHeight = 0.0; nCurLineElements = 0; for( std::list< Element* >::iterator it = pCurPara->Children.begin(); it != pCurPara->Children.end(); ++it ) { TextElement* pTestText = dynamic_cast(*it); if( pTestText ) { fCurLineHeight = (fCurLineHeight*double(nCurLineElements) + pTestText->h)/double(nCurLineElements+1); nCurLineElements++; } } continue; } HyperlinkElement* pLink = dynamic_cast(*page_element); DrawElement* pDraw = dynamic_cast(*page_element); if( ! pDraw && pLink && ! pLink->Children.empty() ) pDraw = dynamic_cast(pLink->Children.front() ); if( pDraw ) { // insert small drawing objects as character, else leave them page bound bool bInsertToParagraph = false; // first check if this is either inside the paragraph if( pCurPara && pDraw->y < pCurPara->y + pCurPara->h ) { if( pDraw->h < fCurLineHeight * 1.5 ) { bInsertToParagraph = true; fCurLineHeight = (fCurLineHeight*double(nCurLineElements) + pDraw->h)/double(nCurLineElements+1); nCurLineElements++; // mark draw element as character pDraw->isCharacter = true; } } // or perhaps the draw element begins a new paragraph else if( next_page_element != elem.Children.end() ) { TextElement* pText = dynamic_cast(*next_page_element); if( ! pText ) { ParagraphElement* pPara = dynamic_cast(*next_page_element); if( pPara && ! pPara->Children.empty() ) pText = dynamic_cast(pPara->Children.front()); } if( pText && // check there is a text pDraw->h < pText->h*1.5 && // and it is approx the same height // and either upper or lower edge of pDraw is inside text's vertical range ( ( pDraw->y >= pText->y && pDraw->y <= pText->y+pText->h ) || ( pDraw->y+pDraw->h >= pText->y && pDraw->y+pDraw->h <= pText->y+pText->h ) ) ) { bInsertToParagraph = true; fCurLineHeight = pDraw->h; nCurLineElements = 1; line_left = pDraw->x; line_right = pDraw->x + pDraw->w; // begin a new paragraph pCurPara = NULL; // mark draw element as character pDraw->isCharacter = true; } } if( ! bInsertToParagraph ) { pCurPara = NULL; continue; } } TextElement* pText = dynamic_cast(*page_element); if( ! pText && pLink && ! pLink->Children.empty() ) pText = dynamic_cast(pLink->Children.front()); if( pText ) { Element* pGeo = pLink ? static_cast(pLink) : static_cast(pText); if( pCurPara ) { // there was already a text element, check for a new paragraph if( nCurLineElements > 0 ) { // if the new text is significantly distant from the paragraph // begin a new paragraph if( pGeo->y > pCurPara->y + pCurPara->h + fCurLineHeight*0.5 ) pCurPara = NULL; // insert new paragraph else if( pGeo->y > (pCurPara->y+pCurPara->h - fCurLineHeight*0.05) ) { // new paragraph if either the last line of the paragraph // was significantly shorter than the paragraph as a whole if( (line_right - line_left) < pCurPara->w*0.75 ) pCurPara = NULL; // or the last line was significantly smaller than the column width else if( (line_right - line_left) < column_width*0.75 ) pCurPara = NULL; } } } // update line height/width if( pCurPara ) { fCurLineHeight = (fCurLineHeight*double(nCurLineElements) + pGeo->h)/double(nCurLineElements+1); nCurLineElements++; if( pGeo->x < line_left ) line_left = pGeo->x; if( pGeo->x+pGeo->w > line_right ) line_right = pGeo->x+pGeo->w; } else { fCurLineHeight = pGeo->h; nCurLineElements = 1; line_left = pGeo->x; line_right = pGeo->x + pGeo->w; } } // move element to current paragraph if (! pCurPara ) // new paragraph, insert one { pCurPara = m_rProcessor.getElementFactory()->createParagraphElement( NULL ); // set parent pCurPara->Parent = &elem; //insert new paragraph before current element page_element = elem.Children.insert( page_element, pCurPara ); // forward iterator to current element again ++ page_element; // update next_element which is now invalid next_page_element = page_element; ++ next_page_element; } Element* pCurEle = *page_element; pCurEle->setParent( page_element, pCurPara ); OSL_ENSURE( !pText || pCurEle == pText || pCurEle == pLink, "paragraph child list in disorder" ); if( pText || pDraw ) pCurPara->updateGeometryWith( pCurEle ); } // process children elem.applyToChildren(*this); } bool isSpaces(TextElement* pTextElem) { rtl::OUString strSpace(32); ::rtl::OUString ouTxt2(pTextElem->Text); for(int i=0; i< pTextElem->Text.getLength(); i++) { rtl::OUString strToken = ouTxt2.copy(i,1) ; if( !strSpace.equals(strToken) ) return false; } return true; } bool notTransformed(GraphicsContext GC) { return ( GC.Transformation.get(0,0) == 100.00 && GC.Transformation.get(1,0) == 0.00 && GC.Transformation.get(0,1) == 0.00 && GC.Transformation.get(1,1) == -100.00 ); } void DrawXmlOptimizer::optimizeTextElements(Element& rParent) { if( rParent.Children.empty() ) // this should not happen { OSL_ENSURE( 0, "empty paragraph optimized" ); return; } // concatenate child elements with same font id std::list< Element* >::iterator next = rParent.Children.begin(); std::list< Element* >::iterator it = next++; FrameElement* pFrame = dynamic_cast(rParent.Parent); bool bRotatedFrame = false; if( pFrame ) { const GraphicsContext& rFrameGC = m_rProcessor.getGraphicsContext( pFrame->GCId ); if( rFrameGC.isRotatedOrSkewed() ) bRotatedFrame = true; } while( next != rParent.Children.end() ) { bool bConcat = false; TextElement* pCur = dynamic_cast(*it); if( pCur ) { TextElement* pNext = dynamic_cast(*next); bool isComplex = false; rtl::OUString str(pCur->Text.getStr()); for(int i=0; i< str.getLength(); i++) { sal_Int16 nType = GetBreakIterator()->getScriptType( str, i ); if (nType == ::com::sun::star::i18n::ScriptType::COMPLEX) isComplex = true; } bool bPara = strspn("ParagraphElement", typeid(rParent).name()); ParagraphElement* pPara = dynamic_cast(&rParent); if (bPara && isComplex) pPara->bRtl = true; if( pNext ) { const GraphicsContext& rCurGC = m_rProcessor.getGraphicsContext( pCur->GCId ); const GraphicsContext& rNextGC = m_rProcessor.getGraphicsContext( pNext->GCId ); // line and space optimization; works only in strictly horizontal mode // concatenate consecutive text elements unless there is a // font or text color or matrix change, leave a new span in that case if( (pCur->FontId == pNext->FontId || isSpaces(pNext)) && rCurGC.FillColor.Red == rNextGC.FillColor.Red && rCurGC.FillColor.Green == rNextGC.FillColor.Green && rCurGC.FillColor.Blue == rNextGC.FillColor.Blue && rCurGC.FillColor.Alpha == rNextGC.FillColor.Alpha && (rCurGC.Transformation == rNextGC.Transformation || notTransformed(rNextGC)) ) { pCur->updateGeometryWith( pNext ); // append text to current element pCur->Text.append( pNext->Text.getStr(), pNext->Text.getLength() ); str = pCur->Text.getStr(); for(int i=0; i< str.getLength(); i++) { sal_Int16 nType = GetBreakIterator()->getScriptType( str, i ); if (nType == ::com::sun::star::i18n::ScriptType::COMPLEX) isComplex = true; } if (bPara && isComplex) pPara->bRtl = true; // append eventual children to current element // and clear children (else the children just // appended to pCur would be destroyed) pCur->Children.splice( pCur->Children.end(), pNext->Children ); // get rid of the now useless element rParent.Children.erase( next ); delete pNext; bConcat = true; } } } else if( dynamic_cast(*it) ) optimizeTextElements( **it ); if ( bConcat ) next = it; else ++it; ++next; } } void DrawXmlOptimizer::visit( DocumentElement& elem, const std::list< Element* >::const_iterator&) { elem.applyToChildren(*this); } ////////////////////////////////////////////////////////////////////////////////// void DrawXmlFinalizer::visit( PolyPolyElement& elem, const std::list< Element* >::const_iterator& ) { // xxx TODO copied from DrawElement const GraphicsContext& rGC = m_rProcessor.getGraphicsContext(elem.GCId ); PropertyMap aProps; aProps[ USTR( "style:family" ) ] = USTR( "graphic" ); aProps[ USTR( "style:parent-style-name") ] = USTR( "standard" ); // generate standard graphic style if necessary m_rStyleContainer.getStandardStyleId( "graphic" ); PropertyMap aGCProps; // TODO(F3): proper dash emulation if( elem.Action & PATH_STROKE ) { aGCProps[ USTR("draw:stroke") ] = rGC.DashArray.empty() ? USTR("solid") : USTR("dash"); aGCProps[ USTR("svg:stroke-color") ] = getColorString( rGC.LineColor ); if( rGC.LineWidth != 0.0 ) { ::basegfx::B2DVector aVec(rGC.LineWidth,0); aVec *= rGC.Transformation; aVec.setX ( convPx2mmPrec2( aVec.getX() )*100.0 ); aVec.setY ( convPx2mmPrec2( aVec.getY() )*100.0 ); aGCProps[ USTR("svg:stroke-width") ] = rtl::OUString::valueOf( aVec.getLength() ); } } else { aGCProps[ USTR("draw:stroke") ] = USTR("none"); } // TODO(F1): check whether stuff could be emulated by gradient/bitmap/hatch if( elem.Action & (PATH_FILL | PATH_EOFILL) ) { aGCProps[ USTR("draw:fill") ] = USTR("solid"); aGCProps[ USTR("draw:fill-color") ] = getColorString( rGC.FillColor ); } else { aGCProps[ USTR("draw:fill") ] = USTR("none"); } StyleContainer::Style aStyle( "style:style", aProps ); StyleContainer::Style aSubStyle( "style:graphic-properties", aGCProps ); aStyle.SubStyles.push_back( &aSubStyle ); elem.StyleId = m_rStyleContainer.getStyleId( aStyle ); } void DrawXmlFinalizer::visit( HyperlinkElement&, const std::list< Element* >::const_iterator& ) { } void DrawXmlFinalizer::visit( TextElement& elem, const std::list< Element* >::const_iterator& ) { const FontAttributes& rFont = m_rProcessor.getFont( elem.FontId ); PropertyMap aProps; aProps[ USTR( "style:family" ) ] = USTR( "text" ); PropertyMap aFontProps; // family name aFontProps[ USTR( "fo:font-family" ) ] = rFont.familyName; aFontProps[ USTR( "style:font-family-complex" ) ] = rFont.familyName; // bold if( rFont.isBold ) { aFontProps[ USTR( "fo:font-weight" ) ] = USTR( "bold" ); aFontProps[ USTR( "fo:font-weight-asian" ) ] = USTR( "bold" ); aFontProps[ USTR( "style:font-weight-complex" ) ] = USTR( "bold" ); } // italic if( rFont.isItalic ) { aFontProps[ USTR( "fo:font-style" ) ] = USTR( "italic" ); aFontProps[ USTR( "fo:font-style-asian" ) ] = USTR( "italic" ); aFontProps[ USTR( "style:font-style-complex" ) ] = USTR( "italic" ); } // underline if( rFont.isUnderline ) { aFontProps[ USTR( "style:text-underline-style" ) ] = USTR( "solid" ); aFontProps[ USTR( "style:text-underline-width" ) ] = USTR( "auto" ); aFontProps[ USTR( "style:text-underline-color" ) ] = USTR( "font-color" ); } // outline if( rFont.isOutline ) { aFontProps[ USTR( "style:text-outline" ) ] = USTR( "true" ); } // size rtl::OUStringBuffer aBuf( 32 ); aBuf.append( rFont.size*72/PDFI_OUTDEV_RESOLUTION ); aBuf.appendAscii( "pt" ); rtl::OUString aFSize = aBuf.makeStringAndClear(); aFontProps[ USTR( "fo:font-size" ) ] = aFSize; aFontProps[ USTR( "style:font-size-asian" ) ] = aFSize; aFontProps[ USTR( "style:font-size-complex" ) ] = aFSize; // color const GraphicsContext& rGC = m_rProcessor.getGraphicsContext( elem.GCId ); aFontProps[ USTR( "fo:color" ) ] = getColorString( rFont.isOutline ? rGC.LineColor : rGC.FillColor ); StyleContainer::Style aStyle( "style:style", aProps ); StyleContainer::Style aSubStyle( "style:text-properties", aFontProps ); aStyle.SubStyles.push_back( &aSubStyle ); elem.StyleId = m_rStyleContainer.getStyleId( aStyle ); } void DrawXmlFinalizer::visit( ParagraphElement& elem, const std::list< Element* >::const_iterator& ) { PropertyMap aProps; aProps[ USTR( "style:family" ) ] = USTR( "paragraph" ); // generate standard paragraph style if necessary m_rStyleContainer.getStandardStyleId( "paragraph" ); PropertyMap aParProps; aParProps[ USTR("fo:text-align")] = USTR("start"); if (elem.bRtl) aParProps[ USTR("style:writing-mode")] = USTR("rl-tb"); else aParProps[ USTR("style:writing-mode")] = USTR("lr-tb"); StyleContainer::Style aStyle( "style:style", aProps ); StyleContainer::Style aSubStyle( "style:paragraph-properties", aParProps ); aStyle.SubStyles.push_back( &aSubStyle ); elem.StyleId = m_rStyleContainer.getStyleId( aStyle ); // update page boundaries if( elem.Parent ) { // check for center alignement // criterion: paragraph is small relative to parent and distributed around its center double p_x = elem.Parent->x; double p_y = elem.Parent->y; double p_w = elem.Parent->w; double p_h = elem.Parent->h; PageElement* pPage = dynamic_cast(elem.Parent); if( pPage ) { p_x += pPage->LeftMargin; p_y += pPage->TopMargin; p_w -= pPage->LeftMargin+pPage->RightMargin; p_h -= pPage->TopMargin+pPage->BottomMargin; } } elem.applyToChildren(*this); } void DrawXmlFinalizer::visit( FrameElement& elem, const std::list< Element* >::const_iterator&) { PropertyMap aProps; aProps[ USTR( "style:family" ) ] = USTR( "graphic" ); aProps[ USTR( "style:parent-style-name") ] = USTR( "standard" ); // generate standard graphic style if necessary m_rStyleContainer.getStandardStyleId( "graphic" ); PropertyMap aGCProps; aGCProps[ USTR("draw:stroke") ] = USTR("none"); aGCProps[ USTR("draw:fill") ] = USTR("none"); aGCProps[ USTR("draw:auto-grow-height") ] = USTR("true"); aGCProps[ USTR("draw:auto-grow-width") ] = USTR("true"); aGCProps[ USTR("draw:textarea-horizontal-align") ] = USTR("left"); aGCProps[ USTR("draw:textarea-vertical-align") ] = USTR("top"); aGCProps[ USTR("fo:min-height")] = USTR("0cm"); aGCProps[ USTR("fo:min-width")] = USTR("0cm"); aGCProps[ USTR("fo:padding-top") ] = USTR("0cm"); aGCProps[ USTR("fo:padding-left") ] = USTR("0cm"); aGCProps[ USTR("fo:padding-right") ] = USTR("0cm"); aGCProps[ USTR("fo:padding-bottom") ] = USTR("0cm"); // remark: vertical mirroring is done in current OOO by // mirroring horzontally and rotating 180 degrees // this is quaint, but unfortunately it seems // mirror=vertical is defined but not implemented in current code if( elem.MirrorVertical ) aGCProps[ USTR("style:mirror") ] = USTR("horizontal"); StyleContainer::Style aStyle( "style:style", aProps ); StyleContainer::Style aSubStyle( "style:graphic-properties", aGCProps ); aStyle.SubStyles.push_back( &aSubStyle ); elem.StyleId = m_rStyleContainer.getStyleId( aStyle ); elem.applyToChildren(*this); } void DrawXmlFinalizer::visit( ImageElement&, const std::list< Element* >::const_iterator& ) { } void DrawXmlFinalizer::visit( PageElement& elem, const std::list< Element* >::const_iterator& ) { if( m_rProcessor.getStatusIndicator().is() ) m_rProcessor.getStatusIndicator()->setValue( elem.PageNumber ); // transform from pixel to mm double page_width = convPx2mm( elem.w ), page_height = convPx2mm( elem.h ); // calculate page margins out of the relevant children (paragraphs) elem.TopMargin = elem.h, elem.BottomMargin = 0, elem.LeftMargin = elem.w, elem.RightMargin = 0; for( std::list< Element* >::const_iterator it = elem.Children.begin(); it != elem.Children.end(); ++it ) { if( (*it)->x < elem.LeftMargin ) elem.LeftMargin = (*it)->x; if( (*it)->y < elem.TopMargin ) elem.TopMargin = (*it)->y; if( (*it)->x + (*it)->w > elem.RightMargin ) elem.RightMargin = ((*it)->x + (*it)->w); if( (*it)->y + (*it)->h > elem.BottomMargin ) elem.BottomMargin = ((*it)->y + (*it)->h); } // transform margins to mm double left_margin = convPx2mm( elem.LeftMargin ); double right_margin = convPx2mm( elem.RightMargin ); double top_margin = convPx2mm( elem.TopMargin ); double bottom_margin = convPx2mm( elem.BottomMargin ); // round left/top margin to nearest mm left_margin = rtl_math_round( left_margin, 0, rtl_math_RoundingMode_Floor ); top_margin = rtl_math_round( top_margin, 0, rtl_math_RoundingMode_Floor ); // round (fuzzy) right/bottom margin to nearest cm right_margin = rtl_math_round( right_margin, right_margin >= 10 ? -1 : 0, rtl_math_RoundingMode_Floor ); bottom_margin = rtl_math_round( bottom_margin, bottom_margin >= 10 ? -1 : 0, rtl_math_RoundingMode_Floor ); // set reasonable default in case of way too large margins // e.g. no paragraph case if( left_margin > page_width/2.0 - 10 ) left_margin = 10; if( right_margin > page_width/2.0 - 10 ) right_margin = 10; if( top_margin > page_height/2.0 - 10 ) top_margin = 10; if( bottom_margin > page_height/2.0 - 10 ) bottom_margin = 10; // catch the weird cases if( left_margin < 0 ) left_margin = 0; if( right_margin < 0 ) right_margin = 0; if( top_margin < 0 ) top_margin = 0; if( bottom_margin < 0 ) bottom_margin = 0; // widely differing margins are unlikely to be correct if( right_margin > left_margin*1.5 ) right_margin = left_margin; elem.LeftMargin = convmm2Px( left_margin ); elem.RightMargin = convmm2Px( right_margin ); elem.TopMargin = convmm2Px( top_margin ); elem.BottomMargin = convmm2Px( bottom_margin ); // get styles for paragraphs PropertyMap aPageProps; PropertyMap aPageLayoutProps; rtl::OUStringBuffer aBuf( 64 ); aPageLayoutProps[ USTR( "fo:margin-top" ) ] = unitMMString( top_margin ); aPageLayoutProps[ USTR( "fo:margin-bottom" ) ] = unitMMString( bottom_margin ); aPageLayoutProps[ USTR( "fo:margin-left" ) ] = unitMMString( left_margin ); aPageLayoutProps[ USTR( "fo:margin-right" ) ] = unitMMString( right_margin ); aPageLayoutProps[ USTR( "fo:page-width" ) ] = unitMMString( page_width ); aPageLayoutProps[ USTR( "fo:page-height" ) ] = unitMMString( page_height ); aPageLayoutProps[ USTR( "style:print-orientation" ) ]= elem.w < elem.h ? USTR( "portrait" ) : USTR( "landscape" ); aPageLayoutProps[ USTR( "style:writing-mode" ) ]= USTR( "lr-tb" ); StyleContainer::Style aStyle( "style:page-layout", aPageProps); StyleContainer::Style aSubStyle( "style:page-layout-properties", aPageLayoutProps); aStyle.SubStyles.push_back(&aSubStyle); sal_Int32 nPageStyle = m_rStyleContainer.impl_getStyleId( aStyle, false ); // create master page rtl::OUString aMasterPageLayoutName = m_rStyleContainer.getStyleName( nPageStyle ); aPageProps[ USTR( "style:page-layout-name" ) ] = aMasterPageLayoutName; StyleContainer::Style aMPStyle( "style:master-page", aPageProps); StyleContainer::Style aHeaderStyle( "style:header", PropertyMap() ); StyleContainer::Style aFooterStyle( "style:footer", PropertyMap() ); elem.StyleId = m_rStyleContainer.impl_getStyleId( aMPStyle,false ); rtl::OUString aMasterPageName = m_rStyleContainer.getStyleName( elem.StyleId ); // create styles for children elem.applyToChildren(*this); } void DrawXmlFinalizer::visit( DocumentElement& elem, const std::list< Element* >::const_iterator& ) { elem.applyToChildren(*this); } }