Relintai/mesh_utils
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Colocals removal pt2.

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Relintai 2021-09-29 08:28:37 +02:00
parent df80bd10f0
commit 15d99e0b05
1 changed files with 14 additions and 142 deletions
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156
xatlas/xatlas.cpp
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@ -722,9 +722,10 @@ static Vector3 operator-(const Vector3 &a, const Vector3 &b) {
return Vector3(a.x - b.x, a.y - b.y, a.z - b.z);
}
/*
static bool operator==(const Vector3 &a, const Vector3 &b) {
return a.x == b.x && a.y == b.y && a.z == b.z;
}
}*/
static Vector3 cross(const Vector3 &a, const Vector3 &b) {
return Vector3(a.y * b.z - a.z * b.y, a.z * b.x - a.x * b.z, a.x * b.y - a.y * b.x);
@ -769,9 +770,10 @@ static Vector3 normalizeSafe(const Vector3 &v, const Vector3 &fallback) {
return fallback;
}
/*
static bool equal(const Vector3 &v0, const Vector3 &v1, float epsilon) {
return fabs(v0.x - v1.x) <= epsilon && fabs(v0.y - v1.y) <= epsilon && fabs(v0.z - v1.z) <= epsilon;
}
}*/
static Vector3 min(const Vector3 &a, const Vector3 &b) {
return Vector3(min(a.x, b.x), min(a.y, b.y), min(a.z, b.z));
@ -2258,7 +2260,7 @@ struct MeshFlags {
class Mesh {
public:
Mesh(float epsilon, uint32_t approxVertexCount, uint32_t approxFaceCount, uint32_t flags = 0, uint32_t id = UINT32_MAX) :
m_epsilon(epsilon), m_flags(flags), m_id(id), m_faceIgnore(MemTag::Mesh), m_faceMaterials(MemTag::Mesh), m_indices(MemTag::MeshIndices), m_positions(MemTag::MeshPositions), m_normals(MemTag::MeshNormals), m_texcoords(MemTag::MeshTexcoords), m_nextColocalVertex(MemTag::MeshColocals), m_firstColocalVertex(MemTag::MeshColocals), m_boundaryEdges(MemTag::MeshBoundaries), m_oppositeEdges(MemTag::MeshBoundaries), m_edgeMap(MemTag::MeshEdgeMap, approxFaceCount * 3) {
m_epsilon(epsilon), m_flags(flags), m_id(id), m_faceIgnore(MemTag::Mesh), m_faceMaterials(MemTag::Mesh), m_indices(MemTag::MeshIndices), m_positions(MemTag::MeshPositions), m_normals(MemTag::MeshNormals), m_texcoords(MemTag::MeshTexcoords), m_boundaryEdges(MemTag::MeshBoundaries), m_oppositeEdges(MemTag::MeshBoundaries), m_edgeMap(MemTag::MeshEdgeMap, approxFaceCount * 3) {
m_indices.reserve(approxFaceCount * 3);
m_positions.reserve(approxVertexCount);
m_texcoords.reserve(approxVertexCount);
@ -2296,92 +2298,6 @@ public:
}
}
void createColocalsBVH() {
const uint32_t vertexCount = m_positions.size();
Array<AABB> aabbs(MemTag::BVH);
aabbs.resize(vertexCount);
for (uint32_t i = 0; i < m_positions.size(); i++)
aabbs[i] = AABB(m_positions[i], m_epsilon);
BVH bvh(aabbs);
Array<uint32_t> colocals(MemTag::MeshColocals);
Array<uint32_t> potential(MemTag::MeshColocals);
m_nextColocalVertex.resize(vertexCount);
m_nextColocalVertex.fillBytes(0xff);
m_firstColocalVertex.resize(vertexCount);
m_firstColocalVertex.fillBytes(0xff);
for (uint32_t i = 0; i < vertexCount; i++) {
if (m_nextColocalVertex[i] != UINT32_MAX)
continue; // Already linked.
// Find other vertices colocal to this one.
colocals.clear();
colocals.push_back(i); // Always add this vertex.
bvh.query(AABB(m_positions[i], m_epsilon), potential);
for (uint32_t j = 0; j < potential.size(); j++) {
const uint32_t otherVertex = potential[j];
if (otherVertex != i && equal(m_positions[i], m_positions[otherVertex], m_epsilon) && m_nextColocalVertex[otherVertex] == UINT32_MAX)
colocals.push_back(otherVertex);
}
if (colocals.size() == 1) {
// No colocals for this vertex.
m_nextColocalVertex[i] = i;
m_firstColocalVertex[i] = i;
continue;
}
// Link in ascending order.
insertionSort(colocals.data(), colocals.size());
for (uint32_t j = 0; j < colocals.size(); j++) {
m_nextColocalVertex[colocals[j]] = colocals[(j + 1) % colocals.size()];
m_firstColocalVertex[colocals[j]] = colocals[0];
}
XA_DEBUG_ASSERT(m_nextColocalVertex[i] != UINT32_MAX);
}
}
void createColocalsHash() {
const uint32_t vertexCount = m_positions.size();
HashMap<Vector3> positionToVertexMap(MemTag::Default, vertexCount);
for (uint32_t i = 0; i < vertexCount; i++)
positionToVertexMap.add(m_positions[i]);
Array<uint32_t> colocals(MemTag::MeshColocals);
m_nextColocalVertex.resize(vertexCount);
m_nextColocalVertex.fillBytes(0xff);
m_firstColocalVertex.resize(vertexCount);
m_firstColocalVertex.fillBytes(0xff);
for (uint32_t i = 0; i < vertexCount; i++) {
if (m_nextColocalVertex[i] != UINT32_MAX)
continue; // Already linked.
// Find other vertices colocal to this one.
colocals.clear();
colocals.push_back(i); // Always add this vertex.
uint32_t otherVertex = positionToVertexMap.get(m_positions[i]);
while (otherVertex != UINT32_MAX) {
if (otherVertex != i && equal(m_positions[i], m_positions[otherVertex], m_epsilon) && m_nextColocalVertex[otherVertex] == UINT32_MAX)
colocals.push_back(otherVertex);
otherVertex = positionToVertexMap.getNext(m_positions[i], otherVertex);
}
if (colocals.size() == 1) {
// No colocals for this vertex.
m_nextColocalVertex[i] = i;
m_firstColocalVertex[i] = i;
continue;
}
// Link in ascending order.
insertionSort(colocals.data(), colocals.size());
for (uint32_t j = 0; j < colocals.size(); j++) {
m_nextColocalVertex[colocals[j]] = colocals[(j + 1) % colocals.size()];
m_firstColocalVertex[colocals[j]] = colocals[0];
}
XA_DEBUG_ASSERT(m_nextColocalVertex[i] != UINT32_MAX);
}
}
void createColocals() {
if (m_epsilon <= FLT_EPSILON)
createColocalsHash();
else
createColocalsBVH();
}
void createBoundaries() {
const uint32_t edgeCount = m_indices.size();
const uint32_t vertexCount = m_positions.size();
@ -2461,30 +2377,7 @@ public:
edge = m_edgeMap.getNext(key, edge);
}
}
// If colocals were created, try every permutation.
/*
if (!m_nextColocalVertex.isEmpty()) {
uint32_t colocalVertex0 = vertex0;
for (;;) {
uint32_t colocalVertex1 = vertex1;
for (;;) {
EdgeKey key(colocalVertex0, colocalVertex1);
uint32_t edge = m_edgeMap.get(key);
while (edge != UINT32_MAX) {
// Don't find edges of ignored faces.
if (!isFaceIgnored(meshEdgeFace(edge)))
return edge;
edge = m_edgeMap.getNext(key, edge);
}
colocalVertex1 = m_nextColocalVertex[colocalVertex1];
if (colocalVertex1 == vertex1)
break; // Back to start.
}
colocalVertex0 = m_nextColocalVertex[colocalVertex0];
if (colocalVertex0 == vertex0)
break; // Back to start.
}
}*/
return UINT32_MAX;
}
@ -2627,8 +2520,9 @@ public:
}
uint32_t firstColocalVertex(uint32_t vertex) const {
XA_DEBUG_ASSERT(m_firstColocalVertex.size() == m_positions.size());
return m_firstColocalVertex[vertex];
return vertex;
//XA_DEBUG_ASSERT(m_firstColocalVertex.size() == m_positions.size());
//return m_firstColocalVertex[vertex];
}
XA_INLINE float epsilon() const { return m_epsilon; }
@ -2667,10 +2561,6 @@ private:
Array<Vector3> m_normals;
Array<Vector2> m_texcoords;
// Populated by createColocals
Array<uint32_t> m_nextColocalVertex; // In: vertex index. Out: the vertex index of the next colocal position.
Array<uint32_t> m_firstColocalVertex;
// Populated by createBoundaries
BitArray m_isBoundaryVertex;
Array<uint32_t> m_boundaryEdges;
@ -5700,8 +5590,8 @@ public:
uint32_t unifiedIndices[3];
for (uint32_t i = 0; i < 3; i++) {
const uint32_t sourceVertex = sourceMesh->vertexAt(m_faceToSourceFaceMap[f] * 3 + i);
//uint32_t sourceUnifiedVertex = sourceMesh->firstColocalVertex(sourceVertex);
uint32_t sourceUnifiedVertex = sourceVertex;
uint32_t sourceUnifiedVertex = sourceMesh->firstColocalVertex(sourceVertex);
//uint32_t sourceUnifiedVertex = sourceVertex;
/*
if (m_generatorType == segment::ChartGeneratorType::OriginalUv && sourceVertex != sourceUnifiedVertex) {
// Original UVs: don't unify vertices with different UVs; we want to preserve UVs.
@ -5762,8 +5652,8 @@ public:
for (uint32_t i = 0; i < 3; i++) {
const uint32_t vertex = sourceMesh->vertexAt(m_faceToSourceFaceMap[f] * 3 + i);
//const uint32_t sourceUnifiedVertex = sourceMesh->firstColocalVertex(vertex);
const uint32_t sourceUnifiedVertex = vertex;
const uint32_t sourceUnifiedVertex = sourceMesh->firstColocalVertex(vertex);
//const uint32_t sourceUnifiedVertex = vertex;
const uint32_t parentVertex = parentMesh->vertexAt(faces[f] * 3 + i);
uint32_t unifiedVertex = sourceVertexToUnifiedVertexMap.get(sourceUnifiedVertex);
@ -6247,9 +6137,6 @@ private:
mesh->addFace(indices);
}
XA_PROFILE_START(createChartGroupMeshColocals)
mesh->createColocals();
XA_PROFILE_END(createChartGroupMeshColocals)
XA_PROFILE_START(createChartGroupMeshBoundaries)
printf("cre3\n");
mesh->createBoundaries();
@ -7495,23 +7382,10 @@ void Destroy(Atlas *atlas) {
}
static void runAddMeshTask(void *groupUserData, void *taskUserData) {
XA_PROFILE_START(addMeshThread)
auto ctx = (Context *)groupUserData;
auto mesh = (internal::Mesh *)taskUserData;
//auto mesh = (internal::Mesh *)taskUserData;
internal::Progress *progress = ctx->addMeshProgress;
if (progress->cancel) {
XA_PROFILE_END(addMeshThread)
return;
}
XA_PROFILE_START(addMeshCreateColocals)
mesh->createColocals();
XA_PROFILE_END(addMeshCreateColocals)
if (progress->cancel) {
XA_PROFILE_END(addMeshThread)
return;
}
progress->increment(1);
XA_PROFILE_END(addMeshThread)
}
static internal::Vector3 DecodePosition(const MeshDecl &meshDecl, uint32_t index) {
@ -7763,7 +7637,6 @@ void AddMeshJoin(Atlas *atlas) {
XA_PROFILE_PRINT_AND_RESET(" Total (real): ", addMeshReal)
XA_PROFILE_PRINT_AND_RESET(" Copy data: ", addMeshCopyData)
XA_PROFILE_PRINT_AND_RESET(" Total (thread): ", addMeshThread)
XA_PROFILE_PRINT_AND_RESET(" Create colocals: ", addMeshCreateColocals)
#if XA_PROFILE_ALLOC
XA_PROFILE_PRINT_AND_RESET(" Alloc: ", alloc)
#endif
@ -8004,7 +7877,6 @@ void ComputeCharts(Atlas *atlas, ChartOptions options) {
XA_PROFILE_PRINT_AND_RESET(" Chart group compute charts (real): ", chartGroupComputeChartsReal)
XA_PROFILE_PRINT_AND_RESET(" Chart group compute charts (thread): ", chartGroupComputeChartsThread)
XA_PROFILE_PRINT_AND_RESET(" Create chart group mesh: ", createChartGroupMesh)
XA_PROFILE_PRINT_AND_RESET(" Create colocals: ", createChartGroupMeshColocals)
XA_PROFILE_PRINT_AND_RESET(" Create boundaries: ", createChartGroupMeshBoundaries)
XA_PROFILE_PRINT_AND_RESET(" Build atlas: ", buildAtlas)
XA_PROFILE_PRINT_AND_RESET(" Init: ", buildAtlasInit)