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godot/thirdparty/thekla_atlas/nvmesh/param/Atlas.cpp

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// Copyright NVIDIA Corporation 2006 -- Ignacio Castano <icastano@nvidia.com>
#include "nvmesh.h" // pch
#include "Atlas.h"
#include "Util.h"
#include "AtlasBuilder.h"
#include "AtlasPacker.h"
#include "SingleFaceMap.h"
#include "OrthogonalProjectionMap.h"
#include "LeastSquaresConformalMap.h"
#include "ParameterizationQuality.h"
//#include "nvmesh/export/MeshExportOBJ.h"
#include "nvmesh/halfedge/Mesh.h"
#include "nvmesh/halfedge/Face.h"
#include "nvmesh/halfedge/Vertex.h"
#include "nvmesh/MeshBuilder.h"
#include "nvmesh/MeshTopology.h"
#include "nvmesh/param/Util.h"
#include "nvmesh/geometry/Measurements.h"
#include "nvmath/Vector.inl"
#include "nvmath/Fitting.h"
#include "nvmath/Box.inl"
#include "nvmath/ProximityGrid.h"
#include "nvmath/Morton.h"
#include "nvcore/StrLib.h"
#include "nvcore/Array.inl"
#include "nvcore/HashMap.inl"
using namespace nv;
/// Ctor.
Atlas::Atlas()
{
failed=false;
}
// Dtor.
Atlas::~Atlas()
{
deleteAll(m_meshChartsArray);
}
uint Atlas::chartCount() const
{
uint count = 0;
foreach(c, m_meshChartsArray) {
count += m_meshChartsArray[c]->chartCount();
}
return count;
}
const Chart * Atlas::chartAt(uint i) const
{
foreach(c, m_meshChartsArray) {
uint count = m_meshChartsArray[c]->chartCount();
if (i < count) {
return m_meshChartsArray[c]->chartAt(i);
}
i -= count;
}
return NULL;
}
Chart * Atlas::chartAt(uint i)
{
foreach(c, m_meshChartsArray) {
uint count = m_meshChartsArray[c]->chartCount();
if (i < count) {
return m_meshChartsArray[c]->chartAt(i);
}
i -= count;
}
return NULL;
}
// Extract the charts and add to this atlas.
void Atlas::addMeshCharts(MeshCharts * meshCharts)
{
m_meshChartsArray.append(meshCharts);
}
void Atlas::extractCharts(const HalfEdge::Mesh * mesh)
{
MeshCharts * meshCharts = new MeshCharts(mesh);
meshCharts->extractCharts();
addMeshCharts(meshCharts);
}
void Atlas::computeCharts(const HalfEdge::Mesh * mesh, const SegmentationSettings & settings, const Array<uint> & unchartedMaterialArray)
{
failed=false;
MeshCharts * meshCharts = new MeshCharts(mesh);
meshCharts->computeCharts(settings, unchartedMaterialArray);
addMeshCharts(meshCharts);
}
#if 0
/// Compute a seamless texture atlas.
bool Atlas::computeSeamlessTextureAtlas(bool groupFaces/*= true*/, bool scaleTiles/*= false*/, uint w/*= 1024*/, uint h/* = 1024*/)
{
// Implement seamless texture atlas similar to what ZBrush does. See also:
// "Meshed Atlases for Real-Time Procedural Solid Texturing"
// http://graphics.cs.uiuc.edu/~jch/papers/rtpst.pdf
// Other methods that we should experiment with:
//
// Seamless Texture Atlases:
// http://www.cs.jhu.edu/~bpurnomo/STA/index.html
//
// Rectangular Multi-Chart Geometry Images:
// http://graphics.cs.uiuc.edu/~jch/papers/rmcgi.pdf
//
// Discrete differential geometry also provide a way of constructing
// seamless quadrangulations as shown in:
// http://www.geometry.caltech.edu/pubs/TACD06.pdf
//
#pragma message(NV_FILE_LINE "TODO: Implement seamless texture atlas.")
if (groupFaces)
{
// @@ TODO.
}
else
{
// @@ Create one atlas per face.
}
if (scaleTiles)
{
// @@ TODO
}
/*
if (!isQuadMesh(m_mesh)) {
// Only handle quads for now.
return false;
}
// Each face is a chart.
const uint faceCount = m_mesh->faceCount();
m_chartArray.resize(faceCount);
for(uint f = 0; f < faceCount; f++) {
m_chartArray[f].faceArray.clear();
m_chartArray[f].faceArray.append(f);
}
// Map each face to a separate square.
// Determine face layout according to width and height.
float aspect = float(m_width) / float(m_height);
uint i = 2;
uint total = (m_width / (i+1)) * (m_height / (i+1));
while(total > faceCount) {
i *= 2;
total = (m_width / (i+1)) * (m_height / (i+1));
}
uint tileSize = i / 2;
int x = 0;
int y = 0;
m_result = new HalfEdge::Mesh();
// Once you have that it's just matter of traversing the faces.
for(uint f = 0; f < faceCount; f++) {
// Compute texture coordinates.
Vector2 tex[4];
tex[0] = Vector2(float(x), float(y));
tex[1] = Vector2(float(x+tileSize), float(y));
tex[2] = Vector2(float(x+tileSize), float(y+tileSize));
tex[3] = Vector2(float(x), float(y+tileSize));
Array<uint> indexArray(4);
const HalfEdge::Face * face = m_mesh->faceAt(f);
int i = 0;
for(HalfEdge::Face::ConstEdgeIterator it(face->edges()); !it.isDone(); it.advance(), i++) {
const HalfEdge::Edge * edge = it.current();
const HalfEdge::Vertex * vertex = edge->from();
HalfEdge::Vertex * newVertex = m_result->addVertex(vertex->id(), vertex->pos());
newVertex->setTex(Vector3(tex[i], 0));
newVertex->setNor(vertex->nor());
indexArray.append(m_result->vertexCount() + 1);
}
m_result->addFace(indexArray);
// Move to the next tile.
x += tileSize + 1;
if (x + tileSize > m_width) {
x = 0;
y += tileSize + 1;
}
}
*/
return false;
}
#endif
void Atlas::parameterizeCharts()
{
foreach(i, m_meshChartsArray) {
m_meshChartsArray[i]->parameterizeCharts();
}
}
float Atlas::packCharts(int quality, float texelsPerUnit, bool blockAlign, bool conservative)
{
AtlasPacker packer(this);
packer.packCharts(quality, texelsPerUnit, blockAlign, conservative);
if (hasFailed())
return 0;
return packer.computeAtlasUtilization();
}
/// Ctor.
MeshCharts::MeshCharts(const HalfEdge::Mesh * mesh) : m_mesh(mesh)
{
}
// Dtor.
MeshCharts::~MeshCharts()
{
deleteAll(m_chartArray);
}
void MeshCharts::extractCharts()
{
const uint faceCount = m_mesh->faceCount();
int first = 0;
Array<uint> queue(faceCount);
BitArray bitFlags(faceCount);
bitFlags.clearAll();
for (uint f = 0; f < faceCount; f++)
{
if (bitFlags.bitAt(f) == false)
{
// Start new patch. Reset queue.
first = 0;
queue.clear();
queue.append(f);
bitFlags.setBitAt(f);
while (first != queue.count())
{
const HalfEdge::Face * face = m_mesh->faceAt(queue[first]);
// Visit face neighbors of queue[first]
for (HalfEdge::Face::ConstEdgeIterator it(face->edges()); !it.isDone(); it.advance())
{
const HalfEdge::Edge * edge = it.current();
nvDebugCheck(edge->pair != NULL);
if (!edge->isBoundary() && /*!edge->isSeam()*/
//!(edge->from()->tex() != edge->pair()->to()->tex() || edge->to()->tex() != edge->pair()->from()->tex()))
!(edge->from() != edge->pair->to() || edge->to() != edge->pair->from())) // Preserve existing seams (not just texture seams).
{
const HalfEdge::Face * neighborFace = edge->pair->face;
nvDebugCheck(neighborFace != NULL);
if (bitFlags.bitAt(neighborFace->id) == false)
{
queue.append(neighborFace->id);
bitFlags.setBitAt(neighborFace->id);
}
}
}
first++;
}
Chart * chart = new Chart();
chart->build(m_mesh, queue);
m_chartArray.append(chart);
}
}
}
/*
LSCM:
- identify sharp features using local dihedral angles.
- identify seed faces farthest from sharp features.
- grow charts from these seeds.
MCGIM:
- phase 1: chart growth
- grow all charts simultaneously using dijkstra search on the dual graph of the mesh.
- graph edges are weighted based on planarity metric.
- metric uses distance to global chart normal.
- terminate when all faces have been assigned.
- phase 2: seed computation:
- place new seed of the chart at the most interior face.
- most interior is evaluated using distance metric only.
- method repeates the two phases, until the location of the seeds does not change.
- cycles are detected by recording all the previous seeds and chartification terminates.
D-Charts:
- Uniaxial conic metric:
- N_c = axis of the generalized cone that best fits the chart. (cone can a be cylinder or a plane).
- omega_c = angle between the face normals and the axis.
- Fitting error between chart C and tringle t: F(c,t) = (N_c*n_t - cos(omega_c))^2
- Compactness metrics:
- Roundness:
- C(c,t) = pi * D(S_c,t)^2 / A_c
- S_c = chart seed.
- D(S_c,t) = length of the shortest path inside the chart betwen S_c and t.
- A_c = chart area.
- Straightness:
- P(c,t) = l_out(c,t) / l_in(c,t)
- l_out(c,t) = lenght of the edges not shared between C and t.
- l_in(c,t) = lenght of the edges shared between C and t.
- Combined metric:
- Cost(c,t) = F(c,t)^alpha + C(c,t)^beta + P(c,t)^gamma
- alpha = 1, beta = 0.7, gamma = 0.5
Our basic approach:
- Just one iteration of k-means?
- Avoid dijkstra by greedily growing charts until a threshold is met. Increase threshold and repeat until no faces left.
- If distortion metric is too high, split chart, add two seeds.
- If chart size is low, try removing chart.
Postprocess:
- If topology is not disk:
- Fill holes, if new faces fit proxy.
- Find best cut, otherwise.
- After parameterization:
- If boundary self-intersects:
- cut chart along the closest two diametral boundary vertices, repeat parametrization.
- what if the overlap is on an appendix? How do we find that out and cut appropiately?
- emphasize roundness metrics to prevent those cases.
- If interior self-overlaps: preserve boundary parameterization and use mean-value map.
*/
SegmentationSettings::SegmentationSettings()
{
// Charts have no area or boundary limits right now.
maxChartArea = NV_FLOAT_MAX;
maxBoundaryLength = NV_FLOAT_MAX;
proxyFitMetricWeight = 1.0f;
roundnessMetricWeight = 0.1f;
straightnessMetricWeight = 0.25f;
normalSeamMetricWeight = 1.0f;
textureSeamMetricWeight = 0.1f;
}
void MeshCharts::computeCharts(const SegmentationSettings & settings, const Array<uint> & unchartedMaterialArray)
{
Chart * vertexMap = NULL;
if (unchartedMaterialArray.count() != 0) {
vertexMap = new Chart();
vertexMap->buildVertexMap(m_mesh, unchartedMaterialArray);
if (vertexMap->faceCount() == 0) {
delete vertexMap;
vertexMap = NULL;
}
}
AtlasBuilder builder(m_mesh);
if (vertexMap != NULL) {
// Mark faces that do not need to be charted.
builder.markUnchartedFaces(vertexMap->faceArray());
m_chartArray.append(vertexMap);
}
if (builder.facesLeft != 0) {
// Tweak these values:
const float maxThreshold = 2;
const uint growFaceCount = 32;
const uint maxIterations = 4;
builder.settings = settings;
//builder.settings.proxyFitMetricWeight *= 0.75; // relax proxy fit weight during initial seed placement.
//builder.settings.roundnessMetricWeight = 0;
//builder.settings.straightnessMetricWeight = 0;
// This seems a reasonable estimate.
uint maxSeedCount = max(6U, builder.facesLeft);
// Create initial charts greedely.
nvDebug("### Placing seeds\n");
builder.placeSeeds(maxThreshold, maxSeedCount);
nvDebug("### Placed %d seeds (max = %d)\n", builder.chartCount(), maxSeedCount);
builder.updateProxies();
builder.mergeCharts();
#if 1
nvDebug("### Relocating seeds\n");
builder.relocateSeeds();
nvDebug("### Reset charts\n");
builder.resetCharts();
if (vertexMap != NULL) {
builder.markUnchartedFaces(vertexMap->faceArray());
}
builder.settings = settings;
nvDebug("### Growing charts\n");
// Restart process growing charts in parallel.
uint iteration = 0;
while (true)
{
if (!builder.growCharts(maxThreshold, growFaceCount))
{
nvDebug("### Can't grow anymore\n");
// If charts cannot grow more: fill holes, merge charts, relocate seeds and start new iteration.
nvDebug("### Filling holes\n");
builder.fillHoles(maxThreshold);
nvDebug("### Using %d charts now\n", builder.chartCount());
builder.updateProxies();
nvDebug("### Merging charts\n");
builder.mergeCharts();
nvDebug("### Using %d charts now\n", builder.chartCount());
nvDebug("### Reseeding\n");
if (!builder.relocateSeeds())
{
nvDebug("### Cannot relocate seeds anymore\n");
// Done!
break;
}
if (iteration == maxIterations)
{
nvDebug("### Reached iteration limit\n");
break;
}
iteration++;
nvDebug("### Reset charts\n");
builder.resetCharts();
if (vertexMap != NULL) {
builder.markUnchartedFaces(vertexMap->faceArray());
}
nvDebug("### Growing charts\n");
}
};
#endif
// Make sure no holes are left!
nvDebugCheck(builder.facesLeft == 0);
const uint chartCount = builder.chartArray.count();
for (uint i = 0; i < chartCount; i++)
{
Chart * chart = new Chart();
m_chartArray.append(chart);
chart->build(m_mesh, builder.chartFaces(i));
}
}
const uint chartCount = m_chartArray.count();
// Build face indices.
m_faceChart.resize(m_mesh->faceCount());
m_faceIndex.resize(m_mesh->faceCount());
for (uint i = 0; i < chartCount; i++)
{
const Chart * chart = m_chartArray[i];
const uint faceCount = chart->faceCount();
for (uint f = 0; f < faceCount; f++)
{
uint idx = chart->faceAt(f);
m_faceChart[idx] = i;
m_faceIndex[idx] = f;
}
}
// Build an exclusive prefix sum of the chart vertex counts.
m_chartVertexCountPrefixSum.resize(chartCount);
if (chartCount > 0)
{
m_chartVertexCountPrefixSum[0] = 0;
for (uint i = 1; i < chartCount; i++)
{
const Chart * chart = m_chartArray[i-1];
m_chartVertexCountPrefixSum[i] = m_chartVertexCountPrefixSum[i-1] + chart->vertexCount();
}
m_totalVertexCount = m_chartVertexCountPrefixSum[chartCount - 1] + m_chartArray[chartCount-1]->vertexCount();
}
else
{
m_totalVertexCount = 0;
}
}
void MeshCharts::parameterizeCharts()
{
ParameterizationQuality globalParameterizationQuality;
// Parameterize the charts.
uint diskCount = 0;
const uint chartCount = m_chartArray.count();
for (uint i = 0; i < chartCount; i++)\
{
Chart * chart = m_chartArray[i];
bool isValid = false;
if (chart->isVertexMapped()) {
continue;
}
if (chart->isDisk())
{
diskCount++;
ParameterizationQuality chartParameterizationQuality;
if (chart->faceCount() == 1) {
computeSingleFaceMap(chart->unifiedMesh());
chartParameterizationQuality = ParameterizationQuality(chart->unifiedMesh());
}
else {
computeOrthogonalProjectionMap(chart->unifiedMesh());
ParameterizationQuality orthogonalQuality(chart->unifiedMesh());
computeLeastSquaresConformalMap(chart->unifiedMesh());
ParameterizationQuality lscmQuality(chart->unifiedMesh());
// If the orthogonal projection produces better results, just use that.
// @@ It may be dangerous to do this, because isValid() does not detect self-overlaps.
// @@ Another problem is that with very thin patches with nearly zero parametric area, the results of our metric are not accurate.
/*if (orthogonalQuality.isValid() && orthogonalQuality.rmsStretchMetric() < lscmQuality.rmsStretchMetric()) {
computeOrthogonalProjectionMap(chart->unifiedMesh());
chartParameterizationQuality = orthogonalQuality;
}
else*/ {
chartParameterizationQuality = lscmQuality;
}
// If conformal map failed,
// @@ Experiment with other parameterization methods.
//computeCircularBoundaryMap(chart->unifiedMesh());
//computeConformalMap(chart->unifiedMesh());
//computeNaturalConformalMap(chart->unifiedMesh());
//computeGuidanceGradientMap(chart->unifiedMesh());
}
//ParameterizationQuality chartParameterizationQuality(chart->unifiedMesh());
isValid = chartParameterizationQuality.isValid();
if (!isValid)
{
nvDebug("*** Invalid parameterization.\n");
#if 0
// Dump mesh to inspect problem:
static int pieceCount = 0;
StringBuilder fileName;
fileName.format("invalid_chart_%d.obj", pieceCount++);
exportMesh(chart->unifiedMesh(), fileName.str());
#endif
}
// @@ Check that parameterization quality is above a certain threshold.
// @@ Detect boundary self-intersections.
globalParameterizationQuality += chartParameterizationQuality;
}
if (!isValid)
{
//nvDebugBreak();
// @@ Run the builder again, but only on this chart.
//AtlasBuilder builder(chart->chartMesh());
}
// Transfer parameterization from unified mesh to chart mesh.
chart->transferParameterization();
}
nvDebug(" Parameterized %d/%d charts.\n", diskCount, chartCount);
nvDebug(" RMS stretch metric: %f\n", globalParameterizationQuality.rmsStretchMetric());
nvDebug(" MAX stretch metric: %f\n", globalParameterizationQuality.maxStretchMetric());
nvDebug(" RMS conformal metric: %f\n", globalParameterizationQuality.rmsConformalMetric());
nvDebug(" RMS authalic metric: %f\n", globalParameterizationQuality.maxAuthalicMetric());
}
Chart::Chart() : m_chartMesh(NULL), m_unifiedMesh(NULL), m_isDisk(false), m_isVertexMapped(false)
{
}
void Chart::build(const HalfEdge::Mesh * originalMesh, const Array<uint> & faceArray)
{
// Copy face indices.
m_faceArray = faceArray;
const uint meshVertexCount = originalMesh->vertexCount();
m_chartMesh = new HalfEdge::Mesh();
m_unifiedMesh = new HalfEdge::Mesh();
Array<uint> chartMeshIndices;
chartMeshIndices.resize(meshVertexCount, ~0);
Array<uint> unifiedMeshIndices;
unifiedMeshIndices.resize(meshVertexCount, ~0);
// Add vertices.
const uint faceCount = faceArray.count();
for (uint f = 0; f < faceCount; f++)
{
const HalfEdge::Face * face = originalMesh->faceAt(faceArray[f]);
nvDebugCheck(face != NULL);
for(HalfEdge::Face::ConstEdgeIterator it(face->edges()); !it.isDone(); it.advance())
{
const HalfEdge::Vertex * vertex = it.current()->vertex;
const HalfEdge::Vertex * unifiedVertex = vertex->firstColocal();
if (unifiedMeshIndices[unifiedVertex->id] == ~0)
{
unifiedMeshIndices[unifiedVertex->id] = m_unifiedMesh->vertexCount();
nvDebugCheck(vertex->pos == unifiedVertex->pos);
m_unifiedMesh->addVertex(vertex->pos);
}
if (chartMeshIndices[vertex->id] == ~0)
{
chartMeshIndices[vertex->id] = m_chartMesh->vertexCount();
m_chartToOriginalMap.append(vertex->id);
m_chartToUnifiedMap.append(unifiedMeshIndices[unifiedVertex->id]);
HalfEdge::Vertex * v = m_chartMesh->addVertex(vertex->pos);
v->nor = vertex->nor;
v->tex = vertex->tex;
}
}
}
// This is ignoring the canonical map:
// - Is it really necessary to link colocals?
m_chartMesh->linkColocals();
//m_unifiedMesh->linkColocals(); // Not strictly necessary, no colocals in the unified mesh. # Wrong.
// This check is not valid anymore, if the original mesh vertices were linked with a canonical map, then it might have
// some colocal vertices that were unlinked. So, the unified mesh might have some duplicate vertices, because firstColocal()
// is not guaranteed to return the same vertex for two colocal vertices.
//nvCheck(m_chartMesh->colocalVertexCount() == m_unifiedMesh->vertexCount());
// Is that OK? What happens in meshes were that happens? Does anything break? Apparently not...
Array<uint> faceIndices(7);
// Add faces.
for (uint f = 0; f < faceCount; f++)
{
const HalfEdge::Face * face = originalMesh->faceAt(faceArray[f]);
nvDebugCheck(face != NULL);
faceIndices.clear();
for(HalfEdge::Face::ConstEdgeIterator it(face->edges()); !it.isDone(); it.advance())
{
const HalfEdge::Vertex * vertex = it.current()->vertex;
nvDebugCheck(vertex != NULL);
faceIndices.append(chartMeshIndices[vertex->id]);
}
m_chartMesh->addFace(faceIndices);
faceIndices.clear();
for(HalfEdge::Face::ConstEdgeIterator it(face->edges()); !it.isDone(); it.advance())
{
const HalfEdge::Vertex * vertex = it.current()->vertex;
nvDebugCheck(vertex != NULL);
vertex = vertex->firstColocal();
faceIndices.append(unifiedMeshIndices[vertex->id]);
}
m_unifiedMesh->addFace(faceIndices);
}
m_chartMesh->linkBoundary();
m_unifiedMesh->linkBoundary();
//exportMesh(m_unifiedMesh.ptr(), "debug_input.obj");
if (m_unifiedMesh->splitBoundaryEdges()) {
m_unifiedMesh = unifyVertices(m_unifiedMesh.ptr());
}
//exportMesh(m_unifiedMesh.ptr(), "debug_split.obj");
// Closing the holes is not always the best solution and does not fix all the problems.
// We need to do some analysis of the holes and the genus to:
// - Find cuts that reduce genus.
// - Find cuts to connect holes.
// - Use minimal spanning trees or seamster.
if (!closeHoles()) {
/*static int pieceCount = 0;
StringBuilder fileName;
fileName.format("debug_hole_%d.obj", pieceCount++);
exportMesh(m_unifiedMesh.ptr(), fileName.str());*/
}
m_unifiedMesh = triangulate(m_unifiedMesh.ptr());
//exportMesh(m_unifiedMesh.ptr(), "debug_triangulated.obj");
// Analyze chart topology.
MeshTopology topology(m_unifiedMesh.ptr());
m_isDisk = topology.isDisk();
// This is sometimes failing, when triangulate fails to add a triangle, it generates a hole in the mesh.
//nvDebugCheck(m_isDisk);
/*if (!m_isDisk) {
static int pieceCount = 0;
StringBuilder fileName;
fileName.format("debug_hole_%d.obj", pieceCount++);
exportMesh(m_unifiedMesh.ptr(), fileName.str());
}*/
#if 0
if (!m_isDisk) {
nvDebugBreak();
static int pieceCount = 0;
StringBuilder fileName;
fileName.format("debug_nodisk_%d.obj", pieceCount++);
exportMesh(m_chartMesh.ptr(), fileName.str());
}
#endif
}
void Chart::buildVertexMap(const HalfEdge::Mesh * originalMesh, const Array<uint> & unchartedMaterialArray)
{
nvCheck(m_chartMesh == NULL && m_unifiedMesh == NULL);
m_isVertexMapped = true;
// Build face indices.
m_faceArray.clear();
const uint meshFaceCount = originalMesh->faceCount();
for (uint f = 0; f < meshFaceCount; f++) {
const HalfEdge::Face * face = originalMesh->faceAt(f);
if (unchartedMaterialArray.contains(face->material)) {
m_faceArray.append(f);
}
}
const uint faceCount = m_faceArray.count();
if (faceCount == 0) {
return;
}
// @@ The chartMesh construction is basically the same as with regular charts, don't duplicate!
const uint meshVertexCount = originalMesh->vertexCount();
m_chartMesh = new HalfEdge::Mesh();
Array<uint> chartMeshIndices;
chartMeshIndices.resize(meshVertexCount, ~0);
// Vertex map mesh only has disconnected vertices.
for (uint f = 0; f < faceCount; f++)
{
const HalfEdge::Face * face = originalMesh->faceAt(m_faceArray[f]);
nvDebugCheck(face != NULL);
for (HalfEdge::Face::ConstEdgeIterator it(face->edges()); !it.isDone(); it.advance())
{
const HalfEdge::Vertex * vertex = it.current()->vertex;
if (chartMeshIndices[vertex->id] == ~0)
{
chartMeshIndices[vertex->id] = m_chartMesh->vertexCount();
m_chartToOriginalMap.append(vertex->id);
HalfEdge::Vertex * v = m_chartMesh->addVertex(vertex->pos);
v->nor = vertex->nor;
v->tex = vertex->tex; // @@ Not necessary.
}
}
}
// @@ Link colocals using the original mesh canonical map? Build canonical map on the fly? Do we need to link colocals at all for this?
//m_chartMesh->linkColocals();
Array<uint> faceIndices(7);
// Add faces.
for (uint f = 0; f < faceCount; f++)
{
const HalfEdge::Face * face = originalMesh->faceAt(m_faceArray[f]);
nvDebugCheck(face != NULL);
faceIndices.clear();
for(HalfEdge::Face::ConstEdgeIterator it(face->edges()); !it.isDone(); it.advance())
{
const HalfEdge::Vertex * vertex = it.current()->vertex;
nvDebugCheck(vertex != NULL);
nvDebugCheck(chartMeshIndices[vertex->id] != ~0);
faceIndices.append(chartMeshIndices[vertex->id]);
}
HalfEdge::Face * new_face = m_chartMesh->addFace(faceIndices);
nvDebugCheck(new_face != NULL);
}
m_chartMesh->linkBoundary();
const uint chartVertexCount = m_chartMesh->vertexCount();
Box bounds;
bounds.clearBounds();
for (uint i = 0; i < chartVertexCount; i++) {
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(i);
bounds.addPointToBounds(vertex->pos);
}
ProximityGrid grid;
grid.init(bounds, chartVertexCount);
for (uint i = 0; i < chartVertexCount; i++) {
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(i);
grid.add(vertex->pos, i);
}
#if 0
// Arrange vertices in a rectangle.
vertexMapWidth = ftoi_ceil(sqrtf(float(chartVertexCount)));
vertexMapHeight = (chartVertexCount + vertexMapWidth - 1) / vertexMapWidth;
nvDebugCheck(vertexMapWidth >= vertexMapHeight);
int x = 0, y = 0;
for (uint i = 0; i < chartVertexCount; i++) {
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(i);
vertex->tex.x = float(x);
vertex->tex.y = float(y);
x++;
if (x == vertexMapWidth) {
x = 0;
y++;
nvCheck(y < vertexMapHeight);
}
}
#elif 0
// Arrange vertices in a rectangle, traversing grid in 3D morton order and laying them down in 2D morton order.
vertexMapWidth = ftoi_ceil(sqrtf(float(chartVertexCount)));
vertexMapHeight = (chartVertexCount + vertexMapWidth - 1) / vertexMapWidth;
nvDebugCheck(vertexMapWidth >= vertexMapHeight);
int n = 0;
uint32 texelCode = 0;
uint cellsVisited = 0;
const uint32 cellCodeCount = grid.mortonCount();
for (uint32 cellCode = 0; cellCode < cellCodeCount; cellCode++) {
int cell = grid.mortonIndex(cellCode);
if (cell < 0) continue;
cellsVisited++;
const Array<uint> & indexArray = grid.cellArray[cell].indexArray;
foreach(i, indexArray) {
uint idx = indexArray[i];
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(idx);
//vertex->tex.x = float(n % rectangleWidth) + 0.5f;
//vertex->tex.y = float(n / rectangleWidth) + 0.5f;
// Lay down the points in z order too.
uint x, y;
do {
x = decodeMorton2X(texelCode);
y = decodeMorton2Y(texelCode);
texelCode++;
} while (x >= U32(vertexMapWidth) || y >= U32(vertexMapHeight));
vertex->tex.x = float(x);
vertex->tex.y = float(y);
n++;
}
}
nvDebugCheck(cellsVisited == grid.cellArray.count());
nvDebugCheck(n == chartVertexCount);
#else
uint texelCount = 0;
const float positionThreshold = 0.01f;
const float normalThreshold = 0.01f;
uint verticesVisited = 0;
uint cellsVisited = 0;
Array<int> vertexIndexArray;
vertexIndexArray.resize(chartVertexCount, -1); // Init all indices to -1.
// Traverse vertices in morton order. @@ It may be more interesting to sort them based on orientation.
const uint cellCodeCount = grid.mortonCount();
for (uint cellCode = 0; cellCode < cellCodeCount; cellCode++) {
int cell = grid.mortonIndex(cellCode);
if (cell < 0) continue;
cellsVisited++;
const Array<uint> & indexArray = grid.cellArray[cell].indexArray;
foreach(i, indexArray) {
uint idx = indexArray[i];
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(idx);
nvDebugCheck(vertexIndexArray[idx] == -1);
Array<uint> neighbors;
grid.gather(vertex->pos, positionThreshold, /*ref*/neighbors);
// Compare against all nearby vertices, cluster greedily.
foreach(j, neighbors) {
uint otherIdx = neighbors[j];
if (vertexIndexArray[otherIdx] != -1) {
HalfEdge::Vertex * otherVertex = m_chartMesh->vertexAt(otherIdx);
if (distance(vertex->pos, otherVertex->pos) < positionThreshold &&
distance(vertex->nor, otherVertex->nor) < normalThreshold)
{
vertexIndexArray[idx] = vertexIndexArray[otherIdx];
break;
}
}
}
// If index not assigned, assign new one.
if (vertexIndexArray[idx] == -1) {
vertexIndexArray[idx] = texelCount++;
}
verticesVisited++;
}
}
nvDebugCheck(cellsVisited == grid.cellArray.count());
nvDebugCheck(verticesVisited == chartVertexCount);
vertexMapWidth = ftoi_ceil(sqrtf(float(texelCount)));
vertexMapWidth = (vertexMapWidth + 3) & ~3; // Width aligned to 4.
vertexMapHeight = vertexMapWidth == 0 ? 0 : (texelCount + vertexMapWidth - 1) / vertexMapWidth;
//vertexMapHeight = (vertexMapHeight + 3) & ~3; // Height aligned to 4.
nvDebugCheck(vertexMapWidth >= vertexMapHeight);
nvDebug("Reduced vertex count from %d to %d.\n", chartVertexCount, texelCount);
#if 0
// This lays down the clustered vertices linearly.
for (uint i = 0; i < chartVertexCount; i++) {
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(i);
int idx = vertexIndexArray[i];
vertex->tex.x = float(idx % vertexMapWidth);
vertex->tex.y = float(idx / vertexMapWidth);
}
#else
// Lay down the clustered vertices in morton order.
Array<uint> texelCodes;
texelCodes.resize(texelCount);
// For each texel, assign one morton code.
uint texelCode = 0;
for (uint i = 0; i < texelCount; i++) {
uint x, y;
do {
x = decodeMorton2X(texelCode);
y = decodeMorton2Y(texelCode);
texelCode++;
} while (x >= U32(vertexMapWidth) || y >= U32(vertexMapHeight));
texelCodes[i] = texelCode - 1;
}
for (uint i = 0; i < chartVertexCount; i++) {
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(i);
int idx = vertexIndexArray[i];
if (idx != -1) {
uint texelCode = texelCodes[idx];
uint x = decodeMorton2X(texelCode);
uint y = decodeMorton2Y(texelCode);
vertex->tex.x = float(x);
vertex->tex.y = float(y);
}
}
#endif
#endif
}
static void getBoundaryEdges(HalfEdge::Mesh * mesh, Array<HalfEdge::Edge *> & boundaryEdges)
{
nvDebugCheck(mesh != NULL);
const uint edgeCount = mesh->edgeCount();
BitArray bitFlags(edgeCount);
bitFlags.clearAll();
boundaryEdges.clear();
// Search for boundary edges. Mark all the edges that belong to the same boundary.
for (uint e = 0; e < edgeCount; e++)
{
HalfEdge::Edge * startEdge = mesh->edgeAt(e);
if (startEdge != NULL && startEdge->isBoundary() && bitFlags.bitAt(e) == false)
{
nvDebugCheck(startEdge->face != NULL);
nvDebugCheck(startEdge->pair->face == NULL);
startEdge = startEdge->pair;
const HalfEdge::Edge * edge = startEdge;
do {
nvDebugCheck(edge->face == NULL);
nvDebugCheck(bitFlags.bitAt(edge->id/2) == false);
bitFlags.setBitAt(edge->id / 2);
edge = edge->next;
} while(startEdge != edge);
boundaryEdges.append(startEdge);
}
}
}
bool Chart::closeLoop(uint start, const Array<HalfEdge::Edge *> & loop)
{
const uint vertexCount = loop.count() - start;
nvDebugCheck(vertexCount >= 3);
if (vertexCount < 3) return false;
nvDebugCheck(loop[start]->vertex->isColocal(loop[start+vertexCount-1]->to()));
// If the hole is planar, then we add a single face that will be properly triangulated later.
// If the hole is not planar, we add a triangle fan with a vertex at the hole centroid.
// This is still a bit of a hack. There surely are better hole filling algorithms out there.
Array<Vector3> points;
points.resize(vertexCount);
for (uint i = 0; i < vertexCount; i++) {
points[i] = loop[start+i]->vertex->pos;
}
bool isPlanar = Fit::isPlanar(vertexCount, points.buffer());
if (isPlanar) {
// Add face and connect edges.
HalfEdge::Face * face = m_unifiedMesh->addFace();
for (uint i = 0; i < vertexCount; i++) {
HalfEdge::Edge * edge = loop[start + i];
edge->face = face;
edge->setNext(loop[start + (i + 1) % vertexCount]);
}
face->edge = loop[start];
nvDebugCheck(face->isValid());
}
else {
// If the polygon is not planar, we just cross our fingers, and hope this will work:
// Compute boundary centroid:
Vector3 centroidPos(0);
for (uint i = 0; i < vertexCount; i++) {
centroidPos += points[i];
}
centroidPos *= (1.0f / vertexCount);
HalfEdge::Vertex * centroid = m_unifiedMesh->addVertex(centroidPos);
// Add one pair of edges for each boundary vertex.
for (uint j = vertexCount-1, i = 0; i < vertexCount; j = i++) {
HalfEdge::Face * face = m_unifiedMesh->addFace(centroid->id, loop[start+j]->vertex->id, loop[start+i]->vertex->id);
nvDebugCheck(face != NULL);
}
}
return true;
}
bool Chart::closeHoles()
{
nvDebugCheck(!m_isVertexMapped);
Array<HalfEdge::Edge *> boundaryEdges;
getBoundaryEdges(m_unifiedMesh.ptr(), boundaryEdges);
uint boundaryCount = boundaryEdges.count();
if (boundaryCount <= 1)
{
// Nothing to close.
return true;
}
// Compute lengths and areas.
Array<float> boundaryLengths;
//Array<Vector3> boundaryCentroids;
for (uint i = 0; i < boundaryCount; i++)
{
const HalfEdge::Edge * startEdge = boundaryEdges[i];
nvCheck(startEdge->face == NULL);
//float boundaryEdgeCount = 0;
float boundaryLength = 0.0f;
//Vector3 boundaryCentroid(zero);
const HalfEdge::Edge * edge = startEdge;
do {
Vector3 t0 = edge->from()->pos;
Vector3 t1 = edge->to()->pos;
//boundaryEdgeCount++;
boundaryLength += length(t1 - t0);
//boundaryCentroid += edge->vertex()->pos;
edge = edge->next;
} while(edge != startEdge);
boundaryLengths.append(boundaryLength);
//boundaryCentroids.append(boundaryCentroid / boundaryEdgeCount);
}
// Find disk boundary.
uint diskBoundary = 0;
float maxLength = boundaryLengths[0];
for (uint i = 1; i < boundaryCount; i++)
{
if (boundaryLengths[i] > maxLength)
{
maxLength = boundaryLengths[i];
diskBoundary = i;
}
}
// Sew holes.
/*for (uint i = 0; i < boundaryCount; i++)
{
if (diskBoundary == i)
{
// Skip disk boundary.
continue;
}
HalfEdge::Edge * startEdge = boundaryEdges[i];
nvCheck(startEdge->face() == NULL);
boundaryEdges[i] = m_unifiedMesh->sewBoundary(startEdge);
}
exportMesh(m_unifiedMesh.ptr(), "debug_sewn.obj");*/
//bool hasNewHoles = false;
// !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
// @@ Close loop is wrong, after closing a loop, we do not only have to add the face, but make sure that every edge in he loop is pointing to the right place.
// Close holes.
for (uint i = 0; i < boundaryCount; i++)
{
if (diskBoundary == i)
{
// Skip disk boundary.
continue;
}
HalfEdge::Edge * startEdge = boundaryEdges[i];
nvDebugCheck(startEdge != NULL);
nvDebugCheck(startEdge->face == NULL);
#if 1
Array<HalfEdge::Vertex *> vertexLoop;
Array<HalfEdge::Edge *> edgeLoop;
HalfEdge::Edge * edge = startEdge;
do {
HalfEdge::Vertex * vertex = edge->next->vertex; // edge->to()
uint i;
for (i = 0; i < vertexLoop.count(); i++) {
if (vertex->isColocal(vertexLoop[i])) {
break;
}
}
bool isCrossing = (i != vertexLoop.count());
if (isCrossing) {
HalfEdge::Edge * prev = edgeLoop[i]; // Previous edge before the loop.
HalfEdge::Edge * next = edge->next; // Next edge after the loop.
nvDebugCheck(prev->to()->isColocal(next->from()));
// Close loop.
edgeLoop.append(edge);
closeLoop(i+1, edgeLoop);
// Link boundary loop.
prev->setNext(next);
vertex->setEdge(next);
// Start over again.
vertexLoop.clear();
edgeLoop.clear();
edge = startEdge;
vertex = edge->to();
}
vertexLoop.append(vertex);
edgeLoop.append(edge);
edge = edge->next;
} while(edge != startEdge);
closeLoop(0, edgeLoop);
#endif
/*
// Add face and connect boundary edges.
HalfEdge::Face * face = m_unifiedMesh->addFace();
face->setEdge(startEdge);
HalfEdge::Edge * edge = startEdge;
do {
edge->setFace(face);
edge = edge->next();
} while(edge != startEdge);
*/
/*
uint edgeCount = 0;
HalfEdge::Edge * edge = startEdge;
do {
edgeCount++;
edge = edge->next();
} while(edge != startEdge);
// Count edges in this boundary.
uint edgeCount = 0;
HalfEdge::Edge * edge = startEdge;
do {
edgeCount++;
edge = edge->next();
} while(edge != startEdge);
// Trivial hole, fill with one triangle. This actually works for all convex boundaries with non colinear vertices.
if (edgeCount == 3) {
// Add face and connect boundary edges.
HalfEdge::Face * face = m_unifiedMesh->addFace();
face->setEdge(startEdge);
edge = startEdge;
do {
edge->setFace(face);
edge = edge->next();
} while(edge != startEdge);
// @@ Implement the above using addFace, it should now work with existing edges, as long as their face pointers is zero.
}
else {
// Ideally we should:
// - compute best fit plane of boundary vertices.
// - project boundary polygon onto plane.
// - triangulate boundary polygon.
// - add faces of the resulting triangulation.
// I don't have a good triangulator available. A more simple solution that works in more (but not all) cases:
// - compute boundary centroid.
// - add vertex centroid.
// - connect centroid vertex with boundary vertices.
// - connect radial edges with boundary edges.
// This should work for non-convex boundaries with colinear vertices as long as the kernel of the polygon is not empty.
// Compute boundary centroid:
Vector3 centroid_pos(0);
Vector2 centroid_tex(0);
HalfEdge::Edge * edge = startEdge;
do {
centroid_pos += edge->vertex()->pos;
centroid_tex += edge->vertex()->tex;
edge = edge->next();
} while(edge != startEdge);
centroid_pos *= (1.0f / edgeCount);
centroid_tex *= (1.0f / edgeCount);
HalfEdge::Vertex * centroid = m_unifiedMesh->addVertex(centroid_pos);
centroid->tex = centroid_tex;
// Add one pair of edges for each boundary vertex.
edge = startEdge;
do {
HalfEdge::Edge * next = edge->next();
nvCheck(edge->face() == NULL);
HalfEdge::Face * face = m_unifiedMesh->addFace(centroid->id(), edge->from()->id(), edge->to()->id());
if (face != NULL) {
nvCheck(edge->face() == face);
}
else {
hasNewHoles = true;
}
edge = next;
} while(edge != startEdge);
}
*/
}
/*nvDebugCheck(!hasNewHoles);
if (hasNewHoles) {
// Link boundary again, in case closeHoles created new holes!
m_unifiedMesh->linkBoundary();
}*/
// Because some algorithms do not expect sparse edge buffers.
//m_unifiedMesh->compactEdges();
// In case we messed up:
//m_unifiedMesh->linkBoundary();
getBoundaryEdges(m_unifiedMesh.ptr(), boundaryEdges);
boundaryCount = boundaryEdges.count();
nvDebugCheck(boundaryCount == 1);
//exportMesh(m_unifiedMesh.ptr(), "debug_hole_filled.obj");
return boundaryCount == 1;
}
// Transfer parameterization from unified mesh to chart mesh.
void Chart::transferParameterization() {
nvDebugCheck(!m_isVertexMapped);
uint vertexCount = m_chartMesh->vertexCount();
for (uint v = 0; v < vertexCount; v++) {
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(v);
HalfEdge::Vertex * unifiedVertex = m_unifiedMesh->vertexAt(mapChartVertexToUnifiedVertex(v));
vertex->tex = unifiedVertex->tex;
}
}
float Chart::computeSurfaceArea() const {
return nv::computeSurfaceArea(m_chartMesh.ptr()) * scale;
}
float Chart::computeParametricArea() const {
// This only makes sense in parameterized meshes.
nvDebugCheck(m_isDisk);
nvDebugCheck(!m_isVertexMapped);
return nv::computeParametricArea(m_chartMesh.ptr());
}
Vector2 Chart::computeParametricBounds() const {
// This only makes sense in parameterized meshes.
nvDebugCheck(m_isDisk);
nvDebugCheck(!m_isVertexMapped);
Box bounds;
bounds.clearBounds();
uint vertexCount = m_chartMesh->vertexCount();
for (uint v = 0; v < vertexCount; v++) {
HalfEdge::Vertex * vertex = m_chartMesh->vertexAt(v);
bounds.addPointToBounds(Vector3(vertex->tex, 0));
}
return bounds.extents().xy();
}
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