voxelman/meshers/voxel_mesher.cpp

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#include "voxel_mesher.h"
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#include "../world/voxel_chunk.h"
Ref<VoxelmanLibrary> VoxelMesher::get_library() {
return _library;
}
void VoxelMesher::set_library(Ref<VoxelmanLibrary> library) {
_library = library;
}
Ref<Material> VoxelMesher::get_material() {
return _material;
}
void VoxelMesher::set_material(Ref<Material> material) {
_material = material;
}
float VoxelMesher::get_ao_strength() const {
return _ao_strength;
}
void VoxelMesher::set_ao_strength(float value) {
_ao_strength = value;
}
float VoxelMesher::get_base_light_value() const {
return _base_light_value;
}
void VoxelMesher::set_base_light_value(float value) {
_base_light_value = value;
}
float VoxelMesher::get_voxel_scale() const {
return _voxel_scale;
}
void VoxelMesher::set_voxel_scale(const float voxel_scale) {
_voxel_scale = voxel_scale;
}
int VoxelMesher::get_lod_size() const {
return _lod_size;
}
void VoxelMesher::set_lod_size(const int lod_size) {
_lod_size = lod_size;
}
Rect2 VoxelMesher::get_uv_margin() const {
return _uv_margin;
}
void VoxelMesher::set_uv_margin(const Rect2 margin) {
_uv_margin = margin;
}
void VoxelMesher::build_mesh(RID mesh) {
ERR_FAIL_COND(mesh == RID());
VS::get_singleton()->mesh_clear(mesh);
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if (_vertices.size() == 0) {
//Nothing to do
return;
}
_surface_tool->begin(Mesh::PRIMITIVE_TRIANGLES);
//if (_material.is_valid())
// _surface_tool->set_material(_material);
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if (_colors.size() != _vertices.size()) {
print_error("Colors.size() != vertices.size() -> " + String::num(_colors.size()) + " " + String::num(_vertices.size()));
_colors.resize(0);
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}
int len = _vertices.size();
for (int i = 0; i < len; ++i) {
if (_normals.size() > 0) {
_surface_tool->add_normal(_normals.get(i));
}
if (_colors.size() > 0) {
_surface_tool->add_color(_colors.get(i));
}
if (_uvs.size() > 0) {
_surface_tool->add_uv(_uvs.get(i));
}
_surface_tool->add_vertex(_vertices.get(i));
}
for (int i = 0; i < _indices.size(); ++i) {
_surface_tool->add_index(_indices.get(i));
}
if (_normals.size() == 0) {
_surface_tool->generate_normals();
}
Array arr = _surface_tool->commit_to_arrays();
VS::get_singleton()->mesh_add_surface_from_arrays(mesh, VisualServer::PRIMITIVE_TRIANGLES, arr);
if (_material.is_valid())
VS::get_singleton()->mesh_surface_set_material(mesh, 0, _library->get_material()->get_rid());
}
//Mesh Simplification
//Mesh Simplification
//Ported from https://github.com/Whinarn/UnityMeshSimplifier
//Original license: MIT License Copyright (c) 2017 Mattias Edlund
void VoxelMesher::initialize_mesh_simplify() {
if ((_indices.size() % 3) != 0)
ERR_FAIL_MSG("The index array length must be a multiple of 3 in order to represent triangles.");
int triangle_count = _indices.size() / 3;
_mu_triangles.resize(triangle_count);
for (int i = 0; i < triangle_count; ++i) {
int offset = i * 3;
int v0 = _indices[offset];
int v1 = _indices[offset + 1];
int v2 = _indices[offset + 2];
_mu_triangles[i] = MUTriangle(v0, v1, v2, 0);
}
}
//private ResizableArray<Triangle> triangles = null;
//private ResizableArray<Vertex> vertices = null;
//Mesh Simplification
//Ported from https://github.com/Whinarn/UnityMeshSimplifier
//Original license: MIT License Copyright (c) 2017 Mattias Edlund
void VoxelMesher::SimplifyMesh(float quality) {
quality = CLAMP(quality, 0, 1);
int deletedTris = 0;
PoolVector<bool> deleted0;
deleted0.resize(20);
PoolVector<bool> deleted1;
deleted1.resize(20);
int startTrisCount = _mu_triangles.size();
int targetTrisCount = static_cast<int>(_mu_triangles.size() * quality + 0.5);
for (int iteration = 0; iteration < maxIterationCount; iteration++) {
if ((startTrisCount - deletedTris) <= targetTrisCount)
break;
// Update mesh once in a while
if ((iteration % 5) == 0) {
UpdateMesh(iteration);
}
// Clear dirty flag
for (int i = 0; i < _mu_triangles.size(); ++i) {
_mu_triangles[i].dirty = false;
}
// All triangles with edges below the threshold will be removed
//
// The following numbers works well for most models.
// If it does not, try to adjust the 3 parameters
double threshold = 0.000000001 * Math::pow(iteration + 3, agressiveness);
//print_verbose("iteration {0} - triangles {1} threshold {2}", iteration, (startTrisCount - deletedTris), threshold);
// Remove vertices & mark deleted triangles
deletedTris = RemoveVertexPass(startTrisCount, targetTrisCount, threshold, deleted0, deleted1, deletedTris);
}
CompactMesh();
//print_verbose("Finished simplification with triangle count {0}", _mu_triangles.size());
}
//Mesh Simplification
//Ported from https://github.com/Whinarn/UnityMeshSimplifier
//Original license: MIT License Copyright (c) 2017 Mattias Edlund
void VoxelMesher::SimplifyMeshLossless() {
int deletedTris = 0;
PoolVector<bool> deleted0;
PoolVector<bool> deleted1;
int startTrisCount = _mu_triangles.size();
for (int iteration = 0; iteration < 9999; iteration++) {
// Update mesh constantly
UpdateMesh(iteration);
// Clear dirty flag
for (int i = 0; i < _mu_triangles.size(); ++i) {
_mu_triangles[i].dirty = false;
}
// All triangles with edges below the threshold will be removed
//
// The following numbers works well for most models.
// If it does not, try to adjust the 3 parameters
double threshold = 1.0E-3;
//Debug.LogFormat("Lossless iteration {0} - triangles {1}", iteration, triangleCount);
// Remove vertices & mark deleted triangles
deletedTris = RemoveVertexPass(startTrisCount, 0, threshold, deleted0, deleted1, deletedTris);
if (deletedTris <= 0)
break;
deletedTris = 0;
}
CompactMesh();
//Debug.LogFormat("Finished simplification with triangle count {0}", this.triangles.Length);
}
void VoxelMesher::UpdateMesh(int iteration) {
if (iteration > 0) // compact triangles
{
int dst = 0;
for (int i = 0; i < _mu_triangles.size(); ++i) {
if (!_mu_triangles[i].deleted) {
if (dst != i) {
_mu_triangles[dst] = _mu_triangles[i];
}
dst++;
}
}
_mu_triangles.resize(dst);
}
UpdateReferences();
// Identify boundary : vertices[].border=0,1
if (iteration == 0) {
PoolVector<int> vcount;
vcount.resize(8);
PoolVector<int> vids;
vids.resize(8);
int vsize = 0;
for (int i = 0; i < _mu_vertices.size(); i++) {
_mu_vertices[i].borderEdge = false;
_mu_vertices[i].uvSeamEdge = false;
_mu_vertices[i].uvFoldoverEdge = false;
}
int ofs;
int id;
int borderVertexCount = 0;
double borderMinX = std::numeric_limits<double>::max();
double borderMaxX = std::numeric_limits<double>::min();
for (int i = 0; i < _mu_vertices.size(); i++) {
int tstart = _mu_vertices[i].tstart;
int tcount = _mu_vertices[i].tcount;
vcount.resize(0);
vids.resize(0);
vsize = 0;
for (int j = 0; j < tcount; j++) {
int tid = _mu_refs[tstart + j].tid;
for (int k = 0; k < 3; k++) {
ofs = 0;
id = _mu_triangles[tid].get(k);
while (ofs < vsize) {
if (vids[ofs] == id)
break;
++ofs;
}
if (ofs == vsize) {
vcount.push_back(1);
vids.push_back(id);
++vsize;
} else {
vcount.set(ofs, vcount[ofs] + 1);
}
}
}
for (int j = 0; j < vsize; j++) {
if (vcount[j] == 1) {
id = vids[j];
_mu_vertices[id].borderEdge = true;
++borderVertexCount;
if (enableSmartLink) {
if (_mu_vertices[id].p.x < borderMinX) {
borderMinX = _mu_vertices[id].p.x;
}
if (_mu_vertices[id].p.x > borderMaxX) {
borderMaxX = _mu_vertices[id].p.x;
}
}
}
}
}
if (enableSmartLink) {
// First find all border vertices
Vector<BorderVertex> borderVertices;
borderVertices.resize(borderVertexCount);
int borderIndexCount = 0;
double borderAreaWidth = borderMaxX - borderMinX;
for (int i = 0; i < _mu_vertices.size(); i++) {
if (_mu_vertices[i].borderEdge) {
int vertexHash = (int)(((((_mu_vertices[i].p.x - borderMinX) / borderAreaWidth) * 2.0) - 1.0) * std::numeric_limits<int>::max());
borderVertices.set(borderIndexCount, BorderVertex(i, vertexHash));
++borderIndexCount;
}
}
// Sort the border vertices by hash
borderVertices.sort_custom<BorderVertexComparer>();
// Calculate the maximum hash distance based on the maximum vertex link distance
double vertexLinkDistance = Math::sqrt(vertexLinkDistanceSqr);
int hashMaxDistance = MAX((int)((vertexLinkDistance / borderAreaWidth) * std::numeric_limits<int>::max()), 1);
// Then find identical border vertices and bind them together as one
for (int i = 0; i < borderIndexCount; i++) {
int myIndex = borderVertices[i].index;
if (myIndex == -1)
continue;
Vector3 myPoint = _mu_vertices[myIndex].p;
for (int j = i + 1; j < borderIndexCount; j++) {
int otherIndex = borderVertices[j].index;
if (otherIndex == -1)
continue;
else if ((borderVertices[j].hash - borderVertices[i].hash) > hashMaxDistance) // There is no point to continue beyond this point
break;
Vector3 otherPoint = _mu_vertices[otherIndex].p;
double sqrX = ((myPoint.x - otherPoint.x) * (myPoint.x - otherPoint.x));
double sqrY = ((myPoint.y - otherPoint.y) * (myPoint.y - otherPoint.y));
double sqrZ = ((myPoint.z - otherPoint.z) * (myPoint.z - otherPoint.z));
double sqrMagnitude = sqrX + sqrY + sqrZ;
if (sqrMagnitude <= vertexLinkDistanceSqr) {
borderVertices.get(j).index = -1; // NOTE: This makes sure that the "other" vertex is not processed again
_mu_vertices[myIndex].borderEdge = false;
_mu_vertices[otherIndex].borderEdge = false;
if (AreUVsTheSame(0, myIndex, otherIndex)) {
_mu_vertices[myIndex].uvFoldoverEdge = true;
_mu_vertices[otherIndex].uvFoldoverEdge = true;
} else {
_mu_vertices[myIndex].uvSeamEdge = true;
_mu_vertices[otherIndex].uvSeamEdge = true;
}
int otherTriangleCount = _mu_vertices[otherIndex].tcount;
int otherTriangleStart = _mu_vertices[otherIndex].tstart;
for (int k = 0; k < otherTriangleCount; k++) {
MURef r = _mu_refs[otherTriangleStart + k];
_mu_triangles[r.tid].set(myIndex, r.tvertex);
}
}
}
}
// Update the references again
UpdateReferences();
}
// Init Quadrics by Plane & Edge Errors
//
// required at the beginning ( iteration == 0 )
// recomputing during the simplification is not required,
// but mostly improves the result for closed meshes
for (int i = 0; i < _mu_vertices.size(); ++i) {
_mu_vertices[i].q.reset();
}
int v0, v1, v2;
Vector3 n, p0, p1, p2, p10, p20, dummy;
SymmetricMatrix sm;
for (int i = 0; i < _mu_triangles.size(); ++i) {
v0 = _mu_triangles[i].v0;
v1 = _mu_triangles[i].v1;
v2 = _mu_triangles[i].v2;
p0 = _mu_vertices[v0].p;
p1 = _mu_vertices[v1].p;
p2 = _mu_vertices[v2].p;
p10 = p1 - p0;
p20 = p2 - p0;
n = p10.cross(p20);
n.normalize();
_mu_triangles[i].n = n;
sm.from_plane(n.x, n.y, n.z, -n.dot(p0));
_mu_vertices[v0].q += sm;
_mu_vertices[v1].q += sm;
_mu_vertices[v2].q += sm;
}
for (int i = 0; i < _mu_triangles.size(); ++i) {
// Calc Edge Error
MUTriangle triangle = _mu_triangles[i];
_mu_triangles[i].err0 = CalculateError(_mu_vertices[triangle.v0], _mu_vertices[triangle.v1], out dummy);
_mu_triangles[i].err1 = CalculateError(_mu_vertices[triangle.v1], _mu_vertices[triangle.v2], out dummy);
_mu_triangles[i].err2 = CalculateError(_mu_vertices[triangle.v2], _mu_vertices[triangle.v0], out dummy);
_mu_triangles[i].err3 = VoxelMesher::Min3(_mu_triangles[i].err0, _mu_triangles[i].err1, _mu_triangles[i].err2);
}
}
}
void VoxelMesher::UpdateReferences() {
// Init Reference ID list
for (int i = 0; i < _mu_vertices.size(); i++) {
_mu_vertices[i].tstart = 0;
_mu_vertices[i].tcount = 0;
}
for (int i = 0; i < _mu_triangles.size(); i++) {
++_mu_vertices[_mu_triangles[i].v0].tcount;
++_mu_vertices[_mu_triangles[i].v1].tcount;
++_mu_vertices[_mu_triangles[i].v2].tcount;
}
int tstart = 0;
for (int i = 0; i < _mu_vertices.size(); i++) {
_mu_vertices[i].tstart = tstart;
tstart += _mu_vertices[i].tcount;
_mu_vertices[i].tcount = 0;
}
// Write References
_mu_refs.resize(tstart);
for (int i = 0; i < _mu_triangles.size(); i++) {
int v0 = _mu_triangles[i].v0;
int v1 = _mu_triangles[i].v1;
int v2 = _mu_triangles[i].v2;
int start0 = _mu_vertices[v0].tstart;
int count0 = _mu_vertices[v0].tcount;
int start1 = _mu_vertices[v1].tstart;
int count1 = _mu_vertices[v1].tcount;
int start2 = _mu_vertices[v2].tstart;
int count2 = _mu_vertices[v2].tcount;
_mu_refs[start0 + count0].Set(i, 0);
_mu_refs[start1 + count1].Set(i, 1);
_mu_refs[start2 + count2].Set(i, 2);
++_mu_vertices[v0].tcount;
++_mu_vertices[v1].tcount;
++_mu_vertices[v2].tcount;
}
}
/// <summary>
/// Finally compact mesh before exiting.
/// </summary>
void VoxelMesher::CompactMesh() {
int dst = 0;
for (int i = 0; i < _mu_vertices.size(); i++) {
_mu_vertices[i].tcount = 0;
}
//int lastSubMeshIndex = -1;
//subMeshOffsets = new int[subMeshCount];
for (int i = 0; i < _mu_triangles.size(); i++) {
MUTriangle triangle = _mu_triangles[i];
if (!triangle.deleted) {
if (triangle.va0 != triangle.v0) {
int iDest = triangle.va0;
int iSrc = triangle.v0;
_mu_vertices[iDest].p = _mu_vertices[iSrc].p;
if (vertBoneWeights != null) {
vertBoneWeights[iDest] = vertBoneWeights[iSrc];
}
triangle.v0 = triangle.va0;
}
if (triangle.va1 != triangle.v1) {
int iDest = triangle.va1;
int iSrc = triangle.v1;
_mu_vertices[iDest].p = _mu_vertices[iSrc].p;
if (vertBoneWeights != null) {
vertBoneWeights[iDest] = vertBoneWeights[iSrc];
}
triangle.v1 = triangle.va1;
}
if (triangle.va2 != triangle.v2) {
int iDest = triangle.va2;
int iSrc = triangle.v2;
_mu_vertices[iDest].p = _mu_vertices[iSrc].p;
if (vertBoneWeights != null) {
vertBoneWeights[iDest] = vertBoneWeights[iSrc];
}
triangle.v2 = triangle.va2;
}
int newTriangleIndex = dst++;
_mu_triangles[newTriangleIndex] = triangle;
_mu_vertices[triangle.v0].tcount = 1;
_mu_vertices[triangle.v1].tcount = 1;
_mu_vertices[triangle.v2].tcount = 1;
if (triangle.subMeshIndex > lastSubMeshIndex) {
for (int j = lastSubMeshIndex + 1; j < triangle.subMeshIndex; j++) {
subMeshOffsets[j] = newTriangleIndex;
}
subMeshOffsets[triangle.subMeshIndex] = newTriangleIndex;
lastSubMeshIndex = triangle.subMeshIndex;
}
}
}
triangleCount = dst;
for (int i = lastSubMeshIndex + 1; i < subMeshCount; i++) {
subMeshOffsets[i] = triangleCount;
}
this.triangles.Resize(triangleCount);
dst = 0;
for (int i = 0; i < vertexCount; i++) {
var vert = vertices[i];
if (vert.tcount > 0) {
vert.tstart = dst;
vertices[i] = vert;
if (dst != i) {
vertices[dst].p = vert.p;
if (vertNormals != null) vertNormals[dst] = vertNormals[i];
if (vertTangents != null) vertTangents[dst] = vertTangents[i];
if (vertUV2D != null) {
for (int j = 0; j < UVChannelCount; j++) {
var vertUV = vertUV2D[j];
if (vertUV != null) {
vertUV[dst] = vertUV[i];
}
}
}
if (vertUV3D != null) {
for (int j = 0; j < UVChannelCount; j++) {
var vertUV = vertUV3D[j];
if (vertUV != null) {
vertUV[dst] = vertUV[i];
}
}
}
if (vertUV4D != null) {
for (int j = 0; j < UVChannelCount; j++) {
var vertUV = vertUV4D[j];
if (vertUV != null) {
vertUV[dst] = vertUV[i];
}
}
}
if (vertColors != null) vertColors[dst] = vertColors[i];
if (vertBoneWeights != null) vertBoneWeights[dst] = vertBoneWeights[i];
if (blendShapes != null) {
for (int shapeIndex = 0; shapeIndex < this.blendShapes.Length; shapeIndex++) {
blendShapes[shapeIndex].MoveVertexElement(dst, i);
}
}
}
++dst;
}
}
for (int i = 0; i < triangleCount; i++) {
var triangle = triangles[i];
triangle.v0 = vertices[triangle.v0].tstart;
triangle.v1 = vertices[triangle.v1].tstart;
triangle.v2 = vertices[triangle.v2].tstart;
triangles[i] = triangle;
}
vertexCount = dst;
this.vertices.Resize(vertexCount);
if (vertNormals != null) this.vertNormals.Resize(vertexCount, true);
if (vertTangents != null) this.vertTangents.Resize(vertexCount, true);
if (vertUV2D != null) this.vertUV2D.Resize(vertexCount, true);
if (vertUV3D != null) this.vertUV3D.Resize(vertexCount, true);
if (vertUV4D != null) this.vertUV4D.Resize(vertexCount, true);
if (vertColors != null) this.vertColors.Resize(vertexCount, true);
if (vertBoneWeights != null) this.vertBoneWeights.Resize(vertexCount, true);
if (blendShapes != null) {
for (int i = 0; i < this.blendShapes.Length; i++) {
blendShapes[i].Resize(vertexCount, false);
}
}
}
bool VoxelMesher::AreUVsTheSame(int channel, int indexA, int indexB) {
if (_uv2s.size() > 0) {
Vector2 vertUV = _uv2s[channel];
Vector2 uvA = _uv2s[indexA];
Vector2 uvB = _uv2s[indexB];
return uvA == uvB;
}
return false;
}
/// Remove vertices and mark deleted triangles
int VoxelMesher::RemoveVertexPass(int startTrisCount, int targetTrisCount, double threshold, PoolVector<bool> deleted0, PoolVector<bool> deleted1, int deletedTris) {
Vector3 p;
Vector3 barycentricCoord;
for (int tid = 0; tid < _mu_triangles.size(); tid++) {
if (_mu_triangles[tid].dirty || _mu_triangles[tid].deleted || _mu_triangles[tid].err3 > threshold)
continue;
Vector3 errors = _mu_triangles[tid].GetErrors();
Vector3 attrib_indices = _mu_triangles[tid].GetAttributeIndices();
for (int edgeIndex = 0; edgeIndex < 3; edgeIndex++) {
if (errors[edgeIndex] > threshold)
continue;
int nextEdgeIndex = ((edgeIndex + 1) % 3);
int i0 = _mu_triangles[tid].get(edgeIndex);
int i1 = _mu_triangles[tid].get(nextEdgeIndex);
// Border check
if (_mu_vertices[i0].borderEdge != _mu_vertices[i1].borderEdge)
continue;
// Seam check
else if (_mu_vertices[i0].uvSeamEdge != _mu_vertices[i1].uvSeamEdge)
continue;
// Foldover check
else if (_mu_vertices[i0].uvFoldoverEdge != _mu_vertices[i1].uvFoldoverEdge)
continue;
// If borders should be preserved
else if (preserveBorderEdges && _mu_vertices[i0].borderEdge)
continue;
// If seams should be preserved
else if (preserveUVSeamEdges && _mu_vertices[i0].uvSeamEdge)
continue;
// If foldovers should be preserved
else if (preserveUVFoldoverEdges && _mu_vertices[i0].uvFoldoverEdge)
continue;
// Compute vertex to collapse to
CalculateError(_mu_vertices[i0], ref _mu_vertices[i1], out p);
deleted0.Resize(_mu_vertices[i0].tcount); // normals temporarily
deleted1.Resize(_mu_vertices[i1].tcount); // normals temporarily
// Don't remove if flipped
if (Flipped(ref p, i0, i1, ref _mu_vertices[i0], deleted0.Data))
continue;
if (Flipped(ref p, i1, i0, ref _mu_vertices[i1], deleted1.Data))
continue;
// Calculate the barycentric coordinates within the triangle
int nextNextEdgeIndex = ((edgeIndex + 2) % 3);
int i2 = _mu_triangles[tid].get(nextNextEdgeIndex);
CalculateBarycentricCoords(ref p, ref _mu_vertices[i0].p, ref _mu_vertices[i1].p, ref _mu_vertices[i2].p, out barycentricCoord);
// Not flipped, so remove edge
_mu_vertices[i0].p = p;
_mu_vertices[i0].q += _mu_vertices[i1].q;
// Interpolate the vertex attributes
int ia0 = attrib_indices[edgeIndex];
int ia1 = attrib_indices[nextEdgeIndex];
int ia2 = attrib_indices[nextNextEdgeIndex];
InterpolateVertexAttributes(ia0, ia0, ia1, ia2, ref barycentricCoord);
if (_mu_vertices[i0].uvSeamEdge) {
ia0 = -1;
}
int tstart = refs.Length;
deletedTris = UpdateTriangles(i0, ia0, _mu_vertices[i0], deleted0, deletedTris);
deletedTris = UpdateTriangles(i0, ia0, _mu_vertices[i1], deleted1, deletedTris);
int tcount = refs.Length - tstart;
if (tcount <= _mu_vertices[i0].tcount) {
// save ram
if (tcount > 0) {
var refsArr = refs.Data;
Array.Copy(refsArr, tstart, refsArr, _mu_vertices[i0].tstart, tcount);
}
} else {
// append
_mu_vertices[i0].tstart = tstart;
}
_mu_vertices[i0].tcount = tcount;
break;
}
// Check if we are already done
if ((startTrisCount - deletedTris) <= targetTrisCount)
break;
}
return deletedTris;
}
double VoxelMesher::VertexError(SymmetricMatrix q, double x, double y, double z) {
return q.m0 * x * x + 2 * q.m1 * x * y + 2 * q.m2 * x * z + 2 * q.m3 * x + q.m4 * y * y + 2 * q.m5 * y * z + 2 * q.m6 * y + q.m7 * z * z + 2 * q.m8 * z + q.m9;
}
double VoxelMesher::CalculateError(MUVertex vert0, MUVertex vert1, Vector3 *result) {
// compute interpolated vertex
SymmetricMatrix q = (vert0.q + vert1.q);
bool borderEdge = (vert0.borderEdge & vert1.borderEdge);
double error = 0.0;
double det = q.Determinant1();
if (det != 0.0 && !borderEdge) {
// q_delta is invertible
result = new Vector3(
-1.0 / det * q.Determinant2(), // vx = A41/det(q_delta)
1.0 / det * q.Determinant3(), // vy = A42/det(q_delta)
-1.0 / det * q.Determinant4()); // vz = A43/det(q_delta)
error = VertexError(q, result->x, result->y, result->z);
} else {
// det = 0 -> try to find best result
Vector3 p1 = vert0.p;
Vector3 p2 = vert1.p;
Vector3 p3 = (p1 + p2) * 0.5f;
double error1 = VertexError(q, p1.x, p1.y, p1.z);
double error2 = VertexError(q, p2.x, p2.y, p2.z);
double error3 = VertexError(q, p3.x, p3.y, p3.z);
error = VoxelMesher::Min3(error1, error2, error3);
if (error == error3) {
result = p3;
} else if (error == error2) {
result = p2;
} else if (error == error1) {
result = p1;
} else {
result = p3;
}
}
return error;
}
void VoxelMesher::UpdateTriangles(int i0, int ia0, MUVertex *v, PoolVector<bool> deleted, int *deletedTriangles) {
Vector3 p;
int tcount = v->tcount;
for (int k = 0; k < tcount; k++) {
MURef r = _mu_refs[v->tstart + k];
int tid = r.tid;
MUTriangle t = _mu_triangles[tid];
if (t.deleted)
continue;
if (deleted[k]) {
_mu_triangles[tid].deleted = true;
++deletedTriangles;
continue;
}
t.set(r.tvertex, i0);
if (ia0 != -1) {
t.SetAttributeIndex(r.tvertex, ia0);
}
t.dirty = true;
t.err0 = CalculateError(_mu_vertices[t.v0], _mu_vertices[t.v1], p);
t.err1 = CalculateError(_mu_vertices[t.v1], _mu_vertices[t.v2], p);
t.err2 = CalculateError(_mu_vertices[t.v2], _mu_vertices[t.v0], p);
t.err3 = VoxelMesher::Min3(t.err0, t.err1, t.err2);
_mu_triangles[tid] = t;
_mu_refs.push_back(r);
}
}
void VoxelMesher::reset() {
_vertices.resize(0);
_normals.resize(0);
_colors.resize(0);
_uvs.resize(0);
_uv2s.resize(0);
_indices.resize(0);
_bones.resize(0);
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_surface_tool->clear();
}
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void VoxelMesher::add_chunk_bind(Node *chunk) {
VoxelChunk *vchunk = Object::cast_to<VoxelChunk>(chunk);
add_chunk(vchunk);
}
void VoxelMesher::add_chunk(VoxelChunk *chunk) {
ERR_FAIL_COND(!has_method("_add_chunk"));
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ERR_FAIL_COND(!ObjectDB::instance_validate(chunk));
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call("_add_chunk", chunk);
}
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void VoxelMesher::add_chunk_liquid_bind(Node *chunk) {
VoxelChunk *vchunk = Object::cast_to<VoxelChunk>(chunk);
add_chunk_liquid(vchunk);
}
void VoxelMesher::add_chunk_liquid(VoxelChunk *chunk) {
ERR_FAIL_COND(!has_method("_add_chunk_liquid"));
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ERR_FAIL_COND(!ObjectDB::instance_validate(chunk));
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call("_add_chunk_liquid", chunk);
}
void VoxelMesher::add_mesh_data_resource(Ref<MeshDataResource> mesh, const Vector3 position, const Vector3 rotation, const Vector3 scale, const Rect2 uv_rect) {
Transform transform = Transform(Basis(rotation).scaled(scale), position);
add_mesh_data_resource_transform(mesh, transform, uv_rect);
}
void VoxelMesher::add_mesh_data_resource_transform(Ref<MeshDataResource> mesh, const Transform transform, const Rect2 uv_rect) {
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ERR_FAIL_COND(mesh->get_array().size() == 0);
Array verts = mesh->get_array().get(Mesh::ARRAY_VERTEX);
for (int i = 0; i < verts.size(); ++i) {
Vector3 vert = verts[i];
vert = transform.xform(vert);
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add_vertex(vert);
}
if (mesh->get_array().size() <= Mesh::ARRAY_NORMAL)
return;
Array normals = mesh->get_array().get(Mesh::ARRAY_NORMAL);
for (int i = 0; i < normals.size(); ++i) {
Vector3 normal = normals[i];
normal = transform.basis.xform(normal);
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add_normal(normal);
}
/*
if (mesh->get_array().size() <= Mesh::ARRAY_TANGENT)
return;
Array tangents = mesh->get_array().get(Mesh::ARRAY_TANGENT);
for (int i = 0; i < verts.size(); ++i) {
Plane p(tangents[i * 4 + 0], tangents[i * 4 + 1], tangents[i * 4 + 2], tangents[i * 4 + 3]);
Vector3 tangent = p.normal;
Vector3 binormal = p.normal.cross(tangent).normalized() * p.d;
tangent = local_transform.basis.xform(tangent);
binormal = local_transform.basis.xform(binormal);
add_t(normal);
add_binorm
}*/
if (mesh->get_array().size() <= Mesh::ARRAY_COLOR)
return;
Array colors = mesh->get_array().get(Mesh::ARRAY_COLOR);
for (int i = 0; i < colors.size(); ++i) {
Color color = colors[i];
add_color(color);
}
if (mesh->get_array().size() <= Mesh::ARRAY_TEX_UV)
return;
Array tex_uv = mesh->get_array().get(Mesh::ARRAY_TEX_UV);
for (int i = 0; i < tex_uv.size(); ++i) {
Vector2 uv = tex_uv[i];
uv.x *= uv_rect.size.x;
uv.y *= uv_rect.size.y;
uv.x += uv_rect.position.x;
uv.y += uv_rect.position.y;
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add_uv(uv);
}
/*
if (mesh->get_array().size() <= Mesh::ARRAY_TEX_UV2)
return;
Array tex_uv2 = mesh->get_array().get(Mesh::ARRAY_TEX_UV2);
for (int i = 0; i < tex_uv.size(); ++i) {
Vector2 uv = tex_uv2[i];
add_uv2(uv);
}*/
/*
if (mesh->get_array().size() <= Mesh::ARRAY_BONES)
return;
Array bones = mesh->get_array().get(Mesh::ARRAY_BONES);
for (int i = 0; i < bones.size(); ++i) {
int bone = bones[i];
add_bone(bone);
}*/
/*
if (mesh->get_array().size() <= Mesh::ARRAY_WEIGHTS)
return;
Array weights = mesh->get_array().get(Mesh::ARRAY_WEIGHTS);
for (int i = 0; i < weights.size(); ++i) {
float weight = weights[i];
add_weight(weight);
}*/
if (mesh->get_array().size() <= Mesh::ARRAY_INDEX)
return;
Array indices = mesh->get_array().get(Mesh::ARRAY_INDEX);
int ic = get_vertex_count() - verts.size();
for (int i = 0; i < indices.size(); ++i) {
int index = indices[i];
add_indices(ic + index);
}
}
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void VoxelMesher::bake_colors_bind(Node *chunk) {
VoxelChunk *vchunk = Object::cast_to<VoxelChunk>(chunk);
bake_colors(vchunk);
}
void VoxelMesher::bake_colors(VoxelChunk *chunk) {
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ERR_FAIL_COND(!ObjectDB::instance_validate(chunk));
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if (has_method("_bake_colors"))
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call("_bake_colors", chunk);
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}
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void VoxelMesher::_bake_colors(Node *p_chunk) {
VoxelChunk *chunk = Object::cast_to<VoxelChunk>(p_chunk);
ERR_FAIL_COND(!ObjectDB::instance_validate(chunk));
Color base_light(_base_light_value, _base_light_value, _base_light_value);
ERR_FAIL_COND(_vertices.size() != _normals.size());
for (int i = 0; i < _vertices.size(); ++i) {
Vector3 vert = _vertices[i];
if (vert.x < 0 || vert.y < 0 || vert.z < 0) {
if (_colors.size() < _vertices.size()) {
_colors.push_back(base_light);
}
continue;
}
unsigned int x = (unsigned int)(vert.x / _voxel_scale);
unsigned int y = (unsigned int)(vert.y / _voxel_scale);
unsigned int z = (unsigned int)(vert.z / _voxel_scale);
if (chunk->validate_channel_data_position(x, y, z)) {
Color light = Color(
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chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_LIGHT_COLOR_R) / 255.0,
chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_LIGHT_COLOR_G) / 255.0,
chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_LIGHT_COLOR_B) / 255.0);
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float ao = (chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_AO) / 255.0) * _ao_strength;
float rao = chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_RANDOM_AO) / 255.0;
ao += rao;
light.r += _base_light_value;
light.g += _base_light_value;
light.b += _base_light_value;
light.r -= ao;
light.g -= ao;
light.b -= ao;
light.r = CLAMP(light.r, 0, 1.0);
light.g = CLAMP(light.g, 0, 1.0);
light.b = CLAMP(light.b, 0, 1.0);
if (_colors.size() < _vertices.size()) {
_colors.push_back(light);
} else {
_colors.set(i, light);
}
} else {
if (_colors.size() < _vertices.size()) {
_colors.push_back(base_light);
}
}
}
}
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void VoxelMesher::bake_liquid_colors_bind(Node *chunk) {
VoxelChunk *vchunk = Object::cast_to<VoxelChunk>(chunk);
bake_liquid_colors(vchunk);
}
void VoxelMesher::bake_liquid_colors(VoxelChunk *chunk) {
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ERR_FAIL_COND(!ObjectDB::instance_validate(chunk));
if (has_method("_bake_liquid_colors"))
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call("_bake_liquid_colors", chunk);
}
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void VoxelMesher::_bake_liquid_colors(Node *p_chunk) {
VoxelChunk *chunk = Object::cast_to<VoxelChunk>(p_chunk);
ERR_FAIL_COND(!ObjectDB::instance_validate(chunk));
Color base_light(_base_light_value, _base_light_value, _base_light_value);
ERR_FAIL_COND(_vertices.size() != _normals.size());
for (int i = 0; i < _vertices.size(); ++i) {
Vector3 vert = _vertices[i];
if (vert.x < 0 || vert.y < 0 || vert.z < 0) {
if (_colors.size() < _vertices.size()) {
_colors.push_back(base_light);
}
continue;
}
unsigned int x = (unsigned int)(vert.x / _voxel_scale);
unsigned int y = (unsigned int)(vert.y / _voxel_scale);
unsigned int z = (unsigned int)(vert.z / _voxel_scale);
if (chunk->validate_channel_data_position(x, y, z)) {
Color light = Color(
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chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_LIGHT_COLOR_R) / 255.0,
chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_LIGHT_COLOR_G) / 255.0,
chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_LIGHT_COLOR_B) / 255.0);
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float ao = (chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_AO) / 255.0) * _ao_strength;
float rao = chunk->get_voxel(x, y, z, VoxelChunk::DEFAULT_CHANNEL_RANDOM_AO) / 255.0;
ao += rao;
light.r += _base_light_value;
light.g += _base_light_value;
light.b += _base_light_value;
light.r -= ao;
light.g -= ao;
light.b -= ao;
light.r = CLAMP(light.r, 0, 1.0);
light.g = CLAMP(light.g, 0, 1.0);
light.b = CLAMP(light.b, 0, 1.0);
if (_colors.size() < _vertices.size()) {
_colors.push_back(light);
} else {
_colors.set(i, light);
}
} else {
if (_colors.size() < _vertices.size()) {
_colors.push_back(base_light);
}
}
}
}
void VoxelMesher::build_collider(RID shape) const {
ERR_FAIL_COND(shape == RID());
if (_vertices.size() == 0)
return;
PoolVector<Vector3> face_points;
if (_indices.size() == 0) {
int len = (_vertices.size() / 4);
for (int i = 0; i < len; ++i) {
face_points.push_back(_vertices.get(i * 4));
face_points.push_back(_vertices.get((i * 4) + 2));
face_points.push_back(_vertices.get((i * 4) + 1));
face_points.push_back(_vertices.get(i * 4));
face_points.push_back(_vertices.get((i * 4) + 3));
face_points.push_back(_vertices.get((i * 4) + 2));
}
PhysicsServer::get_singleton()->shape_set_data(shape, face_points);
return;
}
face_points.resize(_indices.size());
for (int i = 0; i < face_points.size(); i++) {
face_points.set(i, _vertices.get(_indices.get(i)));
}
PhysicsServer::get_singleton()->shape_set_data(shape, face_points);
}
void VoxelMesher::bake_lights(MeshInstance *node, Vector<Ref<VoxelLight> > &lights) {
ERR_FAIL_COND(node == NULL);
Color darkColor(0, 0, 0, 1);
for (int v = 0; v < _vertices.size(); ++v) {
Vector3 vet = _vertices.get(v);
Vector3 vertex = node->to_global(vet);
//grab normal
Vector3 normal = _normals.get(v);
Vector3 v_lightDiffuse;
//calculate the lights value
for (int i = 0; i < lights.size(); ++i) {
Ref<VoxelLight> light = lights.get(i);
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Vector3 lightDir = light->get_world_position() - vertex;
float dist2 = lightDir.dot(lightDir);
//inverse sqrt
lightDir *= (1.0 / sqrt(dist2));
float NdotL = normal.dot(lightDir);
if (NdotL > 1.0) {
NdotL = 1.0;
} else if (NdotL < 0.0) {
NdotL = 0.0;
}
Color cc = light->get_color();
Vector3 cv(cc.r, cc.g, cc.b);
Vector3 value = cv * (NdotL / (1.0 + dist2));
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value *= light->get_size();
v_lightDiffuse += value;
/*
float dist2 = Mathf.Clamp(Vector3.Distance(transformedLights[i], vertices), 0f, 15f);
dist2 /= 35f;
Vector3 value = Vector3.one;
value *= ((float) lights[i].Strength) / 255f;
value *= (1 - dist2);
v_lightDiffuse += value;*/
}
Color f = _colors.get(v);
//Color f = darkColor;
Vector3 cv2(f.r, f.g, f.b);
cv2 += v_lightDiffuse;
if (cv2.x > 1)
cv2.x = 1;
if (cv2.y > 1)
cv2.y = 1;
if (cv2.y > 1)
cv2.y = 1;
// cv2.x = Mathf.Clamp(cv2.x, 0f, 1f);
//cv2.y = Mathf.Clamp(cv2.y, 0f, 1f);
// cv2.z = Mathf.Clamp(cv2.z, 0f, 1f);
f.r = cv2.x;
f.g = cv2.y;
f.b = cv2.z;
//f.r = v_lightDiffuse.x;
//f.g = v_lightDiffuse.y;
//f.b = v_lightDiffuse.z;
_colors.set(v, f);
}
// for (int i = 0; i < _colors->size(); ++i) {
// print_error(_colors->get(i));
// }
}
PoolVector<Vector3> VoxelMesher::get_vertices() {
return _vertices;
}
void VoxelMesher::set_vertices(PoolVector<Vector3> values) {
_vertices = values;
}
int VoxelMesher::get_vertex_count() {
return _vertices.size();
}
void VoxelMesher::add_vertex(Vector3 vertex) {
_vertices.push_back(vertex);
}
Vector3 VoxelMesher::get_vertex(int idx) {
return _vertices.get(idx);
}
void VoxelMesher::remove_vertex(int idx) {
_vertices.remove(idx);
}
PoolVector<Vector3> VoxelMesher::get_normals() {
return _normals;
}
void VoxelMesher::set_normals(PoolVector<Vector3> values) {
_normals = values;
}
int VoxelMesher::get_normal_count() {
return _normals.size();
}
void VoxelMesher::add_normal(Vector3 normal) {
_normals.push_back(normal);
}
Vector3 VoxelMesher::get_normal(int idx) {
return _normals.get(idx);
}
void VoxelMesher::remove_normal(int idx) {
_normals.remove(idx);
}
PoolVector<Color> VoxelMesher::get_colors() {
return _colors;
}
void VoxelMesher::set_colors(PoolVector<Color> values) {
_colors = values;
}
int VoxelMesher::get_color_count() {
return _colors.size();
}
void VoxelMesher::add_color(Color color) {
_colors.push_back(color);
}
Color VoxelMesher::get_color(int idx) {
return _colors.get(idx);
}
void VoxelMesher::remove_color(int idx) {
_colors.remove(idx);
}
PoolVector<Vector2> VoxelMesher::get_uvs() {
return _uvs;
}
void VoxelMesher::set_uvs(PoolVector<Vector2> values) {
_uvs = values;
}
int VoxelMesher::get_uv_count() {
return _uvs.size();
}
void VoxelMesher::add_uv(Vector2 uv) {
_uvs.push_back(uv);
}
Vector2 VoxelMesher::get_uv(int idx) {
return _uvs.get(idx);
}
void VoxelMesher::remove_uv(int idx) {
_uvs.remove(idx);
}
PoolVector<Vector2> VoxelMesher::get_uv2s() {
return _uv2s;
}
void VoxelMesher::set_uv2s(PoolVector<Vector2> values) {
_uv2s = values;
}
int VoxelMesher::get_uv2_count() {
return _uv2s.size();
}
void VoxelMesher::add_uv2(Vector2 uv) {
_uv2s.push_back(uv);
}
Vector2 VoxelMesher::get_uv2(int idx) {
return _uv2s.get(idx);
}
void VoxelMesher::remove_uv2(int idx) {
_uv2s.remove(idx);
}
PoolVector<int> VoxelMesher::get_indices() {
return _indices;
}
void VoxelMesher::set_indices(PoolVector<int> values) {
_indices = values;
}
int VoxelMesher::get_indices_count() {
return _indices.size();
}
void VoxelMesher::add_indices(int index) {
_indices.push_back(index);
}
int VoxelMesher::get_indice(int idx) {
return _indices.get(idx);
}
void VoxelMesher::remove_indices(int idx) {
_indices.remove(idx);
}
VoxelMesher::VoxelMesher(Ref<VoxelmanLibrary> library) {
_library = library;
_voxel_scale = 1;
_lod_size = 1;
_surface_tool.instance();
}
VoxelMesher::VoxelMesher() {
_voxel_scale = 1;
_lod_size = 1;
_ao_strength = 0.25;
_base_light_value = 0.5;
_uv_margin = Rect2(0, 0, 1, 1);
_surface_tool.instance();
maxIterationCount = 100;
agressiveness = 7.0;
enableSmartLink = true;
preserveBorderEdges = false;
preserveUVSeamEdges = false;
preserveUVFoldoverEdges = false;
}
VoxelMesher::~VoxelMesher() {
_surface_tool.unref();
if (_library.is_valid()) {
_library.unref();
}
}
void VoxelMesher::_bind_methods() {
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BIND_VMETHOD(MethodInfo("_add_chunk", PropertyInfo(Variant::OBJECT, "chunk", PROPERTY_HINT_RESOURCE_TYPE, "VoxelChunk")));
BIND_VMETHOD(MethodInfo("_add_chunk_liquid", PropertyInfo(Variant::OBJECT, "chunk", PROPERTY_HINT_RESOURCE_TYPE, "VoxelChunk")));
BIND_VMETHOD(MethodInfo("_bake_colors", PropertyInfo(Variant::OBJECT, "chunk", PROPERTY_HINT_RESOURCE_TYPE, "VoxelChunk")));
BIND_VMETHOD(MethodInfo("_bake_liquid_colors", PropertyInfo(Variant::OBJECT, "chunk", PROPERTY_HINT_RESOURCE_TYPE, "VoxelChunk")));
ClassDB::bind_method(D_METHOD("get_library"), &VoxelMesher::get_library);
ClassDB::bind_method(D_METHOD("set_library", "value"), &VoxelMesher::set_library);
ADD_PROPERTY(PropertyInfo(Variant::OBJECT, "library", PROPERTY_HINT_RESOURCE_TYPE, "VoxelmanLibrary"), "set_library", "get_library");
ClassDB::bind_method(D_METHOD("get_material"), &VoxelMesher::get_material);
ClassDB::bind_method(D_METHOD("set_material", "value"), &VoxelMesher::set_material);
ADD_PROPERTY(PropertyInfo(Variant::OBJECT, "material", PROPERTY_HINT_RESOURCE_TYPE, "Material"), "set_material", "get_material");
ClassDB::bind_method(D_METHOD("get_voxel_scale"), &VoxelMesher::get_voxel_scale);
ClassDB::bind_method(D_METHOD("set_voxel_scale", "value"), &VoxelMesher::set_voxel_scale);
ADD_PROPERTY(PropertyInfo(Variant::REAL, "voxel_scale"), "set_voxel_scale", "get_voxel_scale");
ClassDB::bind_method(D_METHOD("get_lod_size"), &VoxelMesher::get_lod_size);
ClassDB::bind_method(D_METHOD("set_lod_size", "value"), &VoxelMesher::set_lod_size);
ADD_PROPERTY(PropertyInfo(Variant::INT, "lod_size"), "set_lod_size", "get_lod_size");
ClassDB::bind_method(D_METHOD("get_ao_strength"), &VoxelMesher::get_ao_strength);
ClassDB::bind_method(D_METHOD("set_ao_strength", "value"), &VoxelMesher::set_ao_strength);
ADD_PROPERTY(PropertyInfo(Variant::REAL, "ao_strength"), "set_ao_strength", "get_ao_strength");
ClassDB::bind_method(D_METHOD("get_base_light_value"), &VoxelMesher::get_base_light_value);
ClassDB::bind_method(D_METHOD("set_base_light_value", "value"), &VoxelMesher::set_base_light_value);
ADD_PROPERTY(PropertyInfo(Variant::REAL, "base_light_value"), "set_base_light_value", "get_base_light_value");
ClassDB::bind_method(D_METHOD("get_uv_margin"), &VoxelMesher::get_uv_margin);
ClassDB::bind_method(D_METHOD("set_uv_margin", "value"), &VoxelMesher::set_uv_margin);
ADD_PROPERTY(PropertyInfo(Variant::RECT2, "uv_margin"), "set_uv_margin", "get_uv_margin");
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ClassDB::bind_method(D_METHOD("add_chunk", "chunk"), &VoxelMesher::add_chunk_bind);
ClassDB::bind_method(D_METHOD("add_chunk_liquid", "chunk"), &VoxelMesher::add_chunk_liquid_bind);
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ClassDB::bind_method(D_METHOD("add_mesh_data_resource", "mesh", "position", "rotation", "scale", "uv_rect"), &VoxelMesher::add_mesh_data_resource, DEFVAL(Rect2(0, 0, 1, 1)), DEFVAL(Vector3(1.0, 1.0, 1.0)), DEFVAL(Vector3()), DEFVAL(Vector3()));
ClassDB::bind_method(D_METHOD("add_mesh_data_resource_transform", "mesh", "transform", "uv_rect"), &VoxelMesher::add_mesh_data_resource_transform, DEFVAL(Rect2(0, 0, 1, 1)));
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ClassDB::bind_method(D_METHOD("bake_colors", "chunk"), &VoxelMesher::bake_colors_bind);
ClassDB::bind_method(D_METHOD("_bake_colors", "chunk"), &VoxelMesher::_bake_colors);
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ClassDB::bind_method(D_METHOD("bake_liquid_colors", "chunk"), &VoxelMesher::bake_liquid_colors_bind);
ClassDB::bind_method(D_METHOD("_bake_liquid_colors", "chunk"), &VoxelMesher::_bake_liquid_colors);
ClassDB::bind_method(D_METHOD("get_vertices"), &VoxelMesher::get_vertices);
ClassDB::bind_method(D_METHOD("set_vertices", "values"), &VoxelMesher::set_vertices);
ClassDB::bind_method(D_METHOD("get_vertex_count"), &VoxelMesher::get_vertex_count);
ClassDB::bind_method(D_METHOD("get_vertex", "idx"), &VoxelMesher::get_vertex);
ClassDB::bind_method(D_METHOD("remove_vertex", "idx"), &VoxelMesher::remove_vertex);
ClassDB::bind_method(D_METHOD("add_vertex", "vertex"), &VoxelMesher::add_vertex);
ClassDB::bind_method(D_METHOD("get_normals"), &VoxelMesher::get_normals);
ClassDB::bind_method(D_METHOD("set_normals", "values"), &VoxelMesher::set_normals);
ClassDB::bind_method(D_METHOD("get_normal_count"), &VoxelMesher::get_normal_count);
ClassDB::bind_method(D_METHOD("get_normal", "idx"), &VoxelMesher::get_normal);
ClassDB::bind_method(D_METHOD("remove_normal", "idx"), &VoxelMesher::remove_normal);
ClassDB::bind_method(D_METHOD("add_normal", "normal"), &VoxelMesher::add_normal);
ClassDB::bind_method(D_METHOD("get_colors"), &VoxelMesher::get_colors);
ClassDB::bind_method(D_METHOD("set_colors", "values"), &VoxelMesher::set_colors);
ClassDB::bind_method(D_METHOD("get_color_count"), &VoxelMesher::get_color_count);
ClassDB::bind_method(D_METHOD("get_color", "idx"), &VoxelMesher::get_color);
ClassDB::bind_method(D_METHOD("remove_color", "idx"), &VoxelMesher::remove_color);
ClassDB::bind_method(D_METHOD("add_color", "color"), &VoxelMesher::add_color);
ClassDB::bind_method(D_METHOD("get_uvs"), &VoxelMesher::get_uvs);
ClassDB::bind_method(D_METHOD("set_uvs", "values"), &VoxelMesher::set_uvs);
ClassDB::bind_method(D_METHOD("get_uv_count"), &VoxelMesher::get_uv_count);
ClassDB::bind_method(D_METHOD("get_uv", "idx"), &VoxelMesher::get_uv);
ClassDB::bind_method(D_METHOD("remove_uv", "idx"), &VoxelMesher::remove_uv);
ClassDB::bind_method(D_METHOD("add_uv", "uv"), &VoxelMesher::add_uv);
ClassDB::bind_method(D_METHOD("get_uv2s"), &VoxelMesher::get_uv2s);
ClassDB::bind_method(D_METHOD("set_uv2s", "values"), &VoxelMesher::set_uv2s);
ClassDB::bind_method(D_METHOD("get_uv2_count"), &VoxelMesher::get_uv2_count);
ClassDB::bind_method(D_METHOD("get_uv2", "idx"), &VoxelMesher::get_uv2);
ClassDB::bind_method(D_METHOD("remove_uv2", "idx"), &VoxelMesher::remove_uv2);
ClassDB::bind_method(D_METHOD("add_uv2", "uv"), &VoxelMesher::add_uv2);
ClassDB::bind_method(D_METHOD("get_indices"), &VoxelMesher::get_indices);
ClassDB::bind_method(D_METHOD("set_indices", "values"), &VoxelMesher::set_indices);
ClassDB::bind_method(D_METHOD("get_indices_count"), &VoxelMesher::get_indices_count);
ClassDB::bind_method(D_METHOD("get_indice", "idx"), &VoxelMesher::get_indice);
ClassDB::bind_method(D_METHOD("remove_indices", "idx"), &VoxelMesher::remove_indices);
ClassDB::bind_method(D_METHOD("add_indices", "indice"), &VoxelMesher::add_indices);
ClassDB::bind_method(D_METHOD("reset"), &VoxelMesher::reset);
//ClassDB::bind_method(D_METHOD("calculate_vertex_ambient_occlusion", "meshinstance_path", "radius", "intensity", "sampleCount"), &VoxelMesher::calculate_vertex_ambient_occlusion_path);
ClassDB::bind_method(D_METHOD("build_mesh", "mesh_rid"), &VoxelMesher::build_mesh);
}