#include "trianglepatterngeometry.hpp" #include "trianglepattterntopology.hpp" #include #include #include #include #include #include #include /* include the support for half edges */ #include size_t PatternGeometry::computeTiledValence( const size_t &nodeIndex, const std::vector &numberOfNodesPerSlot) const { std::vector connectedEdges; vcg::edge::VEStarVE(&vert[nodeIndex], connectedEdges); const size_t nodeValence = connectedEdges.size(); assert(nodeToSlotMap.count(nodeIndex) != 0); const size_t nodeSlotIndex = nodeToSlotMap.at(nodeIndex); if (nodeSlotIndex == 0) { return nodeValence * fanSize; } else if (nodeSlotIndex == 1 || nodeSlotIndex == 2) { size_t correspondingNodeIndex; if (nodeSlotIndex == 1) { correspondingNodeIndex = nodeIndex + 1; } else { correspondingNodeIndex = nodeIndex - 1; } std::vector connectedEdgesCorrespondingNode; vcg::edge::VEStarVE(&vert[correspondingNodeIndex], connectedEdgesCorrespondingNode); size_t correspondingNodeValence = connectedEdgesCorrespondingNode.size(); return fanSize / 2 * nodeValence + fanSize / 2 * correspondingNodeValence; } else if (nodeSlotIndex == 3 || nodeSlotIndex == 5) { size_t correspondingNodeIndex; size_t numberOfNodesBefore; size_t numberOfNodesAfter; if (nodeSlotIndex == 3) { numberOfNodesBefore = nodeIndex - std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 3, 0); correspondingNodeIndex = std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 6, 0) - 1 - numberOfNodesBefore; } else { numberOfNodesAfter = std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 6, 0) - 1 - nodeIndex; correspondingNodeIndex = numberOfNodesAfter + std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 3, 0); } assert(correspondingNodeIndex < vn); std::vector connectedEdgesCorrespondingNode; vcg::edge::VEStarVE(&vert[correspondingNodeIndex], connectedEdgesCorrespondingNode); size_t correspondingNodeValence = connectedEdgesCorrespondingNode.size(); return nodeValence + correspondingNodeValence; } else if (nodeSlotIndex == 4) { return 2 * nodeValence; } else if (nodeSlotIndex == 6) { return nodeValence; } else { std::cerr << "Error in slot index computation" << std::endl; } assert(false); return 0; } size_t PatternGeometry::getFanSize() const { return fanSize; } double PatternGeometry::getTriangleEdgeSize() const { return triangleEdgeSize; } PatternGeometry::PatternGeometry() {} std::vector PatternGeometry::getVertices() const { std::vector verts(VN()); for (size_t vi = 0; vi < VN(); vi++) { verts[vi] = vert[vi].cP(); } return verts; } PatternGeometry PatternGeometry::createTile(PatternGeometry &pattern) { const size_t fanSize = PatternGeometry().getFanSize(); PatternGeometry fan(createFan(pattern)); PatternGeometry tile(fan); if (fanSize % 2 == 1) { vcg::Matrix44d R; auto rotationAxis = vcg::Point3d(0, 0, 1); R.SetRotateDeg(180, rotationAxis); vcg::tri::UpdatePosition::Matrix(fan, R); } vcg::Matrix44d T; const double centerAngle = 2 * M_PI / fanSize; const double triangleHeight = std::sin((M_PI - centerAngle) / 2) * PatternGeometry().triangleEdgeSize; T.SetTranslate(0, -2 * triangleHeight, 0); vcg::tri::UpdatePosition::Matrix(fan, T); PatternGeometry fanOfFan = createFan(fan); vcg::tri::Append::Mesh(tile, fanOfFan); vcg::tri::Clean::MergeCloseVertex(tile, 0.0000005); vcg::tri::Allocator::CompactEveryVector(tile); vcg::tri::UpdateTopology::VertexEdge(tile); vcg::tri::UpdateTopology::EdgeEdge(tile); for (size_t vi = 0; vi < pattern.vn; vi++) { tile.vert[vi].C() = vcg::Color4b::Blue; } tile.updateEigenEdgeAndVertices(); return tile; } PatternGeometry PatternGeometry::createFan(PatternGeometry &pattern) { const size_t fanSize = PatternGeometry().getFanSize(); PatternGeometry fan(pattern); PatternGeometry rotatedPattern(pattern); for (int rotationCounter = 1; rotationCounter < fanSize; rotationCounter++) { vcg::Matrix44d R; auto rotationAxis = vcg::Point3d(0, 0, 1); R.SetRotateDeg(360 / fanSize, rotationAxis); vcg::tri::UpdatePosition::Matrix(rotatedPattern, R); vcg::tri::Append::Mesh(fan, rotatedPattern); } return fan; } PatternGeometry::PatternGeometry(PatternGeometry &other) { vcg::tri::Append::MeshCopy(*this, other); this->vertices = other.getVertices(); baseTriangle = other.getBaseTriangle(); baseTriangleHeight = computeBaseTriangleHeight(); vcg::tri::UpdateTopology::VertexEdge(*this); vcg::tri::UpdateTopology::EdgeEdge(*this); } bool PatternGeometry::load(const string &plyFilename) { if (!VCGEdgeMesh::load(plyFilename)) { return false; } vcg::tri::UpdateTopology::VertexEdge(*this); baseTriangleHeight = computeBaseTriangleHeight(); baseTriangle = computeBaseTriangle(); updateEigenEdgeAndVertices(); return true; } void PatternGeometry::add(const std::vector &vertices) { this->vertices = vertices; std::for_each(vertices.begin(), vertices.end(), [&](const vcg::Point3d &p) { vcg::tri::Allocator::AddVertex(*this, p); }); vcg::tri::UpdateTopology::VertexEdge(*this); vcg::tri::UpdateTopology::EdgeEdge(*this); updateEigenEdgeAndVertices(); } void PatternGeometry::add(const std::vector &edges) { std::for_each(edges.begin(), edges.end(), [&](const vcg::Point2i &e) { vcg::tri::Allocator::AddEdge(*this, e[0], e[1]); }); vcg::tri::UpdateTopology::VertexEdge(*this); vcg::tri::UpdateTopology::EdgeEdge(*this); updateEigenEdgeAndVertices(); } void PatternGeometry::add(const std::vector &vertices, const std::vector &edges) { add(vertices); add(edges); updateEigenEdgeAndVertices(); } void PatternGeometry::add(const std::vector &numberOfNodesPerSlot, const std::vector &edges) { assert(numberOfNodesPerSlot.size() == 7); auto vertices = constructVertexVector(numberOfNodesPerSlot, fanSize, triangleEdgeSize); add(vertices, edges); vcg::tri::UpdateTopology::VertexEdge(*this); vcg::tri::UpdateTopology::EdgeEdge(*this); updateEigenEdgeAndVertices(); } std::vector PatternGeometry::constructVertexVector( const std::vector &numberOfNodesPerSlot, const size_t &fanSize, const double &triangleEdgeSize) { std::vector vertices; const double centerAngle = 2 * M_PI / fanSize; const double triangleHeight = std::sin((M_PI - centerAngle) / 2) * triangleEdgeSize; const double baseEdgeSize = 2 * triangleEdgeSize * std::cos((M_PI - centerAngle) / 2); const vcg::Point3d triangleV0 = vcg::Point3d(0, 0, 0); const vcg::Point3d triangleV1 = vcg::Point3d(-baseEdgeSize / 2, -triangleHeight, 0); const vcg::Point3d triangleV2 = vcg::Point3d(baseEdgeSize / 2, -triangleHeight, 0); // Nodes if (numberOfNodesPerSlot[0] == 1) { // vertices[0] = triangleV0; vertices.push_back(triangleV0); } if (numberOfNodesPerSlot[1] == 1) { // vertices[1] = triangleV1; vertices.push_back(triangleV1); } if (numberOfNodesPerSlot[2] == 1) { // vertices[2] = triangleV2; vertices.push_back(triangleV2); } // Edges if (numberOfNodesPerSlot[3] != 0) { const double offset0 = 1.0 / (numberOfNodesPerSlot[3] + 1); const vcg::Point3d edgeVector0(triangleV1 - triangleV0); for (size_t vertexIndex = 0; vertexIndex < numberOfNodesPerSlot[3]; vertexIndex++) { // vertices[std::accumulate(numberOfNodesPerSlot.begin(), // numberOfNodesPerSlot.begin() + 2, 0) + // vertexIndex] = vertices.push_back(triangleV0 + edgeVector0.operator*((vertexIndex + 1) * offset0)); } } if (numberOfNodesPerSlot[4] == 1) { vertices.push_back(vcg::Point3d(0, -triangleHeight, 0)); } else if (numberOfNodesPerSlot[4] != 0) { const double offset1 = 1.0 / (numberOfNodesPerSlot[4] + 1); const vcg::Point3d edgeVector1(triangleV2 - triangleV1); for (size_t vertexIndex = 0; vertexIndex < numberOfNodesPerSlot[4]; vertexIndex++) { // vertices[std::accumulate(numberOfNodesPerSlot.begin(), // numberOfNodesPerSlot.begin() + 3, 0) + // vertexIndex] = vertices.push_back(triangleV1 + edgeVector1.operator*((vertexIndex + 1) * offset1)); } } if (numberOfNodesPerSlot[5] != 0) { const double offset2 = 1.0 / (numberOfNodesPerSlot[5] + 1); const vcg::Point3d edgeVector2(triangleV0 - triangleV2); for (size_t vertexIndex = 0; vertexIndex < numberOfNodesPerSlot[5]; vertexIndex++) { // vertices[std::accumulate(numberOfNodesPerSlot.begin(), // numberOfNodesPerSlot.begin() + 4, 0) + // vertexIndex] = vertices.push_back(triangleV2 + edgeVector2.operator*((vertexIndex + 1) * offset2)); } } // Face if (numberOfNodesPerSlot[6] != 0) { const vcg::Point3d triangleCenter((triangleV0 + triangleV1 + triangleV2) / 3); const double radius = 0.1; const double offsetRad = 2 * M_PI / numberOfNodesPerSlot[6]; for (size_t vertexIndex = 0; vertexIndex < numberOfNodesPerSlot[6]; vertexIndex++) { const double pX = triangleCenter[0] + radius * std::cos(vertexIndex * offsetRad); const double pY = triangleCenter[1] + radius * std::sin(vertexIndex * offsetRad); /*vertices[std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 5, 0) + vertexIndex] =*/ vertices.push_back(vcg::Point3d(pX, pY, 0)); } } return vertices; } void PatternGeometry::constructNodeToTiledValenceMap( const std::vector &numberOfNodesPerSlot) { for (size_t nodeIndex = 0; nodeIndex < vn; nodeIndex++) { const size_t tiledValence = computeTiledValence(nodeIndex, numberOfNodesPerSlot); nodeTiledValence[nodeIndex] = tiledValence; } } std::vector PatternGeometry::getEdgeVectorsWithVertexAsOrigin( std::vector &edgePointers, const int &vi) { std::vector incidentElementsVectors(edgePointers.size()); for (int incidentElementsIndex = 0; incidentElementsIndex < edgePointers.size(); incidentElementsIndex++) { assert(vi == getIndex(edgePointers[incidentElementsIndex]->cV(0)) || vi == getIndex(edgePointers[incidentElementsIndex]->cV(1))); incidentElementsVectors[incidentElementsIndex] = vi == getIndex(edgePointers[incidentElementsIndex]->cV(0)) ? edgePointers[incidentElementsIndex]->cP(1) - edgePointers[incidentElementsIndex]->cP(0) : edgePointers[incidentElementsIndex]->cP(0) - edgePointers[incidentElementsIndex]->cP(1); } return incidentElementsVectors; } bool PatternGeometry::hasAngleSmallerThanThreshold(const std::vector &numberOfNodesPerSlot, const double &angleThreshold_degrees) { assert(numberOfNodesPerSlot.size() == 7); //Initialize helping structs if (nodeToSlotMap.empty()) { FlatPatternTopology::constructNodeToSlotMap(numberOfNodesPerSlot, nodeToSlotMap); } if (correspondingNode.empty()) { constructCorrespondingNodeMap(numberOfNodesPerSlot); } // const double theta0 = vcg::math::ToDeg(vcg::Point2d(1, 0).Angle()); // const double theta1 = vcg::math::ToDeg(vcg::Point2d(1, 1).Angle()); // const double theta2 = vcg::math::ToDeg(vcg::Point2d(0, 1).Angle()); // const double theta3 = vcg::math::ToDeg(vcg::Point2d(-1, 1).Angle()); // const double theta4 = vcg::math::ToDeg(vcg::Point2d(-1, 0).Angle()); // const double theta5 = vcg::math::ToDeg(vcg::Point2d(-1, -1).Angle() + 2 * M_PI); // const double theta6 = vcg::math::ToDeg(vcg::Point2d(0, -1).Angle() + 2 * M_PI); // const double theta7 = vcg::math::ToDeg(vcg::Point2d(1, -1).Angle() + 2 * M_PI); // std::set test{theta0, theta1, theta2, theta3, theta4, theta5, theta6, theta7}; bool hasAngleSmallerThan = false; //find tiled incident edges for each node using EdgeIndex = int; using ThetaWithXAxis = double; for (size_t vi = 0; vi < VN(); vi++) { std::vector incidentElementPointers; vcg::edge::VEStarVE(&vert[vi], incidentElementPointers); const size_t numberOfIncidentEdges = incidentElementPointers.size(); if (numberOfIncidentEdges == 0) { continue; } std::vector incidentEdgeVectors = getEdgeVectorsWithVertexAsOrigin(incidentElementPointers, vi); std::vector tiledIncidentVectors = incidentEdgeVectors; const size_t slotIndex = nodeToSlotMap[vi]; if (slotIndex == 2) { //NOTE:I assume that base triangle slots 1,2(bottom triangle nodes) are not used std::cerr << "Slot of bottom base triangle nodes detected.This case is not handled.Exiting.." << std::endl; std::terminate(); } else if (slotIndex == 3 || slotIndex == 5) { //NOTE: I don't need to check both triangle edges std::vector correspondingVertexIncidentElementPointers; vcg::edge::VEStarVE(&vert[correspondingNode[vi]], correspondingVertexIncidentElementPointers); std::vector correspondingVertexIncidentVectors = getEdgeVectorsWithVertexAsOrigin(correspondingVertexIncidentElementPointers, correspondingNode[vi]); // const CoordType &correspondingVertexPosition = vert[correspondingNode[vi]].cP(); vcg::Matrix33d R; if (slotIndex == 3) { R = vcg::RotationMatrix(vcg::Point3d(0, 0, 1), vcg::math::ToRad(-60.0)); } else { R = vcg::RotationMatrix(vcg::Point3d(0, 0, 1), vcg::math::ToRad(60.0)); } // const CoordType &correspondingVertexPosition_rotated = vert[vi].cP(); std::transform( correspondingVertexIncidentVectors.begin(), correspondingVertexIncidentVectors.end(), correspondingVertexIncidentVectors.begin(), [&](const VectorType &v) { // CoordType rotatedTarget = v * R; // v = rotatedTarget - correspondingVertexPosition_rotated; return R * v; }); tiledIncidentVectors.insert(tiledIncidentVectors.end(), correspondingVertexIncidentVectors.begin(), correspondingVertexIncidentVectors.end()); } else if (slotIndex == 4) { std::vector reversedIncidentElementVectors(incidentEdgeVectors.size()); std::transform(incidentEdgeVectors.begin(), incidentEdgeVectors.end(), reversedIncidentElementVectors.begin(), [&](const VectorType &v) { return -v; }); //NOTE: for checking the angles not all opposite incident element vectors are needed but rather the two "extreme" ones of slot 4 //here I simply add them all tiledIncidentVectors.insert(tiledIncidentVectors.end(), reversedIncidentElementVectors.begin(), reversedIncidentElementVectors.end()); } // std::vector> edgePoints; // for (int tiledVectorIndex = 0; tiledVectorIndex < tiledIncidentVectors.size(); // tiledVectorIndex++) { // edgePoints.push_back( // std::array{vert[vi].cP()[0], vert[vi].cP()[1], vert[vi].cP()[2]}); // edgePoints.push_back( // std::array{(vert[vi].cP() + tiledIncidentVectors[tiledVectorIndex])[0], // (vert[vi].cP() + tiledIncidentVectors[tiledVectorIndex])[1], // (vert[vi].cP() + tiledIncidentVectors[tiledVectorIndex])[2]}); // } // polyscope::registerCurveNetworkLine("temp", edgePoints); // polyscope::show(); if (tiledIncidentVectors.size() == 1) { continue; } std::vector thetaAnglesOfIncidentVectors(tiledIncidentVectors.size()); std::transform(tiledIncidentVectors.begin(), tiledIncidentVectors.end(), thetaAnglesOfIncidentVectors.begin(), [](const VectorType &v) { return vcg::Point2d(v[0], v[1]).Angle(); }); //sort them using theta angles std::sort(thetaAnglesOfIncidentVectors.begin(), thetaAnglesOfIncidentVectors.end()); //find nodes that contain incident edges with relative angles less than the threshold const double angleThreshold_rad = vcg::math::ToRad(angleThreshold_degrees); for (int thetaAngleIndex = 1; thetaAngleIndex < thetaAnglesOfIncidentVectors.size(); thetaAngleIndex++) { const double absAngleDifference = std::abs( thetaAnglesOfIncidentVectors[thetaAngleIndex] - thetaAnglesOfIncidentVectors[thetaAngleIndex - 1]); if (absAngleDifference < angleThreshold_rad /*&& absAngleDifference > vcg::math::ToRad(0.01)*/) { // std::cout << "Found angDiff:" << absAngleDifference << std::endl; // vert[vi].C() = vcg::Color4b::Magenta; // hasAngleSmallerThan = true; return true; } } const double firstLastPairAngleDiff = std::abs( thetaAnglesOfIncidentVectors[0] - thetaAnglesOfIncidentVectors[thetaAnglesOfIncidentVectors.size() - 1]); if (firstLastPairAngleDiff < angleThreshold_rad && firstLastPairAngleDiff > 0.01) { return true; } } return false; } bool PatternGeometry::hasValenceGreaterThan(const std::vector &numberOfNodesPerSlot, const size_t &valenceThreshold) { //Initialize helping structs if (nodeToSlotMap.empty()) { FlatPatternTopology::constructNodeToSlotMap(numberOfNodesPerSlot, nodeToSlotMap); } if (correspondingNode.empty()) { constructCorrespondingNodeMap(numberOfNodesPerSlot); } if (nodeTiledValence.empty()) { constructNodeToTiledValenceMap(numberOfNodesPerSlot); } //Check tiled valence of the pattern's nodes bool hasNodeWithValenceGreaterThanDesired = false; for (size_t nodeIndex = 0; nodeIndex < vn; nodeIndex++) { const size_t tiledValence = nodeTiledValence[nodeIndex]; if (tiledValence > valenceThreshold) { vert[nodeIndex].C() = vcg::Color4b::LightRed; hasNodeWithValenceGreaterThanDesired = true; } } return hasNodeWithValenceGreaterThanDesired; } bool PatternGeometry::hasDanglingEdges( const std::vector &numberOfNodesPerSlot) { //Initialize helping structs if (nodeToSlotMap.empty()) { FlatPatternTopology::constructNodeToSlotMap(numberOfNodesPerSlot, nodeToSlotMap); } if (correspondingNode.empty()) { constructCorrespondingNodeMap(numberOfNodesPerSlot); } if (nodeTiledValence.empty()) { constructNodeToTiledValenceMap(numberOfNodesPerSlot); } //Check tiled valence of the pattern's nodes bool hasDanglingEdges = false; for (size_t nodeIndex = 0; nodeIndex < vn; nodeIndex++) { const size_t tiledValence = nodeTiledValence[nodeIndex]; if (tiledValence == 1) { vert[nodeIndex].C() = vcg::Color4b::Red; hasDanglingEdges = true; } } return hasDanglingEdges; } bool PatternGeometry::hasUntiledDanglingEdges() { // vcg::tri::Clean::MergeCloseVertex(*this, // 0.0000005); // vcg::tri::Allocator::CompactEveryVector(*this); // vcg::tri::UpdateTopology::VertexEdge(*this); // vcg::tri::UpdateTopology::EdgeEdge(*this); bool hasDanglingEdges = false; for (size_t vi = 0; vi < vn; vi++) { std::vector connectedEdges; vcg::edge::VEStarVE(&vert[vi], connectedEdges); const size_t nodeValence = connectedEdges.size(); if (nodeValence == 1) { if (vert[vi].C().operator==(vcg::Color4b(vcg::Color4b::Red))) { } else { vert[vi].C() = vcg::Color4b::Blue; } hasDanglingEdges = true; } } return hasDanglingEdges; } // TODO: The function expects that the numberOfNodesPerSlot follows a specific // format and that the vertex container was populated in a particular order. void PatternGeometry::constructCorrespondingNodeMap(const std::vector &numberOfNodesPerSlot) { assert(vn != 0 && !nodeToSlotMap.empty() && correspondingNode.empty() && numberOfNodesPerSlot.size() == 7); for (size_t nodeIndex = 0; nodeIndex < vn; nodeIndex++) { const size_t slotIndex = nodeToSlotMap[nodeIndex]; if (slotIndex == 1) { correspondingNode[nodeIndex] = nodeIndex + 1; } else if (slotIndex == 2) { correspondingNode[nodeIndex] = nodeIndex - 1; } else if (slotIndex == 3) { const size_t numberOfNodesBefore = nodeIndex - std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 3, 0); correspondingNode[nodeIndex] = std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 6, 0) - 1 - numberOfNodesBefore; } else if (slotIndex == 5) { const size_t numberOfNodesAfter = std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 6, 0) - 1 - nodeIndex; correspondingNode[nodeIndex] = numberOfNodesAfter + std::accumulate(numberOfNodesPerSlot.begin(), numberOfNodesPerSlot.begin() + 3, 0); } } } bool PatternGeometry::isFullyConnectedWhenTiled() { assert(vn != 0 /* && !correspondingNode.empty()*/); // TrianglePatternGeometry copyOfPattern(*this); // If bottom interface nodes have a valence of zero there definetely more than // a single cc bool bottomInterfaceIsConnected = false; for (size_t nodeIndex = 0; nodeIndex < vn; nodeIndex++) { if (nodeToSlotMap[nodeIndex] == 1 || nodeToSlotMap[nodeIndex] == 4 || nodeToSlotMap[nodeIndex] == 2) { std::vector connectedEdges; vcg::edge::VEStarVE(&vert[nodeIndex], connectedEdges); const size_t nodeValence = connectedEdges.size(); if (nodeValence != 0) { bottomInterfaceIsConnected = true; break; } } } if (!bottomInterfaceIsConnected) { return false; } PatternGeometry fanedPattern = createFan(*this); vcg::tri::Clean::MergeCloseVertex(fanedPattern, 0.000000005); vcg::tri::Allocator::CompactEveryVector(fanedPattern); vcg::tri::UpdateTopology::VertexEdge(fanedPattern); vcg::tri::UpdateTopology::EdgeEdge(fanedPattern); std::vector> eCC; vcg::tri::Clean::edgeMeshConnectedComponents(fanedPattern, eCC); const bool sideInterfaceIsConnected = 1 == eCC.size(); if (!sideInterfaceIsConnected) { return false; } // for (size_t nodeIndex = 0; nodeIndex < vn; nodeIndex++) { // if (nodeTiledValence[nodeIndex] == 0) // continue; // const size_t slotIndex = nodeSlot[nodeIndex]; // // connect nodes belonging to first or third slot(nodes on the first // // triangle edge) // // if (nodeTiledValence[nodeIndex] == 0 && slotIndex == 3) { // // continue; // // } // if (slotIndex == 1 || slotIndex == 3) { // assert(correspondingNode.count(nodeIndex) != 0); // const size_t correspondingNodeIndex = // correspondingNode[nodeIndex]; // std::vector starEdges; // vcg::edge::VEStarVE(&vert[nodeIndex], starEdges); // bool containsEdge = false; // for (TrianglePatternGeometry::EdgeType *e : starEdges) { // assert(vcg::tri::Index(*this, e->V(0)) == nodeIndex || // vcg::tri::Index(*this, e->V(1)) == nodeIndex); // if (vcg::tri::Index(*this, e->V(0)) == nodeIndex) { // if (vcg::tri::Index(*this, e->V(1)) == correspondingNodeIndex) { // containsEdge = true; // break; // } // } else if (vcg::tri::Index(*this, e->V(1)) == nodeIndex) { // if (vcg::tri::Index(*this, e->V(0)) == correspondingNodeIndex) { // containsEdge = true; // break; // } // } // } // if (!containsEdge) { // vcg::tri::Allocator::AddEdge( // copyOfPattern, nodeIndex, correspondingNodeIndex); // } // } else if (slotIndex == 2 || slotIndex == 5) { // assert(correspondingNode.count(nodeIndex) != 0); // } else { // assert(correspondingNode.count(nodeIndex) == 0); // } // } // std::vector> eCC; // vcg::tri::Clean::edgeMeshConnectedComponents( // copyOfPattern, eCC); // size_t numberOfCC_edgeBased = eCC.size(); // size_t numberOfCC_vertexBased = numberOfCC_edgeBased; // if (numberOfCC_edgeBased == 1) { // vcg::tri::UpdateTopology::VertexEdge( // copyOfPattern); // vcg::tri::UpdateTopology::EdgeEdge(copyOfPattern); // vcg::tri::UpdateFlags::VertexSetV(copyOfPattern); // vcg::tri::UpdateFlags::VertexClear(copyOfPattern); // for (size_t ei = 0; ei < copyOfPattern.EN(); ei++) { // copyOfPattern.edge[ei].V(0)->SetV(); // copyOfPattern.edge[ei].V(1)->SetV(); // } // for (size_t vi = 0; vi < copyOfPattern.VN(); vi++) { // if (!copyOfPattern.vert[vi].IsV()) { // numberOfCC_vertexBased++; // } // } // return numberOfCC_vertexBased; // } // return numberOfCC_edgeBased == 1; // TODO: not good return true; } bool PatternGeometry::hasIntersectingEdges( const std::string &patternBinaryRepresentation, const std::unordered_map> &intersectingEdges) { bool containsIntersectingEdges = false; for (size_t validEdgeIndex = 0; validEdgeIndex < patternBinaryRepresentation.size(); validEdgeIndex++) { if (patternBinaryRepresentation[validEdgeIndex] == '1' && intersectingEdges.count(validEdgeIndex) != 0) { for (auto edgeIndexIt = intersectingEdges.find(validEdgeIndex)->second.begin(); edgeIndexIt != intersectingEdges.find(validEdgeIndex)->second.end(); edgeIndexIt++) { if (patternBinaryRepresentation[*edgeIndexIt] == '1') { containsIntersectingEdges = true; // statistics.numberOfIntersectingEdgesOverAllPatterns++; break; // should be uncommented in order to improve // performance } } if (containsIntersectingEdges) { break; // should be uncommented in order to improve performance } } } return containsIntersectingEdges; } std::unordered_map> PatternGeometry::getIntersectingEdges( size_t &numberOfIntersectingEdgePairs) const { std::unordered_map> intersectingEdges; numberOfIntersectingEdgePairs = 0; size_t numberOfEdgePairs; if (en == 0 || en == 1) { numberOfEdgePairs = 0; } else { numberOfEdgePairs = binomialCoefficient(en, 2); } for (size_t edgePairIndex = 0; edgePairIndex < numberOfEdgePairs; edgePairIndex++) { size_t ei0 = en - 2 - floor(sqrt(-8 * edgePairIndex + 4 * en * (en - 1) - 7) / 2.0 - 0.5); size_t ei1 = edgePairIndex + ei0 + 1 - en * (en - 1) / 2 + (en - ei0) * ((en - ei0) - 1) / 2; const vcg::Point2d p0(edge[ei0].cP(0)[0], edge[ei0].cP(0)[1]); const float epsilon = 0.000005; vcg::Box2d bb0(p0 - vcg::Point2d(epsilon, epsilon), p0 + vcg::Point2d(epsilon, epsilon)); const vcg::Point2d p1(edge[ei0].cP(1)[0], edge[ei0].cP(1)[1]); vcg::Box2d bb1(p1 - vcg::Point2d(epsilon, epsilon), p1 + vcg::Point2d(epsilon, epsilon)); const vcg::Point2d p2(edge[ei1].cP(0)[0], edge[ei1].cP(0)[1]); vcg::Box2d bb2(p2 - vcg::Point2d(epsilon, epsilon), p2 + vcg::Point2d(epsilon, epsilon)); if (bb2.Collide(bb1) || bb2.Collide(bb0)) continue; const vcg::Point2d p3(edge[ei1].cP(1)[0], edge[ei1].cP(1)[1]); vcg::Box2d bb3(p3 - vcg::Point2d(epsilon, epsilon), p3 + vcg::Point2d(epsilon, epsilon)); if (bb3.Collide(bb1) || bb3.Collide(bb0)) continue; const vcg::Segment2d s0(p0, p1); const vcg::Segment2d s1(p2, p3); vcg::Point2d intersectionPoint; const bool edgesIntersect = vcg::SegmentSegmentIntersection(s0, s1, intersectionPoint); if (edgesIntersect) { numberOfIntersectingEdgePairs++; intersectingEdges[ei0].insert(ei1); intersectingEdges[ei1].insert(ei0); } } return intersectingEdges; } PatternGeometry::PatternGeometry(const std::string &filename, bool addNormalsIfAbsent) { if (!std::filesystem::exists(std::filesystem::path(filename))) { assert(false); std::cerr << "No flat pattern with name " << filename << std::endl; return; } if (!load(filename)) { assert(false); std::cerr << "File could not be loaded " << filename << std::endl; return; } if (addNormalsIfAbsent) { addNormals(); } vcg::tri::UpdateTopology::VertexEdge(*this); baseTriangleHeight = computeBaseTriangleHeight(); baseTriangle = computeBaseTriangle(); updateEigenEdgeAndVertices(); } double PatternGeometry::computeBaseTriangleHeight() const { return vcg::Distance(vert[0].cP(), vert[interfaceNodeIndex].cP()); } vcg::Triangle3 PatternGeometry::getBaseTriangle() const { return baseTriangle; } void PatternGeometry::addNormals() { bool normalsAreAbsent = vert[0].cN().Norm() < 0.000001; if (normalsAreAbsent) { for (auto &v : vert) { v.N() = CoordType(0, 0, 1); } } } vcg::Triangle3 PatternGeometry::computeBaseTriangle() const { const double baseTriangleHeight = computeBaseTriangleHeight(); double bottomEdgeHalfSize = baseTriangleHeight / std::tan(M_PI / 3); CoordType patternCoord0 = vert[0].cP(); CoordType patternBottomRight = vert[interfaceNodeIndex].cP() + CoordType(bottomEdgeHalfSize, 0, 0); CoordType patternBottomLeft = vert[interfaceNodeIndex].cP() - CoordType(bottomEdgeHalfSize, 0, 0); return vcg::Triangle3(patternCoord0, patternBottomLeft, patternBottomRight); } PatternGeometry::PatternGeometry( const std::vector &numberOfNodesPerSlot, const std::vector &edges) { add(numberOfNodesPerSlot, edges); addNormals(); baseTriangleHeight = computeBaseTriangleHeight(); baseTriangle = computeBaseTriangle(); updateEigenEdgeAndVertices(); } std::shared_ptr PatternGeometry::tilePattern( std::vector &patterns, const std::vector &connectToNeighborsVi, const VCGPolyMesh &tileInto, const std::vector &perSurfaceFacePatternIndices, std::vector &tileIntoEdgesToTiledVi, std::vector> &perPatternIndexToTiledPatternEdgeIndex) { perPatternIndexToTiledPatternEdgeIndex.resize(patterns.size()); std::shared_ptr pTiledPattern(new PatternGeometry); std::vector> tileIntoEdgeToInterfaceVi( tileInto.EN()); //ith element contains all the interface nodes that lay on the ith edge of tileInto //Compute the barycentric coords of the verts in the base triangle pattern std::vector> barycentricCoordinates(patterns.size()); for (size_t patternIndex = 0; patternIndex < patterns.size(); patternIndex++) { const PatternGeometry &pattern = patterns[patternIndex]; const vcg::Triangle3 &baseTriangle = pattern.getBaseTriangle(); barycentricCoordinates[patternIndex].resize(pattern.VN()); for (int vi = 0; vi < pattern.VN(); vi++) { CoordType barycentricCoords_vi; vcg::InterpolationParameters, double>(baseTriangle, pattern.vert[vi].cP(), barycentricCoords_vi); barycentricCoordinates[patternIndex][vi] = barycentricCoords_vi; } } VCGTriMesh tileIntoEdgeMesh; assert(vcg::tri::HasFEAdjacency(tileInto)); assert(vcg::tri::HasFVAdjacency(tileInto)); for (const VCGPolyMesh::FaceType &f : tileInto.face) { CoordType centerOfFace(0, 0, 0); for (size_t vi = 0; vi < f.VN(); vi++) { centerOfFace = centerOfFace + f.cP(vi); } centerOfFace /= f.VN(); vcg::tri::Allocator::AddVertex(tileIntoEdgeMesh, centerOfFace, vcg::Color4b::Yellow); std::vector firstInFanConnectToNeighbor_vi(connectToNeighborsVi); for (int &vi : firstInFanConnectToNeighbor_vi) { vi += pTiledPattern->VN(); } const size_t facePatternIndex = perSurfaceFacePatternIndices[tileInto.getIndex(f)]; ConstPatternGeometry &pattern = patterns[facePatternIndex]; for (size_t vi = 0; vi < f.VN(); vi++) { auto ep = f.FEp(vi); assert(vcg::tri::IsValidPointer(tileInto, ep)); std::vector meshTrianglePoints{centerOfFace, f.cP(vi), vi + 1 == f.VN() ? f.cP(0) : f.cP(vi + 1)}; // std::vector meshTrianglePoints{centerOfFace, ep->cP(0), ep->cP(1)}; auto fit = vcg::tri::Allocator::AddFace(tileIntoEdgeMesh, meshTrianglePoints[0], meshTrianglePoints[1], meshTrianglePoints[2]); // CoordType faceNormal = ((meshTrianglePoints[1] - meshTrianglePoints[0]) // ^ (meshTrianglePoints[2] - meshTrianglePoints[0])) // .Normalize(); //TODO: in planar surfaces I should compute the face of triangle CoordType faceNormal = f.cN(); fit->N() = faceNormal; PatternGeometry transformedPattern; transformedPattern.copy(pattern); //Transform the base triangle nodes to the mesh triangle using barycentric coords for (int vi = 0; vi < transformedPattern.VN(); vi++) { transformedPattern.vert[vi].P() = CoordType( meshTrianglePoints[0] * barycentricCoordinates[facePatternIndex][vi][0] + meshTrianglePoints[1] * barycentricCoordinates[facePatternIndex][vi][1] + meshTrianglePoints[2] * barycentricCoordinates[facePatternIndex][vi][2]); } for (VertexType &v : transformedPattern.vert) { v.N() = faceNormal; } vcg::tri::Append::Remap remap; vcg::tri::Append::Mesh(*pTiledPattern, transformedPattern, remap); for (size_t ei = 0; ei < pattern.EN(); ei++) { perPatternIndexToTiledPatternEdgeIndex[facePatternIndex].push_back(remap.edge[ei]); } const size_t ei = tileInto.getIndex(ep); tileIntoEdgeToInterfaceVi[ei].push_back(remap.vert[pattern.interfaceNodeIndex]); //Add edges for connecting the desired vertices if (!connectToNeighborsVi.empty()) { if (vi + 1 == f.VN()) { for (int connectToNeighborIndex = 0; connectToNeighborIndex < connectToNeighborsVi.size(); connectToNeighborIndex++) { auto eIt = vcg::tri::Allocator::AddEdge( *pTiledPattern, firstInFanConnectToNeighbor_vi[connectToNeighborIndex], pTiledPattern->VN() - pattern.VN() + connectToNeighborsVi[connectToNeighborIndex]); perPatternIndexToTiledPatternEdgeIndex[facePatternIndex].push_back( pTiledPattern->getIndex(*eIt)); } } if (vi != 0) { for (int connectToNeighborIndex = 0; connectToNeighborIndex < connectToNeighborsVi.size(); connectToNeighborIndex++) { auto eIt = vcg::tri::Allocator::AddEdge( *pTiledPattern, pTiledPattern->VN() - 2 * pattern.VN() + connectToNeighborsVi[connectToNeighborIndex], pTiledPattern->VN() - pattern.VN() + connectToNeighborsVi[connectToNeighborIndex]); perPatternIndexToTiledPatternEdgeIndex[facePatternIndex].push_back( pTiledPattern->getIndex(*eIt)); } } } // tiledPattern.updateEigenEdgeAndVertices(); // tiledPattern.registerForDrawing(); // polyscope::show(); } } vcg::tri::Allocator::PointerUpdater pu_vertices; vcg::tri::Allocator::PointerUpdater pu_edges; pTiledPattern->removeDuplicateVertices(pu_vertices, pu_edges); //Update perPattern // for (std::vector &tiledPatternEdges : perPatternIndexToTiledPatternEdgeIndex) { // for (size_t &ei : tiledPatternEdges) { // ei = pu_edges.remap[ei]; // } // auto end = tiledPatternEdges.end(); // for (auto it = tiledPatternEdges.begin(); it != end; ++it) { // end = std::remove(it + 1, end, *it); // } // tiledPatternEdges.erase(end, tiledPatternEdges.end()); // } const size_t sumOfEdgeIndices = std::accumulate(perPatternIndexToTiledPatternEdgeIndex.begin(), perPatternIndexToTiledPatternEdgeIndex.end(), 0, [](const size_t &sum, const std::vector &v) { return sum + v.size(); }); assert(pTiledPattern->EN() == sumOfEdgeIndices); tileIntoEdgesToTiledVi.clear(); tileIntoEdgesToTiledVi.resize(tileInto.EN()); for (int ei = 0; ei < tileInto.EN(); ei++) { const std::vector interfaceVis = tileIntoEdgeToInterfaceVi[ei]; assert(interfaceVis.size() == 1 || interfaceVis.size() == 2); assert( interfaceVis.size() == 1 || (interfaceVis.size() == 2 && (pu_vertices.remap[interfaceVis[0]] == std::numeric_limits::max() || pu_vertices.remap[interfaceVis[1]] == std::numeric_limits::max()))); tileIntoEdgesToTiledVi[ei] = pu_vertices.remap[interfaceVis[0]]; } pTiledPattern->deleteDanglingVertices(); vcg::tri::Allocator::CompactEveryVector(*pTiledPattern); pTiledPattern->updateEigenEdgeAndVertices(); pTiledPattern->save(); return pTiledPattern; } bool PatternGeometry::createHoneycombAtom() { VCGEdgeMesh honeycombQuarter; const VCGEdgeMesh::CoordType n(0, 0, 1); const double H = 0.2; const double height = 1.5 * H; const double width = 0.2; const double theta = 70; const double dy = tan(vcg::math::ToRad(90 - theta)) * width / 2; vcg::tri::Allocator::AddVertex(honeycombQuarter, VCGEdgeMesh::CoordType(0, height / 2, 0), n); vcg::tri::Allocator::AddVertex(honeycombQuarter, VCGEdgeMesh::CoordType(0, H / 2 - dy, 0), n); vcg::tri::Allocator::AddVertex(honeycombQuarter, VCGEdgeMesh::CoordType(width / 2, H / 2, 0), n); vcg::tri::Allocator::AddVertex(honeycombQuarter, VCGEdgeMesh::CoordType(width / 2, 0, 0), n); vcg::tri::Allocator::AddEdge(honeycombQuarter, 0, 1); vcg::tri::Allocator::AddEdge(honeycombQuarter, 1, 2); vcg::tri::Allocator::AddEdge(honeycombQuarter, 2, 3); VCGEdgeMesh honeycombAtom; // Top right vcg::tri::Append::MeshCopy(honeycombAtom, honeycombQuarter); // Bottom right vcg::Matrix44d rotM; rotM.SetRotateDeg(180, vcg::Point3d(1, 0, 0)); vcg::tri::UpdatePosition::Matrix(honeycombQuarter, rotM); vcg::tri::Append::Mesh(honeycombAtom, honeycombQuarter); // Bottom left rotM.SetRotateDeg(180, vcg::Point3d(0, 1, 0)); vcg::tri::UpdatePosition::Matrix(honeycombQuarter, rotM); vcg::tri::Append::Mesh(honeycombAtom, honeycombQuarter); // Top left rotM.SetRotateDeg(180, vcg::Point3d(1, 0, 0)); vcg::tri::UpdatePosition::Matrix(honeycombQuarter, rotM); vcg::tri::Append::Mesh(honeycombAtom, honeycombQuarter); for (VertexType &v : honeycombAtom.vert) { v.P()[2] = 0; } return true; } void PatternGeometry::copy(PatternGeometry ©From) { VCGEdgeMesh::copy(copyFrom); baseTriangleHeight = copyFrom.getBaseTriangleHeight(); baseTriangle = copyFrom.getBaseTriangle(); interfaceNodeIndex = copyFrom.interfaceNodeIndex; } void PatternGeometry::scale(const double &desiredBaseTriangleCentralEdgeSize, const int &interfaceNodeIndex) { const double baseTriangleCentralEdgeSize = computeBaseTriangleHeight(); const double scaleRatio = desiredBaseTriangleCentralEdgeSize / baseTriangleCentralEdgeSize; vcg::tri::UpdatePosition::Scale(*this, scaleRatio); baseTriangle = computeBaseTriangle(); baseTriangleHeight = computeBaseTriangleHeight(); } void PatternGeometry::createFan(const std::vector &connectToNeighborsVi, const size_t &fanSize) { PatternGeometry rotatedPattern; vcg::tri::Append::MeshCopy(rotatedPattern, *this); for (int rotationCounter = 1; rotationCounter < fanSize; rotationCounter++) { vcg::Matrix44d R; auto rotationAxis = vcg::Point3d(0, 0, 1); R.SetRotateDeg(360 / fanSize, rotationAxis); vcg::tri::UpdatePosition::Matrix(rotatedPattern, R); vcg::tri::Append::Mesh(*this, rotatedPattern); //Add edges for connecting the desired vertices if (!connectToNeighborsVi.empty()) { if (rotationCounter == fanSize - 1) { for (int connectToNeighborIndex = 0; connectToNeighborIndex < connectToNeighborsVi.size(); connectToNeighborIndex++) { vcg::tri::Allocator::AddEdge( *this, connectToNeighborsVi[connectToNeighborIndex], this->VN() - rotatedPattern.VN() + connectToNeighborsVi[connectToNeighborIndex]); } } for (int connectToNeighborIndex = 0; connectToNeighborIndex < connectToNeighborsVi.size(); connectToNeighborIndex++) { vcg::tri::Allocator::AddEdge( *this, this->VN() - 2 * rotatedPattern.VN() + connectToNeighborsVi[connectToNeighborIndex], this->VN() - rotatedPattern.VN() + connectToNeighborsVi[connectToNeighborIndex]); } } removeDuplicateVertices(); updateEigenEdgeAndVertices(); } } double PatternGeometry::getBaseTriangleHeight() const { return baseTriangleHeight; }