#include #include #include "strokemodifier.h" #include "util.h" void StrokeModifier::enableIntermediateAddition() { m_intermediateAdditionEnabled = true; } size_t StrokeModifier::addNode(const QVector3D &position, float radius, const std::vector &cutTemplate, float cutRotation) { size_t nodeIndex = m_nodes.size(); Node node; node.isOriginal = true; node.position = position; node.radius = radius; node.cutTemplate = cutTemplate; node.cutRotation = cutRotation; node.originNodeIndex = nodeIndex; m_nodes.push_back(node); return nodeIndex; } size_t StrokeModifier::addEdge(size_t firstNodeIndex, size_t secondNodeIndex) { size_t edgeIndex = m_edges.size(); Edge edge; edge.firstNodeIndex = firstNodeIndex; edge.secondNodeIndex = secondNodeIndex; m_edges.push_back(edge); return edgeIndex; } void StrokeModifier::createIntermediateNode(const Node &firstNode, const Node &secondNode, float factor, Node *resultNode) { float firstFactor = 1.0 - factor; resultNode->position = firstNode.position * firstFactor + secondNode.position * factor; resultNode->radius = firstNode.radius * firstFactor + secondNode.radius * factor; if (factor <= 0.5) { resultNode->originNodeIndex = firstNode.originNodeIndex; resultNode->nearOriginNodeIndex = firstNode.originNodeIndex; resultNode->farOriginNodeIndex = secondNode.originNodeIndex; resultNode->cutRotation = firstNode.cutRotation; resultNode->cutTemplate = firstNode.cutTemplate; } else { resultNode->originNodeIndex = secondNode.originNodeIndex; resultNode->nearOriginNodeIndex = secondNode.originNodeIndex; resultNode->farOriginNodeIndex = firstNode.originNodeIndex; resultNode->cutRotation = secondNode.cutRotation; resultNode->cutTemplate = secondNode.cutTemplate; } } void StrokeModifier::subdivide() { for (auto &node: m_nodes) { subdivideFace2D(&node.cutTemplate); } } float StrokeModifier::averageCutTemplateEdgeLength(const std::vector &cutTemplate) { if (cutTemplate.empty()) return 0; float sum = 0; for (size_t i = 0; i < cutTemplate.size(); ++i) { size_t j = (i + 1) % cutTemplate.size(); sum += (cutTemplate[i] - cutTemplate[j]).length(); } return sum / cutTemplate.size(); } void StrokeModifier::roundEnd() { std::map> neighbors; for (const auto &edge: m_edges) { neighbors[edge.firstNodeIndex].push_back(edge.secondNodeIndex); neighbors[edge.secondNodeIndex].push_back(edge.firstNodeIndex); } for (const auto &it: neighbors) { if (1 == it.second.size()) { const Node ¤tNode = m_nodes[it.first]; const Node &neighborNode = m_nodes[it.second[0]]; Node endNode; endNode.radius = currentNode.radius * 0.5; endNode.position = currentNode.position + (currentNode.position - neighborNode.position).normalized() * endNode.radius; endNode.cutTemplate = currentNode.cutTemplate; endNode.cutRotation = currentNode.cutRotation; endNode.originNodeIndex = currentNode.originNodeIndex; size_t endNodeIndex = m_nodes.size(); m_nodes.push_back(endNode); addEdge(endNode.originNodeIndex, endNodeIndex); } } } void StrokeModifier::createIntermediateCutTemplateEdges(std::vector &cutTemplate, float averageCutTemplateLength) { std::vector newCutTemplate; auto pointCount = cutTemplate.size(); float targetLength = averageCutTemplateLength * 1.2; for (size_t index = 0; index < pointCount; ++index) { size_t nextIndex = (index + 1) % pointCount; newCutTemplate.push_back(cutTemplate[index]); float oldEdgeLength = (cutTemplate[index] - cutTemplate[nextIndex]).length(); if (targetLength >= oldEdgeLength) continue; size_t newInsertNum = oldEdgeLength / targetLength; if (newInsertNum < 1) newInsertNum = 1; if (newInsertNum > 100) continue; float stepFactor = 1.0 / (newInsertNum + 1); float factor = stepFactor; for (size_t i = 0; i < newInsertNum && factor < 1.0; factor += stepFactor, ++i) { float firstFactor = 1.0 - factor; newCutTemplate.push_back(cutTemplate[index] * firstFactor + cutTemplate[nextIndex] * factor); } } cutTemplate = newCutTemplate; } void StrokeModifier::finalize() { if (!m_intermediateAdditionEnabled) return; for (auto &node: m_nodes) { node.averageCutTemplateLength = averageCutTemplateEdgeLength(node.cutTemplate); createIntermediateCutTemplateEdges(node.cutTemplate, node.averageCutTemplateLength); } auto oldEdges = m_edges; m_edges.clear(); for (const auto &edge: oldEdges) { const Node &firstNode = m_nodes[edge.firstNodeIndex]; const Node &secondNode = m_nodes[edge.secondNodeIndex]; //float edgeLengthThreshold = (firstNode.radius + secondNode.radius) * 0.75; auto firstAverageCutTemplateEdgeLength = firstNode.averageCutTemplateLength * firstNode.radius; auto secondAverageCutTemplateEdgeLength = secondNode.averageCutTemplateLength * secondNode.radius; float targetEdgeLength = (firstAverageCutTemplateEdgeLength + secondAverageCutTemplateEdgeLength) * 0.5; //if (targetEdgeLength < edgeLengthThreshold) // targetEdgeLength = edgeLengthThreshold; float currentEdgeLength = (firstNode.position - secondNode.position).length(); if (targetEdgeLength >= currentEdgeLength) { addEdge(edge.firstNodeIndex, edge.secondNodeIndex); continue; } size_t newInsertNum = currentEdgeLength / targetEdgeLength; if (newInsertNum < 1) newInsertNum = 1; if (newInsertNum > 100) continue; float stepFactor = 1.0 / (newInsertNum + 1); std::vector nodeIndices; nodeIndices.push_back(edge.firstNodeIndex); float factor = stepFactor; for (size_t i = 0; i < newInsertNum && factor < 1.0; factor += stepFactor, ++i) { Node intermediateNode; const Node &firstNode = m_nodes[edge.firstNodeIndex]; const Node &secondNode = m_nodes[edge.secondNodeIndex]; createIntermediateNode(firstNode, secondNode, factor, &intermediateNode); size_t intermedidateNodeIndex = m_nodes.size(); nodeIndices.push_back(intermedidateNodeIndex); m_nodes.push_back(intermediateNode); } nodeIndices.push_back(edge.secondNodeIndex); for (size_t i = 1; i < nodeIndices.size(); ++i) { addEdge(nodeIndices[i - 1], nodeIndices[i]); } } } const std::vector &StrokeModifier::nodes() { return m_nodes; } const std::vector &StrokeModifier::edges() { return m_edges; }