/**************************************************************************** ** ** Implementation of the TQSvgDevice class ** ** Copyright (C) 2000-2008 Trolltech ASA. All rights reserved. ** ** This file is part of the xml module of the TQt GUI Toolkit. ** ** This file may be used under the terms of the GNU General ** Public License versions 2.0 or 3.0 as published by the Free ** Software Foundation and appearing in the files LICENSE.GPL2 ** and LICENSE.GPL3 included in the packaging of this file. ** Alternatively you may (at your option) use any later version ** of the GNU General Public License if such license has been ** publicly approved by Trolltech ASA (or its successors, if any) ** and the KDE Free TQt Foundation. ** ** Please review the following information to ensure GNU General ** Public Licensing requirements will be met: ** http://trolltech.com/products/qt/licenses/licensing/opensource/. ** If you are unsure which license is appropriate for your use, please ** review the following information: ** http://trolltech.com/products/qt/licenses/licensing/licensingoverview ** or contact the sales department at sales@trolltech.com. ** ** This file may be used under the terms of the Q Public License as ** defined by Trolltech ASA and appearing in the file LICENSE.TQPL ** included in the packaging of this file. Licensees holding valid TQt ** Commercial licenses may use this file in accordance with the TQt ** Commercial License Agreement provided with the Software. ** ** This file is provided "AS IS" with NO WARRANTY OF ANY KIND, ** INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR ** A PARTICULAR PURPOSE. Trolltech reserves all rights not granted ** herein. ** *****************************************************************************/ #include #ifndef TQT_NO_SVG #include "ntqpainter.h" #include "ntqpaintdevicemetrics.h" #include "ntqfile.h" #include "ntqmap.h" #include "ntqregexp.h" #include "ntqvaluelist.h" #include "ntqtextstream.h" #include "ntqimage.h" #include "ntqpixmap.h" #include const double deg2rad = 0.017453292519943295769; // pi/180 const char piData[] = "version=\"1.0\" standalone=\"no\""; const char publicId[] = "-//W3C//DTD SVG 20001102//EN"; const char systemId[] = "http://www.w3.org/TR/2000/CR-SVG-20001102/DTD/svg-20001102.dtd"; struct TQM_EXPORT_SVG ImgElement { TQDomElement element; TQImage image; TQ_DUMMY_COMPARISON_OPERATOR( ImgElement ) }; struct TQM_EXPORT_SVG PixElement { TQDomElement element; TQPixmap pixmap; TQ_DUMMY_COMPARISON_OPERATOR( PixElement ) }; struct TQSvgDeviceState { int textx, texty; // current text position int textalign; // text alignment TQ_DUMMY_COMPARISON_OPERATOR( TQSvgDeviceState ) }; typedef TQValueList ImageList; typedef TQValueList PixmapList; typedef TQValueList StateList; class TQSvgDevicePrivate { public: ImageList images; PixmapList pixmaps; StateList stack; int currentClip; uint justRestored : 1; TQMap clipPathTable; }; enum ElementType { InvalidElement = 0, AnchorElement, CircleElement, ClipElement, CommentElement, DescElement, EllipseElement, GroupElement, ImageElement, LineElement, PolylineElement, PolygonElement, PathElement, RectElement, SvgElement, TextElement, TitleElement, TSpanElement }; typedef TQMap TQSvgTypeMap; static TQSvgTypeMap *qSvgTypeMap=0; // element types static TQMap *qSvgColMap=0; // recognized color keyword names /*! \class TQSvgDevice qsvgdevice.h \brief The TQSvgDevice class provides a paint device for SVG vector graphics. \if defined(commercial) It is part of the TQt Enterprise Edition. \endif \ingroup xml-tools \module XML \internal SVG is an XML vector graphics format. This class supports the loading and saving of SVG files with load() and save(), and the rendering of an SVG onto a TQPainter using play(). Use toString() to put the SVG into a string. \sa TQPaintDevice TQPainter */ /*! Creates a TQSvgDevice object. */ TQSvgDevice::TQSvgDevice() : TQPaintDevice( TQInternal::ExternalDevice ), pt( 0 ) { d = new TQSvgDevicePrivate; d->currentClip = 0; d->justRestored = FALSE; } /*! Destroys the TQSvgDevice object and frees the resources it used. */ TQSvgDevice::~TQSvgDevice() { delete qSvgTypeMap; qSvgTypeMap = 0; // static delete qSvgColMap; qSvgColMap = 0; delete d; } /*! Loads and parses a SVG from \a dev into the device. Returns TRUE on success (i.e. loaded and parsed without error); otherwise returns FALSE. */ bool TQSvgDevice::load( TQIODevice *dev ) { return doc.setContent( dev ); } /*! Renders (replays) the SVG on the \a painter and returns TRUE if successful (i.e. it is a valid SVG); otherwise returns FALSE. */ bool TQSvgDevice::play( TQPainter *painter ) { if ( !painter ) { #if defined(QT_CHECK_RANGE) Q_ASSERT( painter ); #endif return FALSE; } pt = painter; pt->setPen( TQt::NoPen ); // SVG default pen and brush pt->setBrush( TQt::black ); if ( doc.isNull() ) { tqWarning( "TQSvgDevice::play: No SVG data set." ); return FALSE; } TQDomNode svg = doc.namedItem( "svg" ); if ( svg.isNull() || !svg.isElement() ) { tqWarning( "TQSvgDevice::play: Couldn't find any svg element." ); return FALSE; } // force transform to be activated in case our sequences // are replayed later with a transformed painter painter->setWorldXForm( TRUE ); TQDomNamedNodeMap attr = svg.attributes(); int x = lenToInt( attr, "x" ); int y = lenToInt( attr, "y" ); brect.setX( x ); brect.setY( y ); TQString wstr = attr.contains( "width" ) ? attr.namedItem( "width" ).nodeValue() : TQString( "100%" ); TQString hstr = attr.contains( "height" ) ? attr.namedItem( "height" ).nodeValue() : TQString( "100%" ); double width = parseLen( wstr, 0, TRUE ); double height = parseLen( hstr, 0, FALSE ); // SVG doesn't respect x and y. But we want a proper bounding rect. brect.setWidth( int(width) - x ); brect.setHeight( int(height) - y ); painter->setClipRect( brect, TQPainter::CoordPainter ); if ( attr.contains( "viewBox" ) ) { TQRegExp re( TQString::fromLatin1("\\s*(\\S+)\\s*,?\\s*(\\S+)\\s*,?" "\\s*(\\S+)\\s*,?\\s*(\\S+)\\s*") ); if ( re.search( attr.namedItem( "viewBox" ).nodeValue() ) < 0 ) { tqWarning( "TQSvgDevice::play: Invalid viewBox attribute."); return FALSE; } else { double x = re.cap( 1 ).toDouble(); double y = re.cap( 2 ).toDouble(); double w = re.cap( 3 ).toDouble(); double h = re.cap( 4 ).toDouble(); if ( w < 0 || h < 0 ) { tqWarning( "TQSvgDevice::play: Invalid viewBox dimension."); return FALSE; } else if ( w == 0 || h == 0 ) { return TRUE; } painter->scale( width/w, height/h ); painter->translate( -x, -y ); } } const struct ElementTable { const char *name; ElementType type; } etab[] = { { "a", AnchorElement }, { "#comment", CommentElement }, { "circle", CircleElement }, { "clipPath", ClipElement }, { "desc", DescElement }, { "ellipse", EllipseElement }, { "g", GroupElement }, { "image", ImageElement }, { "line", LineElement }, { "polyline", PolylineElement }, { "polygon", PolygonElement }, { "path", PathElement }, { "rect", RectElement }, { "svg", SvgElement }, { "text", TextElement }, { "tspan", TSpanElement }, { "title", TitleElement }, { 0, InvalidElement } }; // initialize only once if ( !qSvgTypeMap ) { qSvgTypeMap = new TQSvgTypeMap; const ElementTable *t = etab; while ( t->name ) { qSvgTypeMap->insert( t->name, t->type ); t++; } } // initial state TQSvgDeviceState st; st.textx = st.texty = 0; st.textalign = TQt::AlignLeft; d->stack.append(st); curr = &d->stack.last(); // 'play' all elements recursively starting with 'svg' as root bool b = play( svg ); d->stack.remove( d->stack.begin() ); return b; } /*! Returns the SVG as a single string of XML. */ TQString TQSvgDevice::toString() const { if ( doc.isNull() ) return TQString(); return doc.toString(); } /*! Saves the SVG to \a fileName. */ bool TQSvgDevice::save( const TQString &fileName ) { // guess svg id from fileName TQString svgName = fileName.endsWith( ".svg" ) ? fileName.left( fileName.length()-4 ) : fileName; // now we have the info about name and dimensions available TQDomElement root = doc.documentElement(); root.setAttribute( "id", svgName ); // the standard doesn't take respect x and y. But we want a // proper bounding rect. We make width and height bigger when // writing out and subtract x and y when reading in. root.setAttribute( "x", brect.x() ); root.setAttribute( "y", brect.y() ); root.setAttribute( "width", brect.width() + brect.x() ); root.setAttribute( "height", brect.height() + brect.y() ); // ... and know how to name any image files to be written out int icount = 0; ImageList::Iterator iit = d->images.begin(); for ( ; iit != d->images.end(); ++iit ) { TQString href = TQString( "%1_%2.png" ).arg( svgName ).arg( icount ); (*iit).image.save( href, "PNG" ); (*iit).element.setAttribute( "xlink:href", href ); icount++; } PixmapList::Iterator pit = d->pixmaps.begin(); for ( ; pit != d->pixmaps.end(); ++pit ) { TQString href = TQString( "%1_%2.png" ).arg( svgName ).arg( icount ); (*pit).pixmap.save( href, "PNG" ); (*pit).element.setAttribute( "xlink:href", href ); icount++; } TQFile f( fileName ); if ( !f.open ( IO_WriteOnly ) ) return FALSE; TQTextStream s( &f ); s.setEncoding( TQTextStream::UnicodeUTF8 ); s << doc; return TRUE; } /*! \overload \a dev is the device to use for saving. */ bool TQSvgDevice::save( TQIODevice *dev ) { #if defined(CHECK_RANGE) if ( !d->images.isEmpty() || !d->pixmaps.isEmpty() ) tqWarning( "TQSvgDevice::save: skipping external images" ); #endif TQTextStream s( dev ); s.setEncoding( TQTextStream::UnicodeUTF8 ); s << doc; return TRUE; } /*! \fn TQRect TQSvgDevice::boundingRect() const Returns the bounding rectangle of the SVG. */ /*! Sets the bounding rectangle of the SVG to rectangle \a r. */ void TQSvgDevice::setBoundingRect( const TQRect &r ) { brect = r; } /*! Internal implementation of the virtual TQPaintDevice::metric() function. \warning Use the TQPaintDeviceMetrics class instead. A TQSvgDevice has the following hard coded values: dpi=72, numcolors=16777216 and depth=24. \a m is the metric to get. */ int TQSvgDevice::metric( int m ) const { int val; switch ( m ) { case TQPaintDeviceMetrics::PdmWidth: val = brect.width(); break; case TQPaintDeviceMetrics::PdmHeight: val = brect.height(); break; case TQPaintDeviceMetrics::PdmWidthMM: val = int(25.4/72.0*brect.width()); break; case TQPaintDeviceMetrics::PdmHeightMM: val = int(25.4/72.0*brect.height()); break; case TQPaintDeviceMetrics::PdmDpiX: val = 72; break; case TQPaintDeviceMetrics::PdmDpiY: val = 72; break; case TQPaintDeviceMetrics::PdmNumColors: val = 16777216; break; case TQPaintDeviceMetrics::PdmDepth: val = 24; break; default: val = 0; #if defined(QT_CHECK_RANGE) tqWarning( "TQSvgDevice::metric: Invalid metric command" ); #endif } return val; } /*! \internal Records painter commands and stores them in the TQDomDocument doc. */ bool TQSvgDevice::cmd ( int c, TQPainter *painter, TQPDevCmdParam *p ) { pt = painter; if ( c == PdcBegin ) { TQDomImplementation domImpl; TQDomDocumentType docType = domImpl.createDocumentType( "svg", publicId, systemId ); doc = domImpl.createDocument( "http://www.w3.org/2000/svg", "svg", docType ); doc.insertBefore( doc.createProcessingInstruction( "xml", piData ), doc.firstChild() ); current = doc.documentElement(); d->images.clear(); d->pixmaps.clear(); dirtyTransform = dirtyStyle = FALSE; // ### return TRUE; } else if ( c == PdcEnd ) { return TRUE; } TQDomElement e; TQString str; TQRect rect; TQPointArray a; int i, width, height, x, y; switch ( c ) { case PdcNOP: break; case PdcMoveTo: curPt = *p[0].point; break; case PdcLineTo: e = doc.createElement( "line" ); e.setAttribute( "x1", curPt.x() ); e.setAttribute( "y1", curPt.y() ); e.setAttribute( "x2", p[0].point->x() ); e.setAttribute( "y2", p[0].point->y() ); break; case PdcDrawPoint: case PdcDrawLine: e = doc.createElement( "line" ); e.setAttribute( "x1", p[0].point->x() ); e.setAttribute( "y1", p[0].point->y() ); i = ( c == PdcDrawLine ) ? 1 : 0; e.setAttribute( "x2", p[i].point->x() ); e.setAttribute( "y2", p[i].point->y() ); break; case PdcDrawRect: case PdcDrawRoundRect: e = doc.createElement( "rect" ); x = p[0].rect->x(); y = p[0].rect->y(); width = p[0].rect->width(); height = p[0].rect->height(); if ( width < 0 ) { width = -width; x -= width - 1; } if ( height < 0 ) { height = -height; y -= height - 1; } e.setAttribute( "x", x ); e.setAttribute( "y", y ); e.setAttribute( "width", width ); e.setAttribute( "height", height ); if ( c == PdcDrawRoundRect ) { e.setAttribute( "rx", (p[1].ival*p[0].rect->width())/200 ); e.setAttribute( "ry", (p[2].ival*p[0].rect->height())/200 ); } break; case PdcDrawEllipse: rect = *p[0].rect; if ( rect.width() == rect.height() ) { e = doc.createElement( "circle" ); double cx = rect.x() + (rect.width() / 2.0); double cy = rect.y() + (rect.height() / 2.0); e.setAttribute( "cx", cx ); e.setAttribute( "cy", cy ); e.setAttribute( "r", cx - rect.x() ); } else { e = doc.createElement( "ellipse" ); double cx = rect.x() + (rect.width() / 2.0); double cy = rect.y() + (rect.height() / 2.0); e.setAttribute( "cx", cx ); e.setAttribute( "cy", cy ); e.setAttribute( "rx", cx - rect.x() ); e.setAttribute( "ry", cy - rect.y() ); } break; case PdcDrawArc: case PdcDrawPie: case PdcDrawChord: { rect = *p[0].rect; double a = (double)p[1].ival / 16.0 * deg2rad; double al = (double)p[2].ival / 16.0 * deg2rad; double rx = rect.width() / 2.0; double ry = rect.height() / 2.0; double x0 = (double)rect.x() + rx; double y0 = (double)rect.y() + ry; double x1 = x0 + rx*cos(a); double y1 = y0 - ry*sin(a); double x2 = x0 + rx*cos(a+al); double y2 = y0 - ry*sin(a+al); int large = TQABS( al ) > ( 180.0 * deg2rad ) ? 1 : 0; int sweep = al < 0.0 ? 1 : 0; if ( c == PdcDrawPie ) str = TQString( "M %1 %2 L %3 %4 " ).arg( x0 ).arg( y0 ) .arg( x1 ).arg( y1 ); else str = TQString( "M %1 %2 " ).arg( x1 ).arg( y1 ); str += TQString( "A %1 %2 %3 %4 %5 %6 %7" ) .arg( rx ).arg( ry ).arg( a/deg2rad ). arg( large ).arg( sweep ) .arg( x2 ).arg( y2 ); if ( c != PdcDrawArc ) str += "z"; e = doc.createElement( "path" ); e.setAttribute( "d", str ); } break; case PdcDrawLineSegments: { a = *p[0].ptarr; uint end = a.size() / 2; for (uint i = 0; i < end; i++) { e = doc.createElement( "line" ); e.setAttribute( "x1", a[int(2*i)].x() ); e.setAttribute( "y1", a[int(2*i)].y() ); e.setAttribute( "x2", a[int(2*i+1)].x() ); e.setAttribute( "y2", a[int(2*i+1)].y() ); if ( i < end - 1 ) // The last one will be done at the end appendChild( e, c ); } } break; case PdcDrawPolyline: case PdcDrawPolygon: { a = *p[0].ptarr; e = doc.createElement( ( c == PdcDrawPolyline ) ? "polyline" : "polygon" ); for (uint i = 0; i < a.size(); i++) { TQString tmp; tmp.sprintf( "%d %d ", a[ (int)i ].x(), a[ (int)i ].y() ); str += tmp; } e.setAttribute( "points", str.stripWhiteSpace() ); } break; #ifndef TQT_NO_BEZIER case PdcDrawCubicBezier: a = *p[0].ptarr; e = doc.createElement( "path" ); str.sprintf( "M %d %d C %d %d %d %d %d %d", a[0].x(), a[0].y(), a[1].x(), a[1].y(), a[2].x(), a[2].y(), a[3].x(), a[3].y() ); e.setAttribute( "d", str ); break; #endif case PdcDrawText2: e = doc.createElement( "text" ); if ( p[0].point->x() ) e.setAttribute( "x", p[0].point->x() ); if ( p[0].point->y() ) e.setAttribute( "y", p[0].point->y() ); e.appendChild( doc.createTextNode( *p[1].str ) ); break; case PdcDrawText2Formatted: { e = doc.createElement( "text" ); const TQRect *r = p[0].rect; int tf = p[1].ival; int x, y; // horizontal text alignment if ( ( tf & TQt::AlignHCenter ) != 0 ) { x = r->x() + r->width() / 2; e.setAttribute( "text-anchor", "middle" ); } else if ( ( tf & TQt::AlignRight ) != 0 ) { x = r->right(); e.setAttribute( "text-anchor", "end" ); } else { x = r->x(); } // vertical text alignment if ( ( tf & TQt::AlignVCenter ) != 0 ) y = r->y() + ( r->height() + painter->fontMetrics().ascent() ) / 2; else if ( ( tf & TQt::AlignBottom ) != 0 ) y = r->bottom(); else y = r->y() + painter->fontMetrics().ascent(); if ( x ) e.setAttribute( "x", x ); if ( y ) e.setAttribute( "y", y ); e.appendChild( doc.createTextNode( *p[2].str ) ); } break; case PdcDrawPixmap: case PdcDrawImage: e = doc.createElement( "image" ); e.setAttribute( "x", p[0].rect->x() ); e.setAttribute( "y", p[0].rect->y() ); e.setAttribute( "width", p[0].rect->width() ); e.setAttribute( "height", p[0].rect->height() ); if ( c == PdcDrawImage ) { ImgElement ie; ie.element = e; ie.image = *p[1].image; d->images.append( ie ); } else { PixElement pe; pe.element = e; pe.pixmap = *p[1].pixmap; d->pixmaps.append( pe ); } // saving to disk and setting the xlink:href attribute will be // done later in save() once we now the svg document name. break; case PdcSave: e = doc.createElement( "g" ); break; case PdcRestore: current = current.parentNode(); dirtyTransform = !pt->worldMatrix().isIdentity(); d->justRestored = TRUE; // ### reset dirty flags break; case PdcSetBkColor: case PdcSetBkMode: case PdcSetROP: case PdcSetBrushOrigin: case PdcSetFont: case PdcSetPen: case PdcSetBrush: dirtyStyle = TRUE; break; case PdcSetTabStops: // ### break; case PdcSetTabArray: // ### break; case PdcSetVXform: case PdcSetWindow: case PdcSetViewport: case PdcSetWXform: case PdcSetWMatrix: case PdcSaveWMatrix: case PdcRestoreWMatrix: dirtyTransform = TRUE; break; case PdcSetClip: // ### break; case PdcSetClipRegion: { // We skip the clip after restore, since restoring the clip is done automatically by // the viewer as part of the tree structure. It doesn't hurt to write the region // out, but it doubles the number of clipregions defined in the final svg. if (d->justRestored) { d->justRestored = FALSE; return TRUE; } TQMemArray rects = p[0].rgn->rects(); if (rects.count() == 0) return TRUE; d->currentClip++; e = doc.createElement( "clipPath" ); e.setAttribute( "id", TQString("clip%1").arg(d->currentClip) ); for (int i=0; i<(int)rects.count(); ++i) { TQDomElement ce = doc.createElement("rect"); ce.setAttribute( "x", rects.at(i).x() ); ce.setAttribute( "y", rects.at(i).y() ); ce.setAttribute( "width", rects.at(i).width() ); ce.setAttribute( "height", rects.at(i).height() ); e.appendChild(ce); } break; } default: #if defined(CHECK_RANGE) tqWarning( "TQSVGDevice::cmd: Invalid command %d", c ); #endif break; } appendChild( e, c ); return TRUE; } /*! \internal Appends the child and applys any style and transformation. */ void TQSvgDevice::appendChild( TQDomElement &e, int c ) { if ( !e.isNull() ) { current.appendChild( e ); if ( c == PdcSave ) current = e; // ### optimize application of attributes utilizing if ( c == PdcSetClipRegion ) { TQDomElement ne; ne = doc.createElement( "g" ); ne.setAttribute( "style", TQString("clip-path:url(#clip%1)").arg(d->currentClip) ); current.appendChild( ne ); current = ne; } else { if ( dirtyStyle ) // only reset when entering applyStyle( &e, c ); // or leaving a tag if ( dirtyTransform && e.tagName() != "g" ) { // same as above but not for tags applyTransform( &e ); if ( c == PdcSave ) dirtyTransform = FALSE; } } } } /*! \internal Push the current drawing attributes on a stack. \sa restoreAttributes() */ void TQSvgDevice::saveAttributes() { pt->save(); // copy old state TQSvgDeviceState st( *curr ); d->stack.append( st ); curr = &d->stack.last(); } /*! \internal Pop the current drawing attributes off the stack. \sa saveAttributes() */ void TQSvgDevice::restoreAttributes() { pt->restore(); Q_ASSERT( d->stack.count() > 1 ); d->stack.remove( d->stack.fromLast() ); curr = &d->stack.last(); } /*! \internal Evaluate \a node, drawing on \a p. Allows recursive calls. */ bool TQSvgDevice::play( const TQDomNode &node ) { saveAttributes(); ElementType t = (*qSvgTypeMap)[ node.nodeName() ]; if ( t == LineElement && pt->pen().style() == TQt::NoPen ) { TQPen p = pt->pen(); p.setStyle( TQt::SolidLine ); pt->setPen( p ); } TQDomNamedNodeMap attr = node.attributes(); if ( attr.contains( "style" ) ) setStyle( attr.namedItem( "style" ).nodeValue() ); // ### might have to exclude more elements from transform if ( t != SvgElement && attr.contains( "transform" ) ) setTransform( attr.namedItem( "transform" ).nodeValue() ); uint i = attr.length(); if ( i > 0 ) { TQPen pen = pt->pen(); TQFont font = pt->font(); while ( i-- ) { TQDomNode n = attr.item( i ); TQString a = n.nodeName(); TQString val = n.nodeValue().lower().stripWhiteSpace(); setStyleProperty( a, val, &pen, &font, &curr->textalign ); } pt->setPen( pen ); pt->setFont( font ); } int x1, y1, x2, y2, rx, ry, w, h; double cx1, cy1, crx, cry; switch ( t ) { case CommentElement: // ignore break; case RectElement: rx = ry = 0; x1 = lenToInt( attr, "x" ); y1 = lenToInt( attr, "y" ); w = lenToInt( attr, "width" ); h = lenToInt( attr, "height" ); if ( w == 0 || h == 0 ) // prevent div by zero below break; x2 = (int)attr.contains( "rx" ); // tiny abuse of x2 and y2 y2 = (int)attr.contains( "ry" ); if ( x2 ) rx = lenToInt( attr, "rx" ); if ( y2 ) ry = lenToInt( attr, "ry" ); if ( x2 && !y2 ) ry = rx; else if ( !x2 && y2 ) rx = ry; rx = int(200.0*double(rx)/double(w)); ry = int(200.0*double(ry)/double(h)); pt->drawRoundRect( x1, y1, w, h, rx, ry ); break; case CircleElement: cx1 = lenToDouble( attr, "cx" ) + 0.5; cy1 = lenToDouble( attr, "cy" ) + 0.5; crx = lenToDouble( attr, "r" ); pt->drawEllipse( (int)(cx1-crx), (int)(cy1-crx), (int)(2*crx), (int)(2*crx) ); break; case EllipseElement: cx1 = lenToDouble( attr, "cx" ) + 0.5; cy1 = lenToDouble( attr, "cy" ) + 0.5; crx = lenToDouble( attr, "rx" ); cry = lenToDouble( attr, "ry" ); pt->drawEllipse( (int)(cx1-crx), (int)(cy1-cry), (int)(2*crx), (int)(2*cry) ); break; case LineElement: { x1 = lenToInt( attr, "x1" ); x2 = lenToInt( attr, "x2" ); y1 = lenToInt( attr, "y1" ); y2 = lenToInt( attr, "y2" ); TQPen p = pt->pen(); w = p.width(); p.setWidth( (unsigned int)(w * (TQABS(pt->worldMatrix().m11()) + TQABS(pt->worldMatrix().m22())) / 2) ); pt->setPen( p ); pt->drawLine( x1, y1, x2, y2 ); p.setWidth( w ); pt->setPen( p ); } break; case PolylineElement: case PolygonElement: { TQString pts = attr.namedItem( "points" ).nodeValue(); pts = pts.simplifyWhiteSpace(); TQStringList sl = TQStringList::split( TQRegExp( TQString::fromLatin1("[ ,]") ), pts ); TQPointArray ptarr( (uint)sl.count() / 2); for ( int i = 0; i < (int)sl.count() / 2; i++ ) { double dx = sl[2*i].toDouble(); double dy = sl[2*i+1].toDouble(); ptarr.setPoint( i, int(dx), int(dy) ); } if ( t == PolylineElement ) { if ( pt->brush().style() != TQt::NoBrush ) { TQPen pn = pt->pen(); pt->setPen( TQt::NoPen ); pt->drawPolygon( ptarr ); pt->setPen( pn ); } pt->drawPolyline( ptarr ); // ### closes when filled. bug ? } else { pt->drawPolygon( ptarr ); } } break; case SvgElement: case GroupElement: case AnchorElement: { TQDomNode child = node.firstChild(); while ( !child.isNull() ) { play( child ); child = child.nextSibling(); } } break; case PathElement: drawPath( attr.namedItem( "d" ).nodeValue() ); break; case TSpanElement: case TextElement: { if ( attr.contains( "x" ) ) curr->textx = lenToInt( attr, "x" ); if ( attr.contains( "y" ) ) curr->texty = lenToInt( attr, "y" ); if ( t == TSpanElement ) { curr->textx += lenToInt( attr, "dx" ); curr->texty += lenToInt( attr, "dy" ); } // backup old colors TQPen pn = pt->pen(); TQColor pcolor = pn.color(); TQColor bcolor = pt->brush().color(); TQDomNode c = node.firstChild(); while ( !c.isNull() ) { if ( c.isText() ) { // we have pen and brush reversed for text drawing pn.setColor( bcolor ); pt->setPen( pn ); TQString text = c.toText().nodeValue(); text = text.simplifyWhiteSpace(); // ### 'preserve' w = pt->fontMetrics().width( text ); if ( curr->textalign == TQt::AlignHCenter ) curr->textx -= w / 2; else if ( curr->textalign == TQt::AlignRight ) curr->textx -= w; pt->drawText( curr->textx, curr->texty, text ); // restore pen pn.setColor( pcolor ); pt->setPen( pn ); curr->textx += w; } else if ( c.isElement() && c.toElement().tagName() == "tspan" ) { play( c ); } c = c.nextSibling(); } if ( t == TSpanElement ) { // move current text position in parent text element StateList::Iterator it = --d->stack.fromLast(); (*it).textx = curr->textx; (*it).texty = curr->texty; } } break; case ImageElement: { x1 = lenToInt( attr, "x" ); y1 = lenToInt( attr, "y" ); w = lenToInt( attr, "width" ); h = lenToInt( attr, "height" ); TQString href = attr.namedItem( "xlink:href" ).nodeValue(); // ### catch references to embedded .svg files TQPixmap pix; if ( !pix.load( href ) ) { tqWarning( "TQSvgDevice::play: Couldn't load image %s", href.latin1() ); break; } pt->drawPixmap( TQRect( x1, y1, w, h ), pix ); } break; case DescElement: case TitleElement: // ignored for now break; case ClipElement: { TQDomNode child = node.firstChild(); TQRegion region; while (!child.isNull()) { TQDomNamedNodeMap childAttr = child.attributes(); if ( child.nodeName() == "rect" ) { TQRect r; r.setX(lenToInt( childAttr, "x" )); r.setY(lenToInt( childAttr, "y" )); r.setWidth(lenToInt( childAttr, "width" )); r.setHeight(lenToInt( childAttr, "height" )); region |= r; } else if ( child.nodeName() == "ellipse" ) { TQRect r; int x = lenToInt( childAttr, "cx" ); int y = lenToInt( childAttr, "cy" ); int width = lenToInt( childAttr, "rx" ); int height = lenToInt( childAttr, "ry" ); r.setX( x - width ); r.setY( y - height ); r.setWidth( width * 2 ); r.setHeight( height * 2 ); TQRegion rgn( r, TQRegion::Ellipse ); region |= rgn; } child = child.nextSibling(); } // Store the region in a named map so that it can be used when the // group node is entered. TQString idString = attr.namedItem("id").nodeValue(); if (!idString.isEmpty()) d->clipPathTable[idString] = region; break; } case InvalidElement: tqWarning( "TQSvgDevice::play: unknown element type %s", node.nodeName().latin1() ); break; }; restoreAttributes(); return TRUE; } /*! \internal Parses a CSS2-compatible color specification. Either a keyword or a numerical RGB specification like #ff00ff or rgb(255,0,50%). */ TQColor TQSvgDevice::parseColor( const TQString &col ) { static const struct ColorTable { const char *name; const char *rgb; } coltab[] = { { "black", "#000000" }, { "silver", "#c0c0c0" }, { "gray", "#808080" }, { "white", "#ffffff" }, { "maroon", "#800000" }, { "red", "#ff0000" }, { "purple", "#800080" }, { "fuchsia", "#ff00ff" }, { "green", "#008000" }, { "lime", "#00ff00" }, { "olive", "#808000" }, { "yellow", "#ffff00" }, { "navy", "#000080" }, { "blue", "#0000ff" }, { "teal", "#008080" }, { "aqua", "#00ffff" }, // ### the latest spec has more { 0, 0 } }; // initialize color map on first use if ( !qSvgColMap ) { qSvgColMap = new TQMap; const struct ColorTable *t = coltab; while ( t->name ) { qSvgColMap->insert( t->name, t->rgb ); t++; } } // a keyword ? if ( qSvgColMap->contains ( col ) ) return TQColor( (*qSvgColMap)[ col ] ); // in rgb(r,g,b) form ? TQString c = col; c.replace( TQRegExp( TQString::fromLatin1("\\s*") ), "" ); TQRegExp reg( TQString::fromLatin1("^rgb\$(\\d+)(%?),(\\d+)(%?),(\\d+)(%?)\$$") ); if ( reg.search( c ) >= 0 ) { int comp[3]; for ( int i = 0; i < 3; i++ ) { comp[ i ] = reg.cap( 2*i+1 ).toInt(); if ( !reg.cap( 2*i+2 ).isEmpty() ) // percentage ? comp[ i ] = int((double(255*comp[ i ])/100.0)); } return TQColor( comp[ 0 ], comp[ 1 ], comp[ 2 ] ); } // check for predefined TQt color objects, #RRGGBB and #RGB return TQColor( col ); } /*! \internal Parse a datatype consisting of a number followed by an optional unit specifier. Can be used for type as well. For relative units the value of \a horiz will determine whether the horizontal or vertical dimension will be used. */ double TQSvgDevice::parseLen( const TQString &str, bool *ok, bool horiz ) const { TQRegExp reg( TQString::fromLatin1("([+-]?\\d*\\.*\\d*[Ee]?[+-]?\\d*)(em|ex|px|%|pt|pc|cm|mm|in|)$") ); if ( reg.search( str ) == -1 ) { tqWarning( "TQSvgDevice::parseLen: couldn't parse %s ", str.latin1() ); if ( ok ) *ok = FALSE; return 0.0; } double dbl = reg.cap( 1 ).toDouble(); TQString u = reg.cap( 2 ); if ( !u.isEmpty() && u != "px" ) { TQPaintDeviceMetrics m( pt->device() ); if ( u == "em" ) { TQFontInfo fi( pt->font() ); dbl *= fi.pixelSize(); } else if ( u == "ex" ) { TQFontInfo fi( pt->font() ); dbl *= 0.5 * fi.pixelSize(); } else if ( u == "%" ) dbl *= (horiz ? pt->window().width() : pt->window().height())/100.0; else if ( u == "cm" ) dbl *= m.logicalDpiX() / 2.54; else if ( u == "mm" ) dbl *= m.logicalDpiX() / 25.4; else if ( u == "in" ) dbl *= m.logicalDpiX(); else if ( u == "pt" ) dbl *= m.logicalDpiX() / 72.0; else if ( u == "pc" ) dbl *= m.logicalDpiX() / 6.0; else tqWarning( "TQSvgDevice::parseLen: Unknown unit %s", u.latin1() ); } if ( ok ) *ok = TRUE; return dbl; } /*! \internal Returns the length specified in attribute \a attr in \a map. If the specified attribute doesn't exist or can't be parsed \a def is returned. */ int TQSvgDevice::lenToInt( const TQDomNamedNodeMap &map, const TQString &attr, int def ) const { if ( map.contains( attr ) ) { bool ok; double dbl = parseLen( map.namedItem( attr ).nodeValue(), &ok ); if ( ok ) return tqRound( dbl ); } return def; } double TQSvgDevice::lenToDouble( const TQDomNamedNodeMap &map, const TQString &attr, int def ) const { if ( map.contains( attr ) ) { bool ok; double d = parseLen( map.namedItem( attr ).nodeValue(), &ok ); if ( ok ) return d; } return def; } void TQSvgDevice::setStyleProperty( const TQString &prop, const TQString &val, TQPen *pen, TQFont *font, int *talign ) { if ( prop == "stroke" ) { if ( val == "none" ) { pen->setStyle( TQt::NoPen ); } else { pen->setColor( parseColor( val )); if ( pen->style() == TQt::NoPen ) pen->setStyle( TQt::SolidLine ); if ( pen->width() == 0 ) pen->setWidth( 1 ); } } else if ( prop == "stroke-width" ) { double w = parseLen( val ); if ( w > 0.0001 ) pen->setWidth( int(w) ); else pen->setStyle( TQt::NoPen ); } else if ( prop == "stroke-linecap" ) { if ( val == "butt" ) pen->setCapStyle( TQt::FlatCap ); else if ( val == "round" ) pen->setCapStyle( TQt::RoundCap ); else if ( val == "square" ) pen->setCapStyle( TQt::SquareCap ); } else if ( prop == "stroke-linejoin" ) { if ( val == "miter" ) pen->setJoinStyle( TQt::MiterJoin ); else if ( val == "round" ) pen->setJoinStyle( TQt::RoundJoin ); else if ( val == "bevel" ) pen->setJoinStyle( TQt::BevelJoin ); } else if ( prop == "stroke-dasharray" ) { if ( val == "18,6" ) pen->setStyle( TQt::DashLine ); else if ( val == "3" ) pen->setStyle( TQt::DotLine ); else if ( val == "9,6,3,6" ) pen->setStyle( TQt::DashDotLine ); else if ( val == "9,3,3" ) pen->setStyle( TQt::DashDotDotLine ); else pen->setStyle( TQt::DotLine ); } else if ( prop == "fill" ) { if ( val == "none" ) pt->setBrush( TQt::NoBrush ); else pt->setBrush( parseColor( val ) ); } else if ( prop == "font-size" ) { font->setPointSizeFloat( float(parseLen( val )) ); } else if ( prop == "font-family" ) { font->setFamily( val ); } else if ( prop == "font-style" ) { if ( val == "normal" ) font->setItalic( FALSE ); else if ( val == "italic" ) font->setItalic( TRUE ); else tqWarning( "TQSvgDevice::setStyleProperty: unhandled " "font-style: %s", val.latin1() ); } else if ( prop == "font-weight" ) { int w = font->weight(); // no exact equivalents so we have to "round" a little bit if ( val == "100" || val == "200" ) w = TQFont::Light; if ( val == "300" || val == "400" || val == "normal" ) w = TQFont::Normal; else if ( val == "500" || val == "600" ) w = TQFont::DemiBold; else if ( val == "700" || val == "bold" || val == "800" ) w = TQFont::Bold; else if ( val == "900" ) w = TQFont::Black; font->setWeight( w ); } else if ( prop == "text-anchor" ) { if ( val == "middle" ) *talign = TQt::AlignHCenter; else if ( val == "end" ) *talign = TQt::AlignRight; else *talign = TQt::AlignLeft; } else if ( prop == "clip-path" ) { if (val.startsWith("url(#")) { TQString clipName = val.mid(5, val.length() - 6); if (!clipName.isEmpty()) { TQRegion clipRegion = d->clipPathTable[clipName]; if (!clipRegion.isEmpty()) pt->setClipRegion(pt->clipRegion() & clipRegion, TQPainter::CoordPainter); } } } } void TQSvgDevice::setStyle( const TQString &s ) { TQStringList rules = TQStringList::split( TQChar(';'), s ); TQPen pen = pt->pen(); TQFont font = pt->font(); TQStringList::ConstIterator it = rules.begin(); for ( ; it != rules.end(); it++ ) { int col = (*it).find( ':' ); if ( col > 0 ) { TQString prop = (*it).left( col ).simplifyWhiteSpace(); TQString val = (*it).right( (*it).length() - col - 1 ); val = val.lower().stripWhiteSpace(); setStyleProperty( prop, val, &pen, &font, &curr->textalign ); } } pt->setPen( pen ); pt->setFont( font ); } void TQSvgDevice::setTransform( const TQString &tr ) { TQString t = tr.simplifyWhiteSpace(); TQRegExp reg( TQString::fromLatin1("\\s*([\\w]+)\\s*\$([^\\(]*)\$") ); int index = 0; while ( (index = reg.search(t, index)) >= 0 ) { TQString command = reg.cap( 1 ); TQString params = reg.cap( 2 ); TQStringList plist = TQStringList::split( TQRegExp(TQString::fromLatin1("[,\\s]")), params ); if ( command == "translate" ) { double tx = 0, ty = 0; tx = plist[0].toDouble(); if ( plist.count() >= 2 ) ty = plist[1].toDouble(); pt->translate( tx, ty ); } else if ( command == "rotate" ) { pt->rotate( plist[0].toDouble() ); } else if ( command == "scale" ) { double sx, sy; sx = sy = plist[0].toDouble(); if ( plist.count() >= 2 ) sy = plist[1].toDouble(); pt->scale( sx, sy ); } else if ( command == "matrix" && plist.count() >= 6 ) { double m[ 6 ]; for (int i = 0; i < 6; i++) m[ i ] = plist[ i ].toDouble(); TQWMatrix wm( m[ 0 ], m[ 1 ], m[ 2 ], m[ 3 ], m[ 4 ], m[ 5 ] ); pt->setWorldMatrix( wm, TRUE ); } else if ( command == "skewX" ) { pt->shear( 0.0, tan( plist[0].toDouble() * deg2rad ) ); } else if ( command == "skewY" ) { pt->shear( tan( plist[0].toDouble() * deg2rad ), 0.0 ); } // move on to next command index += reg.matchedLength(); } } void TQSvgDevice::drawPath( const TQString &data ) { double x0 = 0, y0 = 0; // starting point double x = 0, y = 0; // current point double controlX = 0, controlY = 0; // last control point for curves TQPointArray path( 500 ); // resulting path TQValueList subIndex; // start indices for subpaths TQPointArray quad( 4 ), bezier; // for curve calculations int pcount = 0; // current point array index uint idx = 0; // current data position int mode = 0, lastMode = 0; // parser state bool relative = FALSE; // e.g. 'h' vs. 'H' TQString commands( "MZLHVCSTQTA" ); // recognized commands int cmdArgs[] = { 2, 0, 2, 1, 1, 6, 4, 4, 2, 7 }; // no of arguments TQRegExp reg( TQString::fromLatin1("\\s*,?\\s*([+-]?\\d*\\.?\\d*)") ); // floating point subIndex.append( 0 ); // detect next command while ( idx < data.length() ) { TQChar ch = data[ (int)idx++ ]; if ( ch.isSpace() ) continue; TQChar chUp = ch.upper(); int cmd = commands.find( chUp ); if ( cmd >= 0 ) { // switch to new command mode mode = cmd; relative = ( ch != chUp ); // e.g. 'm' instead of 'M' } else { if ( mode && !ch.isLetter() ) { cmd = mode; // continue in previous mode idx--; } else { tqWarning( "TQSvgDevice::drawPath: Unknown command" ); return; } } // read in the required number of arguments const int maxArgs = 7; double arg[ maxArgs ]; int numArgs = cmdArgs[ cmd ]; for ( int i = 0; i < numArgs; i++ ) { int pos = reg.search( data, idx ); if ( pos == -1 ) { tqWarning( "TQSvgDevice::drawPath: Error parsing arguments" ); return; } arg[ i ] = reg.cap( 1 ).toDouble(); idx = pos + reg.matchedLength(); }; // process command double offsetX = relative ? x : 0; // correction offsets double offsetY = relative ? y : 0; // for relative commands switch ( mode ) { case 0: // 'M' move to if ( x != x0 || y != y0 ) path.setPoint( pcount++, int(x0), int(y0) ); x = x0 = arg[ 0 ] + offsetX; y = y0 = arg[ 1 ] + offsetY; subIndex.append( pcount ); path.setPoint( pcount++, int(x0), int(y0) ); mode = 2; // -> 'L' break; case 1: // 'Z' close path path.setPoint( pcount++, int(x0), int(y0) ); x = x0; y = y0; mode = 0; break; case 2: // 'L' line to x = arg[ 0 ] + offsetX; y = arg[ 1 ] + offsetY; path.setPoint( pcount++, int(x), int(y) ); break; case 3: // 'H' horizontal line x = arg[ 0 ] + offsetX; path.setPoint( pcount++, int(x), int(y) ); break; case 4: // 'V' vertical line y = arg[ 0 ] + offsetY; path.setPoint( pcount++, int(x), int(y) ); break; #ifndef TQT_NO_BEZIER case 5: // 'C' cubic bezier curveto case 6: // 'S' smooth shorthand case 7: // 'Q' quadratic bezier curves case 8: { // 'T' smooth shorthand quad.setPoint( 0, int(x), int(y) ); // if possible, reflect last control point if smooth shorthand if ( mode == 6 || mode == 8 ) { // smooth 'S' and 'T' bool cont = mode == lastMode || ( mode == 6 && lastMode == 5 ) || // 'S' and 'C' ( mode == 8 && lastMode == 7 ); // 'T' and 'Q' x = cont ? 2*x-controlX : x; y = cont ? 2*y-controlY : y; quad.setPoint( 1, int(x), int(y) ); quad.setPoint( 2, int(x), int(y) ); } for ( int j = 0; j < numArgs/2; j++ ) { x = arg[ 2*j ] + offsetX; y = arg[ 2*j+1 ] + offsetY; quad.setPoint( j+4-numArgs/2, int(x), int(y) ); } // remember last control point for next shorthand controlX = quad[ 2 ].x(); controlY = quad[ 2 ].y(); // transform quadratic into cubic Bezier if ( mode == 7 || mode == 8 ) { // cubic 'Q' and 'T' int x31 = quad[0].x()+int(2.0*(quad[2].x()-quad[0].x())/3.0); int y31 = quad[0].y()+int(2.0*(quad[2].y()-quad[0].y())/3.0); int x32 = quad[2].x()+int(2.0*(quad[3].x()-quad[2].x())/3.0); int y32 = quad[2].y()+int(2.0*(quad[3].y()-quad[2].y())/3.0); quad.setPoint( 1, x31, y31 ); quad.setPoint( 2, x32, y32 ); } // calculate points on curve bezier = quad.cubicBezier(); // reserve more space if needed if ( bezier.size() > path.size() - pcount ) path.resize( path.size() - pcount + bezier.size() ); // copy for ( int k = 0; k < (int)bezier.size(); k ++ ) path.setPoint( pcount++, bezier[ k ] ); break; } #endif // TQT_NO_BEZIER case 9: // 'A' elliptical arc curve // ### just a straight line x = arg[ 5 ] + offsetX; y = arg[ 6 ] + offsetY; path.setPoint( pcount++, int(x), int(y) ); break; }; lastMode = mode; // array almost full ? expand for next loop if ( pcount >= (int)path.size() - 4 ) path.resize( 2 * path.size() ); } subIndex.append( pcount ); // dummy marking the end if ( pt->brush().style() != TQt::NoBrush ) { // fill the area without stroke first if ( x != x0 || y != y0 ) path.setPoint( pcount++, int(x0), int(y0) ); TQPen pen = pt->pen(); pt->setPen( TQt::NoPen ); pt->drawPolygon( path, FALSE, 0, pcount ); pt->setPen( pen ); } // draw each subpath stroke seperately TQValueListConstIterator it = subIndex.begin(); int start = 0; while ( it != subIndex.fromLast() ) { int next = *++it; // ### always joins ends if first and last point coincide. // ### 'Z' can't have the desired effect pt->drawPolyline( path, start, next-start ); start = next; } } void TQSvgDevice::applyStyle( TQDomElement *e, int c ) const { // ### do not write every attribute each time TQColor pcol = pt->pen().color(); TQColor bcol = pt->brush().color(); TQString s; if ( c == PdcDrawText2 || c == PdcDrawText2Formatted ) { // TQPainter has a reversed understanding of pen/stroke vs. // brush/fill for text s += TQString( "fill:rgb(%1,%2,%3);" ) .arg( pcol.red() ).arg( pcol.green() ).arg( pcol.blue() ); s += TQString( "stroke-width:0;" ); TQFont f = pt->font(); TQFontInfo fi( f ); s += TQString( "font-size:%1;" ).arg( fi.pointSize() ); s += TQString( "font-style:%1;" ) .arg( f.italic() ? "italic" : "normal" ); // not a very scientific distribution TQString fw; if ( f.weight() <= TQFont::Light ) fw = "100"; else if ( f.weight() <= TQFont::Normal ) fw = "400"; else if ( f.weight() <= TQFont::DemiBold ) fw = "600"; else if ( f.weight() <= TQFont::Bold ) fw = "700"; else if ( f.weight() <= TQFont::Black ) fw = "800"; else fw = "900"; s += TQString( "font-weight:%1;" ).arg( fw ); s += TQString( "font-family:%1;" ).arg( f.family() ); } else { s += TQString( "stroke:rgb(%1,%2,%3);" ) .arg( pcol.red() ).arg( pcol.green() ).arg( pcol.blue() ); double pw = pt->pen().width(); if ( pw == 0 && pt->pen().style() != TQt::NoPen ) pw = 0.9; if ( c == PdcDrawLine ) pw /= (TQABS(pt->worldMatrix().m11()) + TQABS(pt->worldMatrix().m22())) / 2.0; s += TQString( "stroke-width:%1;" ).arg( pw ); if ( pt->pen().style() == TQt::DashLine ) s+= TQString( "stroke-dasharray:18,6;" ); else if ( pt->pen().style() == TQt::DotLine ) s+= TQString( "stroke-dasharray:3;" ); else if ( pt->pen().style() == TQt::DashDotLine ) s+= TQString( "stroke-dasharray:9,6,3,6;" ); else if ( pt->pen().style() == TQt::DashDotDotLine ) s+= TQString( "stroke-dasharray:9,3,3;" ); if ( pt->brush().style() == TQt::NoBrush || c == PdcDrawPolyline || c == PdcDrawCubicBezier ) s += "fill:none;"; // TQt polylines use no brush, neither do Beziers else s += TQString( "fill:rgb(%1,%2,%3);" ) .arg( bcol.red() ).arg( bcol.green() ).arg( bcol.blue() ); } e->setAttribute( "style", s ); } void TQSvgDevice::applyTransform( TQDomElement *e ) const { TQWMatrix m = pt->worldMatrix(); TQString s; bool rot = ( m.m11() != 1.0 || m.m12() != 0.0 || m.m21() != 0.0 || m.m22() != 1.0 ); if ( !rot && ( m.dx() != 0.0 || m.dy() != 0.0 ) ) s = TQString( "translate(%1,%2)" ).arg( m.dx() ).arg( m.dy() ); else if ( rot ) { if ( m.m12() == 0.0 && m.m21() == 0.0 && m.dx() == 0.0 && m.dy() == 0.0 ) s = TQString( "scale(%1,%2)" ).arg( m.m11() ).arg( m.m22() ); else s = TQString( "matrix(%1,%2,%3,%4,%5,%6)" ) .arg( m.m11() ).arg( m.m12() ) .arg( m.m21() ).arg( m.m22() ) .arg( m.dx() ).arg( m.dy() ); } else return; e->setAttribute( "transform", s ); } #endif // TQT_NO_SVG