dust3d/src/meshgenerator.cpp

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#include <QDebug>
#include <QElapsedTimer>
#include <QVector2D>
#include <QGuiApplication>
#include <QMatrix4x4>
#include <nodemesh/builder.h>
#include <nodemesh/modifier.h>
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#include <nodemesh/misc.h>
#include <nodemesh/recombiner.h>
#include "meshgenerator.h"
#include "util.h"
#include "trianglesourcenoderesolve.h"
#include "cutface.h"
#include "parttarget.h"
#include "theme.h"
#include "partbase.h"
#include "imageforever.h"
MeshGenerator::MeshGenerator(Snapshot *snapshot) :
m_snapshot(snapshot)
{
}
MeshGenerator::~MeshGenerator()
{
for (auto &it: m_partPreviewMeshes)
delete it.second;
delete m_resultMesh;
delete m_snapshot;
delete m_outcome;
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delete m_cutFaceTransforms;
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delete m_nodesCutFaces;
}
void MeshGenerator::setId(quint64 id)
{
m_id = id;
}
quint64 MeshGenerator::id()
{
return m_id;
}
bool MeshGenerator::isSucceed()
{
return m_isSucceed;
}
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MeshLoader *MeshGenerator::takeResultMesh()
{
MeshLoader *resultMesh = m_resultMesh;
m_resultMesh = nullptr;
return resultMesh;
}
MeshLoader *MeshGenerator::takePartPreviewMesh(const QUuid &partId)
{
MeshLoader *resultMesh = m_partPreviewMeshes[partId];
m_partPreviewMeshes[partId] = nullptr;
return resultMesh;
}
const std::set<QUuid> &MeshGenerator::generatedPreviewPartIds()
{
return m_generatedPreviewPartIds;
}
Outcome *MeshGenerator::takeOutcome()
{
Outcome *outcome = m_outcome;
m_outcome = nullptr;
return outcome;
}
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std::map<QUuid, nodemesh::Builder::CutFaceTransform> *MeshGenerator::takeCutFaceTransforms()
{
auto cutFaceTransforms = m_cutFaceTransforms;
m_cutFaceTransforms = nullptr;
return cutFaceTransforms;
}
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std::map<QUuid, std::map<QString, QVector2D>> *MeshGenerator::takeNodesCutFaces()
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{
auto nodesCutFaces = m_nodesCutFaces;
m_nodesCutFaces = nullptr;
return nodesCutFaces;
}
void MeshGenerator::collectParts()
{
for (const auto &node: m_snapshot->nodes) {
QString partId = valueOfKeyInMapOrEmpty(node.second, "partId");
if (partId.isEmpty())
continue;
m_partNodeIds[partId].insert(node.first);
}
for (const auto &edge: m_snapshot->edges) {
QString partId = valueOfKeyInMapOrEmpty(edge.second, "partId");
if (partId.isEmpty())
continue;
m_partEdgeIds[partId].insert(edge.first);
}
}
bool MeshGenerator::checkIsPartDirty(const QString &partIdString)
{
auto findPart = m_snapshot->parts.find(partIdString);
if (findPart == m_snapshot->parts.end()) {
qDebug() << "Find part failed:" << partIdString;
return false;
}
return isTrueValueString(valueOfKeyInMapOrEmpty(findPart->second, "dirty"));
}
bool MeshGenerator::checkIsPartDependencyDirty(const QString &partIdString)
{
auto findPart = m_snapshot->parts.find(partIdString);
if (findPart == m_snapshot->parts.end()) {
qDebug() << "Find part failed:" << partIdString;
return false;
}
QString cutFaceString = valueOfKeyInMapOrEmpty(findPart->second, "cutFace");
QUuid cutFaceLinkedPartId = QUuid(cutFaceString);
if (!cutFaceLinkedPartId.isNull()) {
if (checkIsPartDirty(cutFaceString))
return true;
}
for (const auto &nodeIdString: m_partNodeIds[partIdString]) {
auto findNode = m_snapshot->nodes.find(nodeIdString);
if (findNode == m_snapshot->nodes.end()) {
qDebug() << "Find node failed:" << nodeIdString;
continue;
}
QString cutFaceString = valueOfKeyInMapOrEmpty(findNode->second, "cutFace");
QUuid cutFaceLinkedPartId = QUuid(cutFaceString);
if (!cutFaceLinkedPartId.isNull()) {
if (checkIsPartDirty(cutFaceString))
return true;
}
}
return false;
}
bool MeshGenerator::checkIsComponentDirty(const QString &componentIdString)
{
bool isDirty = false;
const std::map<QString, QString> *component = &m_snapshot->rootComponent;
if (componentIdString != QUuid().toString()) {
auto findComponent = m_snapshot->components.find(componentIdString);
if (findComponent == m_snapshot->components.end()) {
qDebug() << "Component not found:" << componentIdString;
return isDirty;
}
component = &findComponent->second;
}
if (isTrueValueString(valueOfKeyInMapOrEmpty(*component, "dirty"))) {
isDirty = true;
}
QString linkDataType = valueOfKeyInMapOrEmpty(*component, "linkDataType");
if ("partId" == linkDataType) {
QString partId = valueOfKeyInMapOrEmpty(*component, "linkData");
if (checkIsPartDirty(partId)) {
m_dirtyPartIds.insert(partId);
isDirty = true;
}
if (!isDirty) {
if (checkIsPartDependencyDirty(partId)) {
isDirty = true;
}
}
}
for (const auto &childId: valueOfKeyInMapOrEmpty(*component, "children").split(",")) {
if (childId.isEmpty())
continue;
if (checkIsComponentDirty(childId)) {
isDirty = true;
}
}
if (isDirty)
m_dirtyComponentIds.insert(componentIdString);
return isDirty;
}
void MeshGenerator::checkDirtyFlags()
{
checkIsComponentDirty(QUuid().toString());
}
void MeshGenerator::cutFaceStringToCutTemplate(const QString &cutFaceString, std::vector<QVector2D> &cutTemplate)
{
//std::map<QString, QVector2D> cutTemplateMapByName;
QUuid cutFaceLinkedPartId = QUuid(cutFaceString);
if (!cutFaceLinkedPartId.isNull()) {
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std::map<QString, std::tuple<float, float, float>> cutFaceNodeMap;
auto findCutFaceLinkedPart = m_snapshot->parts.find(cutFaceString);
if (findCutFaceLinkedPart == m_snapshot->parts.end()) {
qDebug() << "Find cut face linked part failed:" << cutFaceString;
} else {
// Build node info map
for (const auto &nodeIdString: m_partNodeIds[cutFaceString]) {
auto findNode = m_snapshot->nodes.find(nodeIdString);
if (findNode == m_snapshot->nodes.end()) {
qDebug() << "Find node failed:" << nodeIdString;
continue;
}
auto &node = findNode->second;
float radius = valueOfKeyInMapOrEmpty(node, "radius").toFloat();
float x = (valueOfKeyInMapOrEmpty(node, "x").toFloat() - m_mainProfileMiddleX);
float y = (m_mainProfileMiddleY - valueOfKeyInMapOrEmpty(node, "y").toFloat());
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cutFaceNodeMap.insert({nodeIdString, std::make_tuple(radius, x, y)});
}
// Build edge link
std::map<QString, std::vector<QString>> cutFaceNodeLinkMap;
for (const auto &edgeIdString: m_partEdgeIds[cutFaceString]) {
auto findEdge = m_snapshot->edges.find(edgeIdString);
if (findEdge == m_snapshot->edges.end()) {
qDebug() << "Find edge failed:" << edgeIdString;
continue;
}
auto &edge = findEdge->second;
QString fromNodeIdString = valueOfKeyInMapOrEmpty(edge, "from");
QString toNodeIdString = valueOfKeyInMapOrEmpty(edge, "to");
cutFaceNodeLinkMap[fromNodeIdString].push_back(toNodeIdString);
cutFaceNodeLinkMap[toNodeIdString].push_back(fromNodeIdString);
}
// Find endpoint
QString endPointNodeIdString;
std::vector<std::pair<QString, std::tuple<float, float, float>>> endpointNodes;
for (const auto &it: cutFaceNodeLinkMap) {
if (1 == it.second.size()) {
const auto &findNode = cutFaceNodeMap.find(it.first);
if (findNode != cutFaceNodeMap.end())
endpointNodes.push_back({it.first, findNode->second});
}
}
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bool isRing = endpointNodes.empty();
if (endpointNodes.empty()) {
for (const auto &it: cutFaceNodeMap) {
endpointNodes.push_back({it.first, it.second});
}
}
if (!endpointNodes.empty()) {
// Calculate the center points
QVector2D sumOfPositions;
for (const auto &it: endpointNodes) {
sumOfPositions += QVector2D(std::get<1>(it.second), std::get<2>(it.second));
}
QVector2D center = sumOfPositions / endpointNodes.size();
// Calculate all the directions emit from center to the endpoint,
// choose the minimal angle, angle: (0, 0 -> -1, -1) to the direction
const QVector3D referenceDirection = QVector3D(-1, -1, 0).normalized();
int choosenEndpoint = -1;
float choosenRadian = 0;
for (int i = 0; i < (int)endpointNodes.size(); ++i) {
const auto &it = endpointNodes[i];
QVector2D direction2d = (QVector2D(std::get<1>(it.second), std::get<2>(it.second)) -
center);
QVector3D direction = QVector3D(direction2d.x(), direction2d.y(), 0).normalized();
float radian = radianBetweenVectors(referenceDirection, direction);
if (-1 == choosenEndpoint || radian < choosenRadian) {
choosenRadian = radian;
choosenEndpoint = i;
}
}
endPointNodeIdString = endpointNodes[choosenEndpoint].first;
}
// Loop all linked nodes
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std::vector<std::tuple<float, float, float, QString>> cutFaceNodes;
std::set<QString> cutFaceVisitedNodeIds;
std::function<void (const QString &)> loopNodeLink;
loopNodeLink = [&](const QString &fromNodeIdString) {
auto findCutFaceNode = cutFaceNodeMap.find(fromNodeIdString);
if (findCutFaceNode == cutFaceNodeMap.end())
return;
if (cutFaceVisitedNodeIds.find(fromNodeIdString) != cutFaceVisitedNodeIds.end())
return;
cutFaceVisitedNodeIds.insert(fromNodeIdString);
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cutFaceNodes.push_back(std::make_tuple(std::get<0>(findCutFaceNode->second),
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std::get<1>(findCutFaceNode->second),
std::get<2>(findCutFaceNode->second),
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fromNodeIdString));
auto findNeighbor = cutFaceNodeLinkMap.find(fromNodeIdString);
if (findNeighbor == cutFaceNodeLinkMap.end())
return;
for (const auto &it: findNeighbor->second) {
if (cutFaceVisitedNodeIds.find(it) == cutFaceVisitedNodeIds.end()) {
loopNodeLink(it);
break;
}
}
};
if (!endPointNodeIdString.isEmpty()) {
loopNodeLink(endPointNodeIdString);
}
// Fetch points from linked nodes
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std::vector<QString> cutTemplateNames;
cutFacePointsFromNodes(cutTemplate, cutFaceNodes, isRing, &cutTemplateNames);
//for (size_t i = 0; i < cutTemplateNames.size(); ++i) {
// cutTemplateMapByName.insert({cutTemplateNames[i], cutTemplate[i]});
//}
}
}
if (cutTemplate.size() < 3) {
CutFace cutFace = CutFaceFromString(cutFaceString.toUtf8().constData());
cutTemplate = CutFaceToPoints(cutFace);
//cutTemplateMapByName.clear();
//for (size_t i = 0; i < cutTemplate.size(); ++i) {
// cutTemplateMapByName.insert({cutFaceString + "/" + QString::number(i + 1), cutTemplate[i]});
//}
}
}
nodemesh::Combiner::Mesh *MeshGenerator::combinePartMesh(const QString &partIdString, bool *hasError, bool addIntermediateNodes)
{
auto findPart = m_snapshot->parts.find(partIdString);
if (findPart == m_snapshot->parts.end()) {
qDebug() << "Find part failed:" << partIdString;
return nullptr;
}
QUuid partId = QUuid(partIdString);
auto &part = findPart->second;
bool isDisabled = isTrueValueString(valueOfKeyInMapOrEmpty(part, "disabled"));
bool xMirrored = isTrueValueString(valueOfKeyInMapOrEmpty(part, "xMirrored"));
bool subdived = isTrueValueString(valueOfKeyInMapOrEmpty(part, "subdived"));
bool rounded = isTrueValueString(valueOfKeyInMapOrEmpty(part, "rounded"));
bool chamfered = isTrueValueString(valueOfKeyInMapOrEmpty(part, "chamfered"));
QString colorString = valueOfKeyInMapOrEmpty(part, "color");
QColor partColor = colorString.isEmpty() ? m_defaultPartColor : QColor(colorString);
float deformThickness = 1.0;
float deformWidth = 1.0;
float cutRotation = 0.0;
auto target = PartTargetFromString(valueOfKeyInMapOrEmpty(part, "target").toUtf8().constData());
auto base = PartBaseFromString(valueOfKeyInMapOrEmpty(part, "base").toUtf8().constData());
QString cutFaceString = valueOfKeyInMapOrEmpty(part, "cutFace");
std::vector<QVector2D> cutTemplate;
cutFaceStringToCutTemplate(cutFaceString, cutTemplate);
if (chamfered)
nodemesh::chamferFace2D(&cutTemplate);
QString cutRotationString = valueOfKeyInMapOrEmpty(part, "cutRotation");
if (!cutRotationString.isEmpty()) {
cutRotation = cutRotationString.toFloat();
}
QString thicknessString = valueOfKeyInMapOrEmpty(part, "deformThickness");
if (!thicknessString.isEmpty()) {
deformThickness = thicknessString.toFloat();
}
QString widthString = valueOfKeyInMapOrEmpty(part, "deformWidth");
if (!widthString.isEmpty()) {
deformWidth = widthString.toFloat();
}
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QImage deformImageStruct;
const QImage *deformImage = nullptr;
QString deformMapImageIdString = valueOfKeyInMapOrEmpty(part, "deformMapImageId");
if (!deformMapImageIdString.isEmpty()) {
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ImageForever::copy(QUuid(deformMapImageIdString), deformImageStruct);
if (!deformImageStruct.isNull())
deformImage = &deformImageStruct;
if (nullptr == deformImage) {
qDebug() << "Deform image id not found:" << deformMapImageIdString;
}
}
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float deformMapScale = 1.0;
QString deformMapScaleString = valueOfKeyInMapOrEmpty(part, "deformMapScale");
if (!deformMapScaleString.isEmpty())
deformMapScale = deformMapScaleString.toFloat();
QUuid materialId;
QString materialIdString = valueOfKeyInMapOrEmpty(part, "materialId");
if (!materialIdString.isEmpty())
materialId = QUuid(materialIdString);
float colorSolubility = 0;
QString colorSolubilityString = valueOfKeyInMapOrEmpty(part, "colorSolubility");
if (!colorSolubilityString.isEmpty())
colorSolubility = colorSolubilityString.toFloat();
auto &partCache = m_cacheContext->parts[partIdString];
partCache.outcomeNodes.clear();
partCache.outcomeNodeVertices.clear();
partCache.outcomePaintMap.clear();
partCache.outcomePaintMap.partId = partId;
partCache.vertices.clear();
partCache.faces.clear();
partCache.previewTriangles.clear();
partCache.isSucceed = false;
delete partCache.mesh;
partCache.mesh = nullptr;
struct NodeInfo
{
float radius = 0;
QVector3D position;
BoneMark boneMark = BoneMark::None;
bool hasCutFaceSettings = false;
float cutRotation = 0.0;
QString cutFace;
};
std::map<QString, NodeInfo> nodeInfos;
for (const auto &nodeIdString: m_partNodeIds[partIdString]) {
auto findNode = m_snapshot->nodes.find(nodeIdString);
if (findNode == m_snapshot->nodes.end()) {
qDebug() << "Find node failed:" << nodeIdString;
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continue;
}
auto &node = findNode->second;
float radius = valueOfKeyInMapOrEmpty(node, "radius").toFloat();
float x = (valueOfKeyInMapOrEmpty(node, "x").toFloat() - m_mainProfileMiddleX);
float y = (m_mainProfileMiddleY - valueOfKeyInMapOrEmpty(node, "y").toFloat());
float z = (m_sideProfileMiddleX - valueOfKeyInMapOrEmpty(node, "z").toFloat());
BoneMark boneMark = BoneMarkFromString(valueOfKeyInMapOrEmpty(node, "boneMark").toUtf8().constData());
bool hasCutFaceSettings = false;
float cutRotation = 0.0;
QString cutFace;
const auto &cutFaceIt = node.find("cutFace");
if (cutFaceIt != node.end()) {
cutFace = cutFaceIt->second;
hasCutFaceSettings = true;
const auto &cutRotationIt = node.find("cutRotation");
if (cutRotationIt != node.end()) {
cutRotation = cutRotationIt->second.toFloat();
}
}
auto &nodeInfo = nodeInfos[nodeIdString];
nodeInfo.position = QVector3D(x, y, z);
nodeInfo.radius = radius;
nodeInfo.boneMark = boneMark;
nodeInfo.hasCutFaceSettings = hasCutFaceSettings;
nodeInfo.cutRotation = cutRotation;
nodeInfo.cutFace = cutFace;
}
std::set<std::pair<QString, QString>> edges;
for (const auto &edgeIdString: m_partEdgeIds[partIdString]) {
auto findEdge = m_snapshot->edges.find(edgeIdString);
if (findEdge == m_snapshot->edges.end()) {
qDebug() << "Find edge failed:" << edgeIdString;
continue;
}
auto &edge = findEdge->second;
QString fromNodeIdString = valueOfKeyInMapOrEmpty(edge, "from");
QString toNodeIdString = valueOfKeyInMapOrEmpty(edge, "to");
const auto &findFromNodeInfo = nodeInfos.find(fromNodeIdString);
if (findFromNodeInfo == nodeInfos.end()) {
qDebug() << "Find from-node info failed:" << fromNodeIdString;
continue;
}
const auto &findToNodeInfo = nodeInfos.find(toNodeIdString);
if (findToNodeInfo == nodeInfos.end()) {
qDebug() << "Find to-node info failed:" << toNodeIdString;
continue;
}
edges.insert({fromNodeIdString, toNodeIdString});
}
std::map<QString, int> nodeIdStringToIndexMap;
std::map<int, QString> nodeIndexToIdStringMap;
nodemesh::Modifier *modifier = new nodemesh::Modifier;
if (addIntermediateNodes)
modifier->enableIntermediateAddition();
QString mirroredPartIdString;
QUuid mirroredPartId;
if (xMirrored) {
mirroredPartId = QUuid().createUuid();
mirroredPartIdString = mirroredPartId.toString();
m_cacheContext->partMirrorIdMap[mirroredPartIdString] = partIdString;
}
for (const auto &nodeIt: nodeInfos) {
const auto &nodeIdString = nodeIt.first;
const auto &nodeInfo = nodeIt.second;
size_t nodeIndex = 0;
if (nodeInfo.hasCutFaceSettings) {
std::vector<QVector2D> nodeCutTemplate;
cutFaceStringToCutTemplate(nodeInfo.cutFace, nodeCutTemplate);
if (chamfered)
nodemesh::chamferFace2D(&nodeCutTemplate);
nodeIndex = modifier->addNode(nodeInfo.position, nodeInfo.radius, nodeCutTemplate, nodeInfo.cutRotation);
} else {
nodeIndex = modifier->addNode(nodeInfo.position, nodeInfo.radius, cutTemplate, cutRotation);
}
nodeIdStringToIndexMap[nodeIdString] = nodeIndex;
nodeIndexToIdStringMap[nodeIndex] = nodeIdString;
OutcomeNode outcomeNode;
outcomeNode.partId = QUuid(partIdString);
outcomeNode.nodeId = QUuid(nodeIdString);
outcomeNode.origin = nodeInfo.position;
outcomeNode.radius = nodeInfo.radius;
outcomeNode.color = partColor;
outcomeNode.materialId = materialId;
outcomeNode.colorSolubility = colorSolubility;
outcomeNode.boneMark = nodeInfo.boneMark;
outcomeNode.mirroredByPartId = mirroredPartIdString;
partCache.outcomeNodes.push_back(outcomeNode);
if (xMirrored) {
outcomeNode.partId = mirroredPartId;
outcomeNode.mirrorFromPartId = QUuid(partId);
outcomeNode.mirroredByPartId = QUuid();
outcomeNode.origin.setX(-nodeInfo.position.x());
partCache.outcomeNodes.push_back(outcomeNode);
}
}
for (const auto &edgeIt: edges) {
const QString &fromNodeIdString = edgeIt.first;
const QString &toNodeIdString = edgeIt.second;
auto findFromNodeIndex = nodeIdStringToIndexMap.find(fromNodeIdString);
if (findFromNodeIndex == nodeIdStringToIndexMap.end()) {
qDebug() << "Find from-node failed:" << fromNodeIdString;
continue;
}
auto findToNodeIndex = nodeIdStringToIndexMap.find(toNodeIdString);
if (findToNodeIndex == nodeIdStringToIndexMap.end()) {
qDebug() << "Find to-node failed:" << toNodeIdString;
continue;
}
modifier->addEdge(findFromNodeIndex->second, findToNodeIndex->second);
}
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if (subdived)
modifier->subdivide();
if (rounded)
modifier->roundEnd();
modifier->finalize();
nodemesh::Builder *builder = new nodemesh::Builder;
builder->setDeformThickness(deformThickness);
builder->setDeformWidth(deformWidth);
builder->setDeformMapScale(deformMapScale);
if (nullptr != deformImage)
builder->setDeformMapImage(deformImage);
if (PartBase::YZ == base) {
builder->enableBaseNormalOnX(false);
} else if (PartBase::Average == base) {
builder->enableBaseNormalAverage(true);
} else if (PartBase::XY == base) {
builder->enableBaseNormalOnZ(false);
} else if (PartBase::ZX == base) {
builder->enableBaseNormalOnY(false);
}
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std::vector<size_t> builderNodeIndices;
for (const auto &node: modifier->nodes()) {
auto nodeIndex = builder->addNode(node.position, node.radius, node.cutTemplate, node.cutRotation);
builder->setNodeOriginInfo(nodeIndex, node.nearOriginNodeIndex, node.farOriginNodeIndex);
builderNodeIndices.push_back(nodeIndex);
const auto &originNodeIdString = nodeIndexToIdStringMap[node.originNodeIndex];
OutcomePaintNode paintNode;
paintNode.originNodeId = QUuid(originNodeIdString);
paintNode.radius = node.radius;
paintNode.origin = node.position;
partCache.outcomePaintMap.paintNodes.push_back(paintNode);
}
for (const auto &edge: modifier->edges())
builder->addEdge(edge.firstNodeIndex, edge.secondNodeIndex);
bool buildSucceed = builder->build();
partCache.vertices = builder->generatedVertices();
partCache.faces = builder->generatedFaces();
for (size_t i = 0; i < partCache.vertices.size(); ++i) {
const auto &position = partCache.vertices[i];
const auto &source = builder->generatedVerticesSourceNodeIndices()[i];
size_t nodeIndex = modifier->nodes()[source].originNodeIndex;
const auto &nodeIdString = nodeIndexToIdStringMap[nodeIndex];
partCache.outcomeNodeVertices.push_back({position, {partIdString, nodeIdString}});
auto &paintNode = partCache.outcomePaintMap.paintNodes[source];
paintNode.vertices.push_back(position);
}
for (size_t i = 0; i < partCache.outcomePaintMap.paintNodes.size(); ++i) {
auto &paintNode = partCache.outcomePaintMap.paintNodes[i];
paintNode.baseNormal = builder->nodeBaseNormal(i);
paintNode.direction = builder->nodeTraverseDirection(i);
paintNode.order = builder->nodeTraverseOrder(i);
}
bool hasMeshError = false;
nodemesh::Combiner::Mesh *mesh = nullptr;
if (buildSucceed) {
mesh = new nodemesh::Combiner::Mesh(partCache.vertices, partCache.faces, false);
if (!mesh->isNull()) {
if (xMirrored) {
std::vector<QVector3D> xMirroredVertices;
std::vector<std::vector<size_t>> xMirroredFaces;
makeXmirror(partCache.vertices, partCache.faces, &xMirroredVertices, &xMirroredFaces);
for (size_t i = 0; i < xMirroredVertices.size(); ++i) {
const auto &position = xMirroredVertices[i];
const auto &source = builder->generatedVerticesSourceNodeIndices()[i];
size_t nodeIndex = modifier->nodes()[source].originNodeIndex;
const auto &nodeIdString = nodeIndexToIdStringMap[nodeIndex];
partCache.outcomeNodeVertices.push_back({position, {mirroredPartIdString, nodeIdString}});
}
size_t xMirrorStart = partCache.vertices.size();
for (const auto &vertex: xMirroredVertices)
partCache.vertices.push_back(vertex);
for (const auto &face: xMirroredFaces) {
std::vector<size_t> newFace = face;
for (auto &it: newFace)
it += xMirrorStart;
partCache.faces.push_back(newFace);
}
nodemesh::Combiner::Mesh *xMirroredMesh = new nodemesh::Combiner::Mesh(xMirroredVertices, xMirroredFaces);
nodemesh::Combiner::Mesh *newMesh = combineTwoMeshes(*mesh,
*xMirroredMesh, nodemesh::Combiner::Method::Union);
delete xMirroredMesh;
if (newMesh && !newMesh->isNull()) {
delete mesh;
mesh = newMesh;
} else {
hasMeshError = true;
qDebug() << "Xmirrored mesh generate failed";
delete newMesh;
}
}
} else {
hasMeshError = true;
qDebug() << "Mesh built is uncombinable";
}
} else {
hasMeshError = true;
qDebug() << "Mesh build failed";
}
delete m_partPreviewMeshes[partId];
m_partPreviewMeshes[partId] = nullptr;
m_generatedPreviewPartIds.insert(partId);
std::vector<QVector3D> partPreviewVertices;
QColor partPreviewColor = partColor;
if (nullptr != mesh) {
partCache.mesh = new nodemesh::Combiner::Mesh(*mesh);
mesh->fetch(partPreviewVertices, partCache.previewTriangles);
partCache.isSucceed = true;
}
if (partCache.previewTriangles.empty()) {
partPreviewVertices = partCache.vertices;
nodemesh::triangulate(partPreviewVertices, partCache.faces, partCache.previewTriangles);
partPreviewColor = Qt::red;
partCache.isSucceed = false;
}
nodemesh::trim(&partPreviewVertices, true);
for (auto &it: partPreviewVertices) {
it *= 2.0;
}
std::vector<QVector3D> partPreviewTriangleNormals;
for (const auto &face: partCache.previewTriangles) {
partPreviewTriangleNormals.push_back(QVector3D::normal(
partPreviewVertices[face[0]],
partPreviewVertices[face[1]],
partPreviewVertices[face[2]]
));
}
std::vector<std::vector<QVector3D>> partPreviewTriangleVertexNormals;
generateSmoothTriangleVertexNormals(partPreviewVertices,
partCache.previewTriangles,
partPreviewTriangleNormals,
&partPreviewTriangleVertexNormals);
if (!partCache.previewTriangles.empty()) {
if (target == PartTarget::CutFace)
partPreviewColor = Theme::red;
m_partPreviewMeshes[partId] = new MeshLoader(partPreviewVertices,
partCache.previewTriangles,
partPreviewTriangleVertexNormals,
partPreviewColor);
}
delete builder;
delete modifier;
if (mesh && mesh->isNull()) {
delete mesh;
mesh = nullptr;
}
if (isDisabled) {
delete mesh;
mesh = nullptr;
}
if (target != PartTarget::Model) {
delete mesh;
mesh = nullptr;
}
if (hasMeshError && target == PartTarget::Model) {
*hasError = true;
//m_isSucceed = false;
}
return mesh;
}
const std::map<QString, QString> *MeshGenerator::findComponent(const QString &componentIdString)
{
const std::map<QString, QString> *component = &m_snapshot->rootComponent;
if (componentIdString != QUuid().toString()) {
auto findComponent = m_snapshot->components.find(componentIdString);
if (findComponent == m_snapshot->components.end()) {
qDebug() << "Component not found:" << componentIdString;
return nullptr;
}
return &findComponent->second;
}
return component;
}
CombineMode MeshGenerator::componentCombineMode(const std::map<QString, QString> *component)
{
if (nullptr == component)
return CombineMode::Normal;
CombineMode combineMode = CombineModeFromString(valueOfKeyInMapOrEmpty(*component, "combineMode").toUtf8().constData());
if (combineMode == CombineMode::Normal) {
if (isTrueValueString(valueOfKeyInMapOrEmpty(*component, "inverse")))
combineMode = CombineMode::Inversion;
}
return combineMode;
}
QString MeshGenerator::componentColorName(const std::map<QString, QString> *component)
{
if (nullptr == component)
return QString();
QString linkDataType = valueOfKeyInMapOrEmpty(*component, "linkDataType");
if ("partId" == linkDataType) {
QString partIdString = valueOfKeyInMapOrEmpty(*component, "linkData");
auto findPart = m_snapshot->parts.find(partIdString);
if (findPart == m_snapshot->parts.end()) {
qDebug() << "Find part failed:" << partIdString;
return QString();
}
auto &part = findPart->second;
QString colorSolubility = valueOfKeyInMapOrEmpty(part, "colorSolubility");
if (!colorSolubility.isEmpty()) {
return QString("+");
}
QString colorName = valueOfKeyInMapOrEmpty(part, "color");
if (colorName.isEmpty())
return QString("-");
return colorName;
}
return QString();
}
nodemesh::Combiner::Mesh *MeshGenerator::combineComponentMesh(const QString &componentIdString, CombineMode *combineMode)
{
nodemesh::Combiner::Mesh *mesh = nullptr;
QUuid componentId;
const std::map<QString, QString> *component = &m_snapshot->rootComponent;
if (componentIdString != QUuid().toString()) {
componentId = QUuid(componentIdString);
auto findComponent = m_snapshot->components.find(componentIdString);
if (findComponent == m_snapshot->components.end()) {
qDebug() << "Component not found:" << componentIdString;
return nullptr;
}
component = &findComponent->second;
}
*combineMode = componentCombineMode(component);
auto &componentCache = m_cacheContext->components[componentIdString];
if (m_cacheEnabled) {
if (m_dirtyComponentIds.find(componentIdString) == m_dirtyComponentIds.end()) {
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if (nullptr != componentCache.mesh)
return new nodemesh::Combiner::Mesh(*componentCache.mesh);
}
}
componentCache.sharedQuadEdges.clear();
componentCache.noneSeamVertices.clear();
componentCache.outcomeNodes.clear();
componentCache.outcomeNodeVertices.clear();
componentCache.outcomePaintMaps.clear();
delete componentCache.mesh;
componentCache.mesh = nullptr;
QString linkDataType = valueOfKeyInMapOrEmpty(*component, "linkDataType");
if ("partId" == linkDataType) {
QString partIdString = valueOfKeyInMapOrEmpty(*component, "linkData");
bool hasError = false;
mesh = combinePartMesh(partIdString, &hasError);
if (hasError) {
delete mesh;
hasError = false;
qDebug() << "Try combine part again without adding intermediate nodes";
mesh = combinePartMesh(partIdString, &hasError, false);
if (hasError) {
m_isSucceed = false;
}
}
const auto &partCache = m_cacheContext->parts[partIdString];
for (const auto &vertex: partCache.vertices)
componentCache.noneSeamVertices.insert(vertex);
collectSharedQuadEdges(partCache.vertices, partCache.faces, &componentCache.sharedQuadEdges);
for (const auto &it: partCache.outcomeNodes)
componentCache.outcomeNodes.push_back(it);
for (const auto &it: partCache.outcomeNodeVertices)
componentCache.outcomeNodeVertices.push_back(it);
componentCache.outcomePaintMaps.push_back(partCache.outcomePaintMap);
} else {
std::vector<std::pair<CombineMode, std::vector<std::pair<QString, QString>>>> combineGroups;
// Firstly, group by combine mode
int currentGroupIndex = -1;
auto lastCombineMode = CombineMode::Count;
bool foundColorSolubilitySetting = false;
for (const auto &childIdString: valueOfKeyInMapOrEmpty(*component, "children").split(",")) {
if (childIdString.isEmpty())
continue;
const auto &child = findComponent(childIdString);
QString colorName = componentColorName(child);
if (colorName == "+") {
foundColorSolubilitySetting = true;
}
auto combineMode = componentCombineMode(child);
if (lastCombineMode != combineMode || lastCombineMode == CombineMode::Inversion) {
qDebug() << "New group[" << currentGroupIndex << "] for combine mode[" << CombineModeToString(combineMode) << "]";
combineGroups.push_back({combineMode, {}});
++currentGroupIndex;
lastCombineMode = combineMode;
}
if (-1 == currentGroupIndex) {
qDebug() << "Should not happen: -1 == currentGroupIndex";
continue;
}
combineGroups[currentGroupIndex].second.push_back({childIdString, colorName});
}
// Secondly, sub group by color
std::vector<std::tuple<nodemesh::Combiner::Mesh *, CombineMode, QString>> groupMeshes;
for (const auto &group: combineGroups) {
std::set<size_t> used;
std::vector<std::vector<QString>> componentIdStrings;
int currentSubGroupIndex = -1;
auto lastColorName = QString();
for (size_t i = 0; i < group.second.size(); ++i) {
if (used.find(i) != used.end())
continue;
const auto &colorName = group.second[i].second;
if (lastColorName != colorName || lastColorName.isEmpty()) {
//qDebug() << "New sub group[" << currentSubGroupIndex << "] for color[" << colorName << "]";
componentIdStrings.push_back({});
++currentSubGroupIndex;
lastColorName = colorName;
}
if (-1 == currentSubGroupIndex) {
qDebug() << "Should not happen: -1 == currentSubGroupIndex";
continue;
}
used.insert(i);
componentIdStrings[currentSubGroupIndex].push_back(group.second[i].first);
if (colorName.isEmpty())
continue;
for (size_t j = i + 1; j < group.second.size(); ++j) {
if (used.find(j) != used.end())
continue;
const auto &otherColorName = group.second[j].second;
if (otherColorName.isEmpty())
continue;
if (otherColorName != colorName)
continue;
used.insert(j);
componentIdStrings[currentSubGroupIndex].push_back(group.second[j].first);
}
}
std::vector<std::tuple<nodemesh::Combiner::Mesh *, CombineMode, QString>> multipleMeshes;
QStringList subGroupMeshIdStringList;
for (const auto &it: componentIdStrings) {
QStringList componentChildGroupIdStringList;
for (const auto &componentChildGroupIdString: it)
componentChildGroupIdStringList += componentChildGroupIdString;
nodemesh::Combiner::Mesh *childMesh = combineComponentChildGroupMesh(it, componentCache);
if (nullptr == childMesh)
continue;
if (childMesh->isNull()) {
delete childMesh;
continue;
}
QString componentChildGroupIdStringListString = componentChildGroupIdStringList.join("|");
subGroupMeshIdStringList += componentChildGroupIdStringListString;
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multipleMeshes.push_back(std::make_tuple(childMesh, CombineMode::Normal, componentChildGroupIdStringListString));
}
nodemesh::Combiner::Mesh *subGroupMesh = combineMultipleMeshes(multipleMeshes, foundColorSolubilitySetting);
if (nullptr == subGroupMesh)
continue;
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groupMeshes.push_back(std::make_tuple(subGroupMesh, group.first, subGroupMeshIdStringList.join("&")));
}
mesh = combineMultipleMeshes(groupMeshes, false);
}
if (nullptr != mesh)
componentCache.mesh = new nodemesh::Combiner::Mesh(*mesh);
if (nullptr != mesh && mesh->isNull()) {
delete mesh;
mesh = nullptr;
}
return mesh;
}
nodemesh::Combiner::Mesh *MeshGenerator::combineMultipleMeshes(const std::vector<std::tuple<nodemesh::Combiner::Mesh *, CombineMode, QString>> &multipleMeshes, bool recombine)
{
nodemesh::Combiner::Mesh *mesh = nullptr;
QString meshIdStrings;
for (const auto &it: multipleMeshes) {
const auto &childCombineMode = std::get<1>(it);
nodemesh::Combiner::Mesh *subMesh = std::get<0>(it);
const QString &subMeshIdString = std::get<2>(it);
//qDebug() << "Combine mode:" << CombineModeToString(childCombineMode);
if (nullptr == subMesh) {
qDebug() << "Child mesh is null";
continue;
}
if (subMesh->isNull()) {
qDebug() << "Child mesh is uncombinable";
delete subMesh;
continue;
}
if (nullptr == mesh) {
mesh = subMesh;
meshIdStrings = subMeshIdString;
} else {
auto combinerMethod = childCombineMode == CombineMode::Inversion ?
nodemesh::Combiner::Method::Diff : nodemesh::Combiner::Method::Union;
auto combinerMethodString = combinerMethod == nodemesh::Combiner::Method::Union ?
"+" : "-";
meshIdStrings += combinerMethodString + subMeshIdString;
if (recombine)
meshIdStrings += "!";
nodemesh::Combiner::Mesh *newMesh = nullptr;
auto findCached = m_cacheContext->cachedCombination.find(meshIdStrings);
if (findCached != m_cacheContext->cachedCombination.end()) {
if (nullptr != findCached->second) {
//qDebug() << "Use cached combination:" << meshIdStrings;
newMesh = new nodemesh::Combiner::Mesh(*findCached->second);
}
} else {
newMesh = combineTwoMeshes(*mesh,
*subMesh,
combinerMethod,
recombine);
delete subMesh;
if (nullptr != newMesh)
m_cacheContext->cachedCombination.insert({meshIdStrings, new nodemesh::Combiner::Mesh(*newMesh)});
else
m_cacheContext->cachedCombination.insert({meshIdStrings, nullptr});
//qDebug() << "Add cached combination:" << meshIdStrings;
}
if (newMesh && !newMesh->isNull()) {
delete mesh;
mesh = newMesh;
} else {
m_isSucceed = false;
qDebug() << "Mesh combine failed";
delete newMesh;
}
}
}
if (nullptr != mesh && mesh->isNull()) {
delete mesh;
mesh = nullptr;
}
return mesh;
}
nodemesh::Combiner::Mesh *MeshGenerator::combineComponentChildGroupMesh(const std::vector<QString> &componentIdStrings, GeneratedComponent &componentCache)
{
std::vector<std::tuple<nodemesh::Combiner::Mesh *, CombineMode, QString>> multipleMeshes;
for (const auto &childIdString: componentIdStrings) {
CombineMode childCombineMode = CombineMode::Normal;
nodemesh::Combiner::Mesh *subMesh = combineComponentMesh(childIdString, &childCombineMode);
if (CombineMode::Uncombined == childCombineMode) {
delete subMesh;
continue;
}
const auto &childComponentCache = m_cacheContext->components[childIdString];
for (const auto &vertex: childComponentCache.noneSeamVertices)
componentCache.noneSeamVertices.insert(vertex);
for (const auto &it: childComponentCache.sharedQuadEdges)
componentCache.sharedQuadEdges.insert(it);
for (const auto &it: childComponentCache.outcomeNodes)
componentCache.outcomeNodes.push_back(it);
for (const auto &it: childComponentCache.outcomeNodeVertices)
componentCache.outcomeNodeVertices.push_back(it);
for (const auto &it: childComponentCache.outcomePaintMaps)
componentCache.outcomePaintMaps.push_back(it);
if (nullptr == subMesh || subMesh->isNull()) {
delete subMesh;
continue;
}
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multipleMeshes.push_back(std::make_tuple(subMesh, childCombineMode, childIdString));
}
return combineMultipleMeshes(multipleMeshes);
}
nodemesh::Combiner::Mesh *MeshGenerator::combineTwoMeshes(const nodemesh::Combiner::Mesh &first, const nodemesh::Combiner::Mesh &second,
nodemesh::Combiner::Method method,
bool recombine)
{
if (first.isNull() || second.isNull())
return nullptr;
std::vector<std::pair<nodemesh::Combiner::Source, size_t>> combinedVerticesSources;
nodemesh::Combiner::Mesh *newMesh = nodemesh::Combiner::combine(first,
second,
method,
&combinedVerticesSources);
if (nullptr == newMesh)
return nullptr;
if (!newMesh->isNull() && recombine) {
nodemesh::Recombiner recombiner;
std::vector<QVector3D> combinedVertices;
std::vector<std::vector<size_t>> combinedFaces;
newMesh->fetch(combinedVertices, combinedFaces);
recombiner.setVertices(&combinedVertices, &combinedVerticesSources);
recombiner.setFaces(&combinedFaces);
if (recombiner.recombine()) {
if (nodemesh::isManifold(recombiner.regeneratedFaces())) {
nodemesh::Combiner::Mesh *reMesh = new nodemesh::Combiner::Mesh(recombiner.regeneratedVertices(), recombiner.regeneratedFaces(), false);
if (!reMesh->isNull() && !reMesh->isSelfIntersected()) {
delete newMesh;
newMesh = reMesh;
} else {
delete reMesh;
}
}
}
}
return newMesh;
}
void MeshGenerator::makeXmirror(const std::vector<QVector3D> &sourceVertices, const std::vector<std::vector<size_t>> &sourceFaces,
std::vector<QVector3D> *destVertices, std::vector<std::vector<size_t>> *destFaces)
{
for (const auto &mirrorFrom: sourceVertices) {
destVertices->push_back(QVector3D(-mirrorFrom.x(), mirrorFrom.y(), mirrorFrom.z()));
}
std::vector<std::vector<size_t>> newFaces;
for (const auto &mirrorFrom: sourceFaces) {
auto newFace = mirrorFrom;
std::reverse(newFace.begin(), newFace.end());
destFaces->push_back(newFace);
}
}
void MeshGenerator::collectSharedQuadEdges(const std::vector<QVector3D> &vertices, const std::vector<std::vector<size_t>> &faces,
std::set<std::pair<nodemesh::PositionKey, nodemesh::PositionKey>> *sharedQuadEdges)
{
for (const auto &face: faces) {
if (face.size() != 4)
continue;
sharedQuadEdges->insert({
nodemesh::PositionKey(vertices[face[0]]),
nodemesh::PositionKey(vertices[face[2]])
});
sharedQuadEdges->insert({
nodemesh::PositionKey(vertices[face[1]]),
nodemesh::PositionKey(vertices[face[3]])
});
}
}
void MeshGenerator::setGeneratedCacheContext(GeneratedCacheContext *cacheContext)
{
m_cacheContext = cacheContext;
}
void MeshGenerator::setSmoothShadingThresholdAngleDegrees(float degrees)
{
m_smoothShadingThresholdAngleDegrees = degrees;
}
void MeshGenerator::process()
{
generate();
this->moveToThread(QGuiApplication::instance()->thread());
emit finished();
}
void MeshGenerator::generate()
{
if (nullptr == m_snapshot)
return;
m_isSucceed = true;
QElapsedTimer countTimeConsumed;
countTimeConsumed.start();
m_outcome = new Outcome;
m_outcome->meshId = m_id;
//m_cutFaceTransforms = new std::map<QUuid, nodemesh::Builder::CutFaceTransform>;
//m_nodesCutFaces = new std::map<QUuid, std::map<QString, QVector2D>>;
bool needDeleteCacheContext = false;
if (nullptr == m_cacheContext) {
m_cacheContext = new GeneratedCacheContext;
needDeleteCacheContext = true;
} else {
m_cacheEnabled = true;
for (auto it = m_cacheContext->parts.begin(); it != m_cacheContext->parts.end(); ) {
if (m_snapshot->parts.find(it->first) == m_snapshot->parts.end()) {
auto mirrorFrom = m_cacheContext->partMirrorIdMap.find(it->first);
if (mirrorFrom != m_cacheContext->partMirrorIdMap.end()) {
if (m_snapshot->parts.find(mirrorFrom->second) != m_snapshot->parts.end()) {
it++;
continue;
}
m_cacheContext->partMirrorIdMap.erase(mirrorFrom);
}
it = m_cacheContext->parts.erase(it);
continue;
}
it++;
}
for (auto it = m_cacheContext->components.begin(); it != m_cacheContext->components.end(); ) {
if (m_snapshot->components.find(it->first) == m_snapshot->components.end()) {
for (auto combinationIt = m_cacheContext->cachedCombination.begin(); combinationIt != m_cacheContext->cachedCombination.end(); ) {
if (-1 != combinationIt->first.indexOf(it->first)) {
//qDebug() << "Removed cached combination:" << combinationIt->first;
delete combinationIt->second;
combinationIt = m_cacheContext->cachedCombination.erase(combinationIt);
continue;
}
combinationIt++;
}
it = m_cacheContext->components.erase(it);
continue;
}
it++;
}
}
collectParts();
checkDirtyFlags();
for (const auto &dirtyComponentId: m_dirtyComponentIds) {
for (auto combinationIt = m_cacheContext->cachedCombination.begin(); combinationIt != m_cacheContext->cachedCombination.end(); ) {
if (-1 != combinationIt->first.indexOf(dirtyComponentId)) {
//qDebug() << "Removed dirty cached combination:" << combinationIt->first;
delete combinationIt->second;
combinationIt = m_cacheContext->cachedCombination.erase(combinationIt);
continue;
}
combinationIt++;
}
}
m_dirtyComponentIds.insert(QUuid().toString());
m_mainProfileMiddleX = valueOfKeyInMapOrEmpty(m_snapshot->canvas, "originX").toFloat();
m_mainProfileMiddleY = valueOfKeyInMapOrEmpty(m_snapshot->canvas, "originY").toFloat();
m_sideProfileMiddleX = valueOfKeyInMapOrEmpty(m_snapshot->canvas, "originZ").toFloat();
CombineMode combineMode;
auto combinedMesh = combineComponentMesh(QUuid().toString(), &combineMode);
const auto &componentCache = m_cacheContext->components[QUuid().toString()];
std::vector<QVector3D> combinedVertices;
std::vector<std::vector<size_t>> combinedFaces;
if (nullptr != combinedMesh) {
combinedMesh->fetch(combinedVertices, combinedFaces);
size_t totalAffectedNum = 0;
size_t affectedNum = 0;
do {
std::vector<QVector3D> weldedVertices;
std::vector<std::vector<size_t>> weldedFaces;
affectedNum = nodemesh::weldSeam(combinedVertices, combinedFaces,
0.025, componentCache.noneSeamVertices,
weldedVertices, weldedFaces);
combinedVertices = weldedVertices;
combinedFaces = weldedFaces;
totalAffectedNum += affectedNum;
} while (affectedNum > 0);
qDebug() << "Total weld affected triangles:" << totalAffectedNum;
recoverQuads(combinedVertices, combinedFaces, componentCache.sharedQuadEdges, m_outcome->triangleAndQuads);
m_outcome->nodes = componentCache.outcomeNodes;
m_outcome->nodeVertices = componentCache.outcomeNodeVertices;
m_outcome->vertices = combinedVertices;
m_outcome->triangles = combinedFaces;
m_outcome->paintMaps = componentCache.outcomePaintMaps;
}
// Recursively check uncombined components
collectUncombinedComponent(QUuid().toString());
auto postprocessOutcome = [this](Outcome *outcome) {
std::vector<QVector3D> combinedFacesNormals;
for (const auto &face: outcome->triangles) {
combinedFacesNormals.push_back(QVector3D::normal(
outcome->vertices[face[0]],
outcome->vertices[face[1]],
outcome->vertices[face[2]]
));
}
outcome->triangleNormals = combinedFacesNormals;
std::vector<std::pair<QUuid, QUuid>> sourceNodes;
triangleSourceNodeResolve(*outcome, sourceNodes);
outcome->setTriangleSourceNodes(sourceNodes);
std::map<std::pair<QUuid, QUuid>, QColor> sourceNodeToColorMap;
for (const auto &node: outcome->nodes)
sourceNodeToColorMap.insert({{node.partId, node.nodeId}, node.color});
outcome->triangleColors.resize(outcome->triangles.size(), Qt::white);
const std::vector<std::pair<QUuid, QUuid>> *triangleSourceNodes = outcome->triangleSourceNodes();
if (nullptr != triangleSourceNodes) {
for (size_t triangleIndex = 0; triangleIndex < outcome->triangles.size(); triangleIndex++) {
const auto &source = (*triangleSourceNodes)[triangleIndex];
outcome->triangleColors[triangleIndex] = sourceNodeToColorMap[source];
}
}
std::vector<std::vector<QVector3D>> triangleVertexNormals;
generateSmoothTriangleVertexNormals(outcome->vertices,
outcome->triangles,
outcome->triangleNormals,
&triangleVertexNormals);
outcome->setTriangleVertexNormals(triangleVertexNormals);
};
postprocessOutcome(m_outcome);
m_resultMesh = new MeshLoader(*m_outcome);
delete combinedMesh;
if (needDeleteCacheContext) {
delete m_cacheContext;
m_cacheContext = nullptr;
}
qDebug() << "The mesh generation took" << countTimeConsumed.elapsed() << "milliseconds";
}
void MeshGenerator::collectUncombinedComponent(const QString &componentIdString)
{
const auto &component = findComponent(componentIdString);
if (CombineMode::Uncombined == componentCombineMode(component)) {
const auto &componentCache = m_cacheContext->components[componentIdString];
if (nullptr == componentCache.mesh || componentCache.mesh->isNull()) {
qDebug() << "Uncombined mesh is null";
return;
}
m_outcome->nodes.insert(m_outcome->nodes.end(), componentCache.outcomeNodes.begin(), componentCache.outcomeNodes.end());
m_outcome->nodeVertices.insert(m_outcome->nodeVertices.end(), componentCache.outcomeNodeVertices.begin(), componentCache.outcomeNodeVertices.end());
m_outcome->paintMaps.insert(m_outcome->paintMaps.end(), componentCache.outcomePaintMaps.begin(), componentCache.outcomePaintMaps.end());
std::vector<QVector3D> uncombinedVertices;
std::vector<std::vector<size_t>> uncombinedFaces;
componentCache.mesh->fetch(uncombinedVertices, uncombinedFaces);
std::vector<std::vector<size_t>> uncombinedTriangleAndQuads;
recoverQuads(uncombinedVertices, uncombinedFaces, componentCache.sharedQuadEdges, uncombinedTriangleAndQuads);
auto vertexStartIndex = m_outcome->vertices.size();
auto updateVertexIndices = [=](std::vector<std::vector<size_t>> &faces) {
for (auto &it: faces) {
for (auto &subIt: it)
subIt += vertexStartIndex;
}
};
updateVertexIndices(uncombinedFaces);
updateVertexIndices(uncombinedTriangleAndQuads);
m_outcome->vertices.insert(m_outcome->vertices.end(), uncombinedVertices.begin(), uncombinedVertices.end());
m_outcome->triangles.insert(m_outcome->triangles.end(), uncombinedFaces.begin(), uncombinedFaces.end());
m_outcome->triangleAndQuads.insert(m_outcome->triangleAndQuads.end(), uncombinedTriangleAndQuads.begin(), uncombinedTriangleAndQuads.end());
return;
}
for (const auto &childIdString: valueOfKeyInMapOrEmpty(*component, "children").split(",")) {
if (childIdString.isEmpty())
continue;
collectUncombinedComponent(childIdString);
}
}
void MeshGenerator::generateSmoothTriangleVertexNormals(const std::vector<QVector3D> &vertices, const std::vector<std::vector<size_t>> &triangles,
const std::vector<QVector3D> &triangleNormals,
std::vector<std::vector<QVector3D>> *triangleVertexNormals)
{
std::vector<QVector3D> smoothNormals;
nodemesh::angleSmooth(vertices,
triangles,
triangleNormals,
m_smoothShadingThresholdAngleDegrees,
smoothNormals);
triangleVertexNormals->resize(triangles.size(), {
QVector3D(), QVector3D(), QVector3D()
});
size_t index = 0;
for (size_t i = 0; i < triangles.size(); ++i) {
auto &normals = (*triangleVertexNormals)[i];
for (size_t j = 0; j < 3; ++j) {
if (index < smoothNormals.size())
normals[j] = smoothNormals[index];
++index;
}
}
}
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void MeshGenerator::setDefaultPartColor(const QColor &color)
{
m_defaultPartColor = color;
}