static inline void writeAttributes( std::ostream &out, const GraphAttributes &GA, const node &v) { const long flags = GA.attributes(); out << "["; bool separator = false; // Wheter to put separator before attribute. if(flags & GraphAttributes::nodeId) { writeAttribute(out, separator, "id", GA.idNode(v)); } if(flags & GraphAttributes::nodeLabel) { writeAttribute(out, separator, "label", GA.label(v)); } if(flags & GraphAttributes::nodeTemplate) { writeAttribute(out, separator, "comment", GA.templateNode(v)); } if(flags & GraphAttributes::nodeGraphics) { writeAttribute(out, separator, "width", GA.width(v)); writeAttribute(out, separator, "height", GA.height(v)); writeAttribute(out, separator, "shape", dot::toString(GA.shape(v))); out << ", pos=\"" << GA.x(v) << "," << GA.y(v); if(flags & GraphAttributes::threeD) { out << "," << GA.z(v); } out << "\""; } if(flags & GraphAttributes::nodeStyle) { writeAttribute(out, separator, "color", GA.strokeColor(v)); writeAttribute(out, separator, "fillcolor", GA.fillColor(v)); writeAttribute(out, separator, "stroketype", toString(GA.strokeType(v))); writeAttribute(out, separator, "strokewidth", GA.strokeWidth(v)); writeAttribute(out, separator, "fillpattern", toString(GA.fillPattern(v))); } if(flags & GraphAttributes::nodeType) { writeAttribute(out, separator, "type", int(GA.type(v))); } if(flags & GraphAttributes::nodeWeight) { writeAttribute(out, separator, "weight", GA.weight(v)); } out << "]"; }
static inline void writeAttributes( std::ostream &out, const GraphAttributes &GA, const node &v) { const long flags = GA.attributes(); out << "["; bool separator = false; // Wheter to put separator before attribute. if(flags & GraphAttributes::nodeId) { writeAttribute(out, separator, "id", GA.idNode(v)); } if(flags & GraphAttributes::nodeLabel) { writeAttribute(out, separator, "label", GA.label(v)); } if(flags & GraphAttributes::nodeTemplate) { writeAttribute(out, separator, "comment", GA.templateNode(v)); } if(flags & GraphAttributes::nodeGraphics) { writeAttribute(out, separator, "width", GA.width(v)); writeAttribute(out, separator, "height", GA.height(v)); writeAttribute(out, separator, "shape", dot::toString(GA.shape(v))); out << ", pos=\"" << GA.x(v) << "," << GA.y(v); if(flags & GraphAttributes::threeD) { out << "," << GA.z(v); } out << "\""; } if(flags & GraphAttributes::nodeStyle) { writeAttribute(out, separator, "color", GA.strokeColor(v)); writeAttribute(out, separator, "fillcolor", GA.fillColor(v)); } // NOTE: Node type is weird and (probably) cannot be mapped to DOT. // NOTE: Node weight is not supported. out << "]"; }
static inline void readAttValue( GraphAttributes &GA, node v, const std::string &name, const std::string &value) { const long attrs = GA.attributes(); // For not "viz" attributes, we use GraphML ones. switch(graphml::toAttribute(name)) { case graphml::Attribute::NodeType: if(attrs & GraphAttributes::nodeType) { GA.type(v) = graphml::toNodeType(value); } break; case graphml::Attribute::Template: if(attrs & GraphAttributes::nodeTemplate) { GA.templateNode(v) = value; } break; case graphml::Attribute::NodeWeight: if(attrs & GraphAttributes::nodeWeight) { std::istringstream ss(value); ss >> GA.weight(v); } break; case graphml::Attribute::NodeStrokeType: if(attrs & GraphAttributes::nodeStyle) { GA.strokeType(v) = fromString<StrokeType>(value); } break; case graphml::Attribute::NodeFillPattern: if(attrs & GraphAttributes::nodeStyle) { GA.fillPattern(v) = fromString<FillPattern>(value); } break; case graphml::Attribute::NodeStrokeWidth: if(attrs & GraphAttributes::nodeWeight) { std::istringstream ss(value); ss >> GA.strokeWidth(v); }
bool GraphMLParser::readData( GraphAttributes &GA, const node &v, const pugi::xml_node nodeData) { pugi::xml_attribute keyId = nodeData.attribute("key"); if (!keyId) { GraphIO::logger.lout() << "Node data does not have a key." << endl; return false; } const long attrs = GA.attributes(); pugi::xml_text text = nodeData.text(); switch (graphml::toAttribute(m_attrName[keyId.value()])) { case graphml::a_nodeLabel: if(attrs & GraphAttributes::nodeLabel) { GA.label(v) = text.get(); } break; case graphml::a_x: if(attrs & GraphAttributes::nodeGraphics) { GA.x(v) = text.as_double(); } break; case graphml::a_y: if(attrs & GraphAttributes::nodeGraphics) { GA.y(v) = text.as_double();; } break; case graphml::a_width: if(attrs & GraphAttributes::nodeGraphics) { GA.width(v) = text.as_double(); } break; case graphml::a_height: if(attrs & GraphAttributes::nodeGraphics) { GA.height(v) = text.as_double(); } break; case graphml::a_size: if(attrs & GraphAttributes::nodeGraphics) { double size = text.as_double(); // We want to set a new size only if width and height was not set. if (GA.height(v) == GA.width(v)) { GA.height(v) = GA.width(v) = size; } } break; case graphml::a_shape: if(attrs & GraphAttributes::nodeGraphics) { GA.shape(v) = graphml::toShape(text.get()); } break; case graphml::a_z: if(attrs & GraphAttributes::threeD) { GA.z(v) = text.as_double(); } break; case graphml::a_r: if (attrs & GraphAttributes::nodeStyle && !GraphIO::setColorValue(text.as_int(), [&](uint8_t val) { GA.fillColor(v).red(val); })) { return false; } break; case graphml::a_g: if(attrs & GraphAttributes::nodeStyle && !GraphIO::setColorValue(text.as_int(), [&](uint8_t val) { GA.fillColor(v).green(val); })) { return false; } break; case graphml::a_b: if(attrs & GraphAttributes::nodeStyle && !GraphIO::setColorValue(text.as_int(), [&](uint8_t val) { GA.fillColor(v).blue(val); })) { return false; } break; case graphml::a_nodeFill: if(attrs & GraphAttributes::nodeStyle) { GA.fillColor(v) = text.get(); } break; case graphml::a_nodeStroke: if(attrs & GraphAttributes::nodeStyle) { GA.strokeColor(v) = text.get(); } break; case graphml::a_nodeType: if(attrs & GraphAttributes::nodeType) { GA.type(v) = graphml::toNodeType(text.get()); } break; case graphml::a_template: if(attrs & GraphAttributes::nodeTemplate) { GA.templateNode(v) = text.get(); } break; case graphml::a_nodeWeight: if(attrs & GraphAttributes::nodeWeight) { GA.weight(v) = text.as_int(); } break; default: GraphIO::logger.lout(Logger::LL_MINOR) << "Unknown node attribute: \"" << keyId.value() << "\"." << endl; } return true; }
static inline void writeAttributes( std::ostream &out, int depth, const GraphAttributes &GA, node v) { const long attrs = GA.attributes(); if(attrs & GraphAttributes::nodeGraphics) { const double z = (attrs & GraphAttributes::threeD) ? GA.z(v) : 0.0; GraphIO::indent(out, depth) << "<viz:position " << "x=\"" << GA.x(v) << "\" " << "y=\"" << GA.y(v) << "\" " << "z=\"" << z << "\" " << "/>\n"; // TODO: size is a scale here, so we have to know average size first. // const double size = std::max(GA.width(v), GA.height(v)); // GraphIO::indent(out, depth) << "<viz:size " // << "value=\"" << size << "\" " // << "/>\n"; const Shape shape = GA.shape(v); GraphIO::indent(out, depth) << "<viz:shape " << "value=\"" << toString(shape) << "\" " << "/>\n"; } if(attrs & GraphAttributes::nodeStyle) { const Color &color = GA.fillColor(v); const int red = color.red(); const int green = color.green(); const int blue = color.blue(); const int alpha = color.alpha(); GraphIO::indent(out, depth) << "<viz:color " << "red=\"" << red << "\" " << "green=\"" << green << "\" " << "blue=\"" << blue << "\" " << "alpha=\"" << alpha << "\" " << "/>\n"; } /* * Node type, template and weight are not supported by VIZ module. So, they * need to be written using <attvalues> tag (for estetic reasons, we write * them only if either of them is present). For convenience reasons, we use * the same names and values as in GraphML format. */ if(!(attrs & (GraphAttributes::nodeType | GraphAttributes::nodeTemplate | GraphAttributes::nodeWeight))) { return; } GraphIO::indent(out, depth) << "<attvalues>\n"; if(attrs & GraphAttributes::nodeType) { writeAttValue( out, depth + 1, graphml::a_nodeType, graphml::toString(GA.type(v))); } if(attrs & GraphAttributes::nodeTemplate) { writeAttValue(out, depth + 1, graphml::a_template, GA.templateNode(v)); } if(attrs & GraphAttributes::nodeWeight) { writeAttValue(out, depth + 1, graphml::a_nodeWeight, GA.weight(v)); } GraphIO::indent(out, depth) << "</attvalues>\n"; }
bool GmlParser::read(Graph &G, GraphAttributes &AG) { OGDF_ASSERT(&G == &(AG.constGraph())) G.clear(); int minId = m_mapToNode.low(); int maxId = m_mapToNode.high(); int notDefined = minId-1; //indicates not defined id key HashArray<string,Shape> strToShape(shRect); strToShape["rectangle"] = shRect; strToShape["rect"] = shRect; strToShape["roundedRect"] = shRoundedRect; strToShape["oval"] = shEllipse; strToShape["ellipse"] = shEllipse; strToShape["triangle"] = shTriangle; strToShape["pentagon"] = shPentagon; strToShape["hexagon"] = shHexagon; strToShape["octagon"] = shOctagon; strToShape["rhomb"] = shRhomb; strToShape["trapeze"] = shTrapeze; strToShape["parallelogram"] = shParallelogram; strToShape["invTriangle"] = shInvTriangle; strToShape["invTrapeze"] = shInvTrapeze; strToShape["invParallelogram"] = shInvParallelogram; strToShape["image"] = shImage; DPolyline bends; GmlObject *son = m_graphObject->m_pFirstSon; for(; son; son = son->m_pBrother) { switch(id(son)) { case nodePredefKey: { if (son->m_valueType != gmlListBegin) break; // set attributes to default values int vId = notDefined; double x = 0, y = 0, w = 0, h = 0; string label; string templ; string fill; // the fill color attribute string line; // the line color attribute string shape; //the shape type float lineWidth = 1.0f; //node line width int pattern = 1; //node brush pattern int stipple = 1; //line style pattern int weight = 0; // node weight // read all relevant attributes GmlObject *nodeSon = son->m_pFirstSon; for(; nodeSon; nodeSon = nodeSon->m_pBrother) { switch(id(nodeSon)) { case idPredefKey: if(nodeSon->m_valueType != gmlIntValue) break; vId = nodeSon->m_intValue; break; case graphicsPredefKey: { if (nodeSon->m_valueType != gmlListBegin) break; GmlObject *graphicsObject = nodeSon->m_pFirstSon; for(; graphicsObject; graphicsObject = graphicsObject->m_pBrother) { switch(id(graphicsObject)) { case xPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; x = graphicsObject->m_doubleValue; break; case yPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; y = graphicsObject->m_doubleValue; break; case wPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; w = graphicsObject->m_doubleValue; break; case hPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; h = graphicsObject->m_doubleValue; break; case fillPredefKey: if(graphicsObject->m_valueType != gmlStringValue) break; fill = graphicsObject->m_stringValue; break; case linePredefKey: if(graphicsObject->m_valueType != gmlStringValue) break; line = graphicsObject->m_stringValue; break; case lineWidthPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; lineWidth = (float)graphicsObject->m_doubleValue; break; case typePredefKey: if(graphicsObject->m_valueType != gmlStringValue) break; shape = graphicsObject->m_stringValue; break; case patternPredefKey: //fill style if(graphicsObject->m_valueType != gmlIntValue) break; pattern = graphicsObject->m_intValue; case stipplePredefKey: //line style if(graphicsObject->m_valueType != gmlIntValue) break; stipple = graphicsObject->m_intValue; } } break; } case templatePredefKey: if (nodeSon->m_valueType != gmlStringValue) break; templ = nodeSon->m_stringValue; break; case labelPredefKey: if (nodeSon->m_valueType != gmlStringValue) break; label = nodeSon->m_stringValue; break; case edgeWeightPredefKey: //sic! if (nodeSon->m_valueType != gmlIntValue) break; weight = nodeSon->m_intValue; break; } } // check if everything required is defined correctly if (vId == notDefined) { setError("node id not defined"); return false; } // create new node if necessary and assign attributes if (m_mapToNode[vId] == nullptr) m_mapToNode[vId] = G.newNode(); node v = m_mapToNode[vId]; if (AG.attributes() & GraphAttributes::nodeGraphics) { AG.x(v) = x; AG.y(v) = y; AG.width (v) = w; AG.height(v) = h; AG.shape(v) = strToShape[shape]; } if (AG.attributes() & GraphAttributes::nodeLabel) AG.label(m_mapToNode[vId]) = label; if (AG.attributes() & GraphAttributes::nodeTemplate) AG.templateNode(m_mapToNode[vId]) = templ; if (AG.attributes() & GraphAttributes::nodeId) AG.idNode(m_mapToNode[vId]) = vId; if (AG.attributes() & GraphAttributes::nodeWeight) AG.weight(m_mapToNode[vId]) = weight; if (AG.attributes() & GraphAttributes::nodeStyle) { AG.fillColor(m_mapToNode[vId]) = fill; AG.strokeColor(m_mapToNode[vId]) = line; AG.setFillPattern(m_mapToNode[vId], intToFillPattern(pattern)); AG.setStrokeType(m_mapToNode[vId], intToStrokeType(stipple)); AG.strokeWidth(m_mapToNode[vId]) = lineWidth; } }//node //Todo: line style set stipple value break; case edgePredefKey: { string arrow; // the arrow type attribute string fill; //the color fill attribute int stipple = 1; //the line style float lineWidth = 1.0f; double edgeWeight = 1.0; int subGraph = 0; //edgeSubGraphs attribute string label; // label attribute if (son->m_valueType != gmlListBegin) break; // set attributes to default values int sourceId = notDefined, targetId = notDefined; Graph::EdgeType umlType = Graph::association; // read all relevant attributes GmlObject *edgeSon = son->m_pFirstSon; for(; edgeSon; edgeSon = edgeSon->m_pBrother) { switch(id(edgeSon)) { case sourcePredefKey: if (edgeSon->m_valueType != gmlIntValue) break; sourceId = edgeSon->m_intValue; break; case targetPredefKey: if (edgeSon->m_valueType != gmlIntValue) break; targetId = edgeSon->m_intValue; break; case subGraphPredefKey: if (edgeSon->m_valueType != gmlIntValue) break; subGraph = edgeSon->m_intValue; break; case labelPredefKey: if (edgeSon->m_valueType != gmlStringValue) break; label = edgeSon->m_stringValue; break; case graphicsPredefKey: { if (edgeSon->m_valueType != gmlListBegin) break; GmlObject *graphicsObject = edgeSon->m_pFirstSon; for(; graphicsObject; graphicsObject = graphicsObject->m_pBrother) { if(id(graphicsObject) == LinePredefKey && graphicsObject->m_valueType == gmlListBegin) { readLineAttribute(graphicsObject->m_pFirstSon,bends); } if(id(graphicsObject) == arrowPredefKey && graphicsObject->m_valueType == gmlStringValue) arrow = graphicsObject->m_stringValue; if(id(graphicsObject) == fillPredefKey && graphicsObject->m_valueType == gmlStringValue) fill = graphicsObject->m_stringValue; if (id(graphicsObject) == stipplePredefKey && //line style graphicsObject->m_valueType == gmlIntValue) stipple = graphicsObject->m_intValue; if (id(graphicsObject) == lineWidthPredefKey && //line width graphicsObject->m_valueType == gmlDoubleValue) lineWidth = (float)graphicsObject->m_doubleValue; if (id(graphicsObject) == edgeWeightPredefKey && graphicsObject->m_valueType == gmlDoubleValue) edgeWeight = graphicsObject->m_doubleValue; }//for graphics } case generalizationPredefKey: if (edgeSon->m_valueType != gmlIntValue) break; umlType = (edgeSon->m_intValue == 0) ? Graph::association : Graph::generalization; break; } } // check if everything required is defined correctly if (sourceId == notDefined || targetId == notDefined) { setError("source or target id not defined"); return false; } else if (sourceId < minId || maxId < sourceId || targetId < minId || maxId < targetId) { setError("source or target id out of range"); return false; } // create adjacent nodes if necessary and new edge if (m_mapToNode[sourceId] == nullptr) m_mapToNode[sourceId] = G.newNode(); if (m_mapToNode[targetId] == nullptr) m_mapToNode[targetId] = G.newNode(); edge e = G.newEdge(m_mapToNode[sourceId],m_mapToNode[targetId]); if (AG.attributes() & GraphAttributes::edgeGraphics) AG.bends(e).conc(bends); if (AG.attributes() & GraphAttributes::edgeType) AG.type(e) = umlType; if(AG.attributes() & GraphAttributes::edgeSubGraphs) AG.subGraphBits(e) = subGraph; if (AG.attributes() & GraphAttributes::edgeLabel) AG.label(e) = label; if (AG.attributes() & GraphAttributes::edgeArrow) { if (arrow == "none") AG.arrowType(e) = eaNone; else if (arrow == "last") AG.arrowType(e) = eaLast; else if (arrow == "first") AG.arrowType(e) = eaFirst; else if (arrow == "both") AG.arrowType(e) = eaBoth; else AG.arrowType(e) = eaUndefined; } if (AG.attributes() & GraphAttributes::edgeStyle) { AG.strokeColor(e) = fill; AG.setStrokeType(e, intToStrokeType(stipple)); AG.strokeWidth(e) = lineWidth; } if (AG.attributes() & GraphAttributes::edgeDoubleWeight) AG.doubleWeight(e) = edgeWeight; break; } case directedPredefKey: { if(son->m_valueType != gmlIntValue) break; AG.setDirected(son->m_intValue > 0); break; } } } return true; }//read
bool GmlParser::read(Graph &G, GraphAttributes &AG) { OGDF_ASSERT(&G == &(AG.constGraph())) G.clear(); int minId = m_mapToNode.low(); int maxId = m_mapToNode.high(); int notDefined = minId-1; //indicates not defined id key DPolyline bends; GmlObject *son = m_graphObject->m_pFirstSon; for(; son; son = son->m_pBrother) { switch(id(son)) { case nodePredefKey: { if (son->m_valueType != gmlListBegin) break; // set attributes to default values int vId = notDefined; double x = 0, y = 0, w = 0, h = 0; String label; String templ; String fill; // the fill color attribute String line; // the line color attribute String shape; //the shape type double lineWidth = 1.0; //node line width int pattern = 1; //node brush pattern int stipple = 1; //line style pattern // read all relevant attributes GmlObject *nodeSon = son->m_pFirstSon; for(; nodeSon; nodeSon = nodeSon->m_pBrother) { switch(id(nodeSon)) { case idPredefKey: if(nodeSon->m_valueType != gmlIntValue) break; vId = nodeSon->m_intValue; break; case graphicsPredefKey: { if (nodeSon->m_valueType != gmlListBegin) break; GmlObject *graphicsObject = nodeSon->m_pFirstSon; for(; graphicsObject; graphicsObject = graphicsObject->m_pBrother) { switch(id(graphicsObject)) { case xPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; x = graphicsObject->m_doubleValue; break; case yPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; y = graphicsObject->m_doubleValue; break; case wPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; w = graphicsObject->m_doubleValue; break; case hPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; h = graphicsObject->m_doubleValue; break; case fillPredefKey: if(graphicsObject->m_valueType != gmlStringValue) break; fill = graphicsObject->m_stringValue; break; case linePredefKey: if(graphicsObject->m_valueType != gmlStringValue) break; line = graphicsObject->m_stringValue; break; case lineWidthPredefKey: if(graphicsObject->m_valueType != gmlDoubleValue) break; lineWidth = graphicsObject->m_doubleValue; break; case typePredefKey: if(graphicsObject->m_valueType != gmlStringValue) break; shape = graphicsObject->m_stringValue; break; case patternPredefKey: //fill style if(graphicsObject->m_valueType != gmlIntValue) break; pattern = graphicsObject->m_intValue; case stipplePredefKey: //line style if(graphicsObject->m_valueType != gmlIntValue) break; stipple = graphicsObject->m_intValue; } } break; } case templatePredefKey: if (nodeSon->m_valueType != gmlStringValue) break; templ = nodeSon->m_stringValue; break; case labelPredefKey: if (nodeSon->m_valueType != gmlStringValue) break; label = nodeSon->m_stringValue; break; } } // check if everything required is defined correctly if (vId == notDefined) { setError("node id not defined"); return false; } // create new node if necessary and assign attributes if (m_mapToNode[vId] == 0) m_mapToNode[vId] = G.newNode(); if (AG.attributes() & GraphAttributes::nodeGraphics) { AG.x(m_mapToNode[vId]) = x; AG.y(m_mapToNode[vId]) = y; AG.width (m_mapToNode[vId]) = w; AG.height(m_mapToNode[vId]) = h; if (shape == "oval") AG.shapeNode(m_mapToNode[vId]) = GraphAttributes::oval; else AG.shapeNode(m_mapToNode[vId]) = GraphAttributes::rectangle; } if ( (AG.attributes() & GraphAttributes::nodeColor) && (AG.attributes() & GraphAttributes::nodeGraphics) ) { AG.colorNode(m_mapToNode[vId]) = fill; AG.nodeLine(m_mapToNode[vId]) = line; } if (AG.attributes() & GraphAttributes::nodeLabel) AG.labelNode(m_mapToNode[vId]) = label; if (AG.attributes() & GraphAttributes::nodeTemplate) AG.templateNode(m_mapToNode[vId]) = templ; if (AG.attributes() & GraphAttributes::nodeId) AG.idNode(m_mapToNode[vId]) = vId; if (AG.attributes() & GraphAttributes::nodeStyle) { AG.nodePattern(m_mapToNode[vId]) = GraphAttributes::intToPattern(pattern); AG.styleNode(m_mapToNode[vId]) = GraphAttributes::intToStyle(stipple); AG.lineWidthNode(m_mapToNode[vId]) = lineWidth; } }//node //Todo: line style set stipple value break; case edgePredefKey: { String arrow; // the arrow type attribute String fill; //the color fill attribute int stipple = 1; //the line style double lineWidth = 1.0; double edgeWeight = 1.0; int subGraph = 0; //edgeSubGraph attribute String label; // label attribute if (son->m_valueType != gmlListBegin) break; // set attributes to default values int sourceId = notDefined, targetId = notDefined; Graph::EdgeType umlType = Graph::association; // read all relevant attributes GmlObject *edgeSon = son->m_pFirstSon; for(; edgeSon; edgeSon = edgeSon->m_pBrother) { switch(id(edgeSon)) { case sourcePredefKey: if (edgeSon->m_valueType != gmlIntValue) break; sourceId = edgeSon->m_intValue; break; case targetPredefKey: if (edgeSon->m_valueType != gmlIntValue) break; targetId = edgeSon->m_intValue; break; case subGraphPredefKey: if (edgeSon->m_valueType != gmlIntValue) break; subGraph = edgeSon->m_intValue; break; case labelPredefKey: if (edgeSon->m_valueType != gmlStringValue) break; label = edgeSon->m_stringValue; break; case graphicsPredefKey: { if (edgeSon->m_valueType != gmlListBegin) break; GmlObject *graphicsObject = edgeSon->m_pFirstSon; for(; graphicsObject; graphicsObject = graphicsObject->m_pBrother) { if(id(graphicsObject) == LinePredefKey && graphicsObject->m_valueType == gmlListBegin) { readLineAttribute(graphicsObject->m_pFirstSon,bends); } if(id(graphicsObject) == arrowPredefKey && graphicsObject->m_valueType == gmlStringValue) arrow = graphicsObject->m_stringValue; if(id(graphicsObject) == fillPredefKey && graphicsObject->m_valueType == gmlStringValue) fill = graphicsObject->m_stringValue; if (id(graphicsObject) == stipplePredefKey && //line style graphicsObject->m_valueType == gmlIntValue) stipple = graphicsObject->m_intValue; if (id(graphicsObject) == lineWidthPredefKey && //line width graphicsObject->m_valueType == gmlDoubleValue) lineWidth = graphicsObject->m_doubleValue; if (id(graphicsObject) == edgeWeightPredefKey && graphicsObject->m_valueType == gmlDoubleValue) edgeWeight = graphicsObject->m_doubleValue; }//for graphics } case generalizationPredefKey: if (edgeSon->m_valueType != gmlIntValue) break; umlType = (edgeSon->m_intValue == 0) ? Graph::association : Graph::generalization; break; } } // check if everything required is defined correctly if (sourceId == notDefined || targetId == notDefined) { setError("source or target id not defined"); return false; } else if (sourceId < minId || maxId < sourceId || targetId < minId || maxId < targetId) { setError("source or target id out of range"); return false; } // create adjacent nodes if necessary and new edge if (m_mapToNode[sourceId] == 0) m_mapToNode[sourceId] = G.newNode(); if (m_mapToNode[targetId] == 0) m_mapToNode[targetId] = G.newNode(); edge e = G.newEdge(m_mapToNode[sourceId],m_mapToNode[targetId]); if (AG.attributes() & GraphAttributes::edgeGraphics) AG.bends(e).conc(bends); if (AG.attributes() & GraphAttributes::edgeType) AG.type(e) = umlType; if(AG.attributes() & GraphAttributes::edgeSubGraph) AG.subGraphBits(e) = subGraph; if (AG.attributes() & GraphAttributes::edgeLabel) AG.labelEdge(e) = label; if (AG.attributes() & GraphAttributes::edgeArrow) if (arrow == "none") AG.arrowEdge(e) = GraphAttributes::none; else if (arrow == "last") AG.arrowEdge(e) = GraphAttributes::last; else if (arrow == "first") AG.arrowEdge(e) = GraphAttributes::first; else if (arrow == "both") AG.arrowEdge(e) = GraphAttributes::both; else AG.arrowEdge(e) = GraphAttributes::undefined; if (AG.attributes() & GraphAttributes::edgeColor) AG.colorEdge(e) = fill; if (AG.attributes() & GraphAttributes::edgeStyle) { AG.styleEdge(e) = AG.intToStyle(stipple); AG.edgeWidth(e) = lineWidth; } if (AG.attributes() & GraphAttributes::edgeDoubleWeight) AG.doubleWeight(e) = edgeWeight; break; } case directedPredefKey: { if(son->m_valueType != gmlIntValue) break; AG.directed(son->m_intValue > 0); break; } } } return true; }//read