77a045e902
-Reworked how meshes are treated by importer by using EditorSceneImporterMesh and EditorSceneImporterMeshNode. Instead of Mesh and MeshInstance, this allows more efficient processing of meshes before they are actually registered in the RenderingServer. -Integrated MeshOptimizer -Reworked internals of SurfaceTool to use arrays, making it more performant and easy to run optimizatons on.
351 lines
12 KiB
C++
351 lines
12 KiB
C++
// This file is part of meshoptimizer library; see meshoptimizer.h for version/license details
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#include "meshoptimizer.h"
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#include <assert.h>
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#include <math.h>
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#include <string.h>
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// This work is based on:
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// Graham Wihlidal. Optimizing the Graphics Pipeline with Compute. 2016
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// Matthaeus Chajdas. GeometryFX 1.2 - Cluster Culling. 2016
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// Jack Ritter. An Efficient Bounding Sphere. 1990
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namespace meshopt
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{
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static void computeBoundingSphere(float result[4], const float points[][3], size_t count)
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{
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assert(count > 0);
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// find extremum points along all 3 axes; for each axis we get a pair of points with min/max coordinates
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size_t pmin[3] = {0, 0, 0};
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size_t pmax[3] = {0, 0, 0};
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for (size_t i = 0; i < count; ++i)
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{
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const float* p = points[i];
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for (int axis = 0; axis < 3; ++axis)
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{
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pmin[axis] = (p[axis] < points[pmin[axis]][axis]) ? i : pmin[axis];
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pmax[axis] = (p[axis] > points[pmax[axis]][axis]) ? i : pmax[axis];
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}
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}
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// find the pair of points with largest distance
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float paxisd2 = 0;
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int paxis = 0;
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for (int axis = 0; axis < 3; ++axis)
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{
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const float* p1 = points[pmin[axis]];
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const float* p2 = points[pmax[axis]];
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float d2 = (p2[0] - p1[0]) * (p2[0] - p1[0]) + (p2[1] - p1[1]) * (p2[1] - p1[1]) + (p2[2] - p1[2]) * (p2[2] - p1[2]);
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if (d2 > paxisd2)
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{
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paxisd2 = d2;
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paxis = axis;
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}
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}
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// use the longest segment as the initial sphere diameter
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const float* p1 = points[pmin[paxis]];
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const float* p2 = points[pmax[paxis]];
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float center[3] = {(p1[0] + p2[0]) / 2, (p1[1] + p2[1]) / 2, (p1[2] + p2[2]) / 2};
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float radius = sqrtf(paxisd2) / 2;
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// iteratively adjust the sphere up until all points fit
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for (size_t i = 0; i < count; ++i)
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{
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const float* p = points[i];
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float d2 = (p[0] - center[0]) * (p[0] - center[0]) + (p[1] - center[1]) * (p[1] - center[1]) + (p[2] - center[2]) * (p[2] - center[2]);
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if (d2 > radius * radius)
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{
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float d = sqrtf(d2);
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assert(d > 0);
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float k = 0.5f + (radius / d) / 2;
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center[0] = center[0] * k + p[0] * (1 - k);
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center[1] = center[1] * k + p[1] * (1 - k);
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center[2] = center[2] * k + p[2] * (1 - k);
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radius = (radius + d) / 2;
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}
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}
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result[0] = center[0];
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result[1] = center[1];
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result[2] = center[2];
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result[3] = radius;
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}
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} // namespace meshopt
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size_t meshopt_buildMeshletsBound(size_t index_count, size_t max_vertices, size_t max_triangles)
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{
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assert(index_count % 3 == 0);
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assert(max_vertices >= 3);
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assert(max_triangles >= 1);
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// meshlet construction is limited by max vertices and max triangles per meshlet
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// the worst case is that the input is an unindexed stream since this equally stresses both limits
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// note that we assume that in the worst case, we leave 2 vertices unpacked in each meshlet - if we have space for 3 we can pack any triangle
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size_t max_vertices_conservative = max_vertices - 2;
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size_t meshlet_limit_vertices = (index_count + max_vertices_conservative - 1) / max_vertices_conservative;
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size_t meshlet_limit_triangles = (index_count / 3 + max_triangles - 1) / max_triangles;
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return meshlet_limit_vertices > meshlet_limit_triangles ? meshlet_limit_vertices : meshlet_limit_triangles;
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}
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size_t meshopt_buildMeshlets(meshopt_Meshlet* destination, const unsigned int* indices, size_t index_count, size_t vertex_count, size_t max_vertices, size_t max_triangles)
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{
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assert(index_count % 3 == 0);
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assert(max_vertices >= 3);
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assert(max_triangles >= 1);
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meshopt_Allocator allocator;
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meshopt_Meshlet meshlet;
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memset(&meshlet, 0, sizeof(meshlet));
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assert(max_vertices <= sizeof(meshlet.vertices) / sizeof(meshlet.vertices[0]));
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assert(max_triangles <= sizeof(meshlet.indices) / 3);
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// index of the vertex in the meshlet, 0xff if the vertex isn't used
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unsigned char* used = allocator.allocate<unsigned char>(vertex_count);
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memset(used, -1, vertex_count);
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size_t offset = 0;
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for (size_t i = 0; i < index_count; i += 3)
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{
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unsigned int a = indices[i + 0], b = indices[i + 1], c = indices[i + 2];
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assert(a < vertex_count && b < vertex_count && c < vertex_count);
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unsigned char& av = used[a];
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unsigned char& bv = used[b];
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unsigned char& cv = used[c];
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unsigned int used_extra = (av == 0xff) + (bv == 0xff) + (cv == 0xff);
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if (meshlet.vertex_count + used_extra > max_vertices || meshlet.triangle_count >= max_triangles)
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{
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destination[offset++] = meshlet;
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for (size_t j = 0; j < meshlet.vertex_count; ++j)
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used[meshlet.vertices[j]] = 0xff;
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memset(&meshlet, 0, sizeof(meshlet));
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}
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if (av == 0xff)
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{
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av = meshlet.vertex_count;
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meshlet.vertices[meshlet.vertex_count++] = a;
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}
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if (bv == 0xff)
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{
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bv = meshlet.vertex_count;
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meshlet.vertices[meshlet.vertex_count++] = b;
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}
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if (cv == 0xff)
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{
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cv = meshlet.vertex_count;
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meshlet.vertices[meshlet.vertex_count++] = c;
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}
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meshlet.indices[meshlet.triangle_count][0] = av;
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meshlet.indices[meshlet.triangle_count][1] = bv;
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meshlet.indices[meshlet.triangle_count][2] = cv;
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meshlet.triangle_count++;
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}
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if (meshlet.triangle_count)
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destination[offset++] = meshlet;
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assert(offset <= meshopt_buildMeshletsBound(index_count, max_vertices, max_triangles));
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return offset;
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}
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meshopt_Bounds meshopt_computeClusterBounds(const unsigned int* indices, size_t index_count, const float* vertex_positions, size_t vertex_count, size_t vertex_positions_stride)
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{
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using namespace meshopt;
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assert(index_count % 3 == 0);
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assert(vertex_positions_stride > 0 && vertex_positions_stride <= 256);
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assert(vertex_positions_stride % sizeof(float) == 0);
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assert(index_count / 3 <= 256);
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(void)vertex_count;
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size_t vertex_stride_float = vertex_positions_stride / sizeof(float);
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// compute triangle normals and gather triangle corners
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float normals[256][3];
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float corners[256][3][3];
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size_t triangles = 0;
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for (size_t i = 0; i < index_count; i += 3)
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{
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unsigned int a = indices[i + 0], b = indices[i + 1], c = indices[i + 2];
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assert(a < vertex_count && b < vertex_count && c < vertex_count);
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const float* p0 = vertex_positions + vertex_stride_float * a;
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const float* p1 = vertex_positions + vertex_stride_float * b;
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const float* p2 = vertex_positions + vertex_stride_float * c;
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float p10[3] = {p1[0] - p0[0], p1[1] - p0[1], p1[2] - p0[2]};
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float p20[3] = {p2[0] - p0[0], p2[1] - p0[1], p2[2] - p0[2]};
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float normalx = p10[1] * p20[2] - p10[2] * p20[1];
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float normaly = p10[2] * p20[0] - p10[0] * p20[2];
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float normalz = p10[0] * p20[1] - p10[1] * p20[0];
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float area = sqrtf(normalx * normalx + normaly * normaly + normalz * normalz);
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// no need to include degenerate triangles - they will be invisible anyway
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if (area == 0.f)
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continue;
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// record triangle normals & corners for future use; normal and corner 0 define a plane equation
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normals[triangles][0] = normalx / area;
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normals[triangles][1] = normaly / area;
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normals[triangles][2] = normalz / area;
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memcpy(corners[triangles][0], p0, 3 * sizeof(float));
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memcpy(corners[triangles][1], p1, 3 * sizeof(float));
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memcpy(corners[triangles][2], p2, 3 * sizeof(float));
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triangles++;
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}
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meshopt_Bounds bounds = {};
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// degenerate cluster, no valid triangles => trivial reject (cone data is 0)
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if (triangles == 0)
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return bounds;
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// compute cluster bounding sphere; we'll use the center to determine normal cone apex as well
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float psphere[4] = {};
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computeBoundingSphere(psphere, corners[0], triangles * 3);
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float center[3] = {psphere[0], psphere[1], psphere[2]};
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// treating triangle normals as points, find the bounding sphere - the sphere center determines the optimal cone axis
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float nsphere[4] = {};
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computeBoundingSphere(nsphere, normals, triangles);
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float axis[3] = {nsphere[0], nsphere[1], nsphere[2]};
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float axislength = sqrtf(axis[0] * axis[0] + axis[1] * axis[1] + axis[2] * axis[2]);
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float invaxislength = axislength == 0.f ? 0.f : 1.f / axislength;
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axis[0] *= invaxislength;
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axis[1] *= invaxislength;
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axis[2] *= invaxislength;
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// compute a tight cone around all normals, mindp = cos(angle/2)
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float mindp = 1.f;
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for (size_t i = 0; i < triangles; ++i)
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{
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float dp = normals[i][0] * axis[0] + normals[i][1] * axis[1] + normals[i][2] * axis[2];
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mindp = (dp < mindp) ? dp : mindp;
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}
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// fill bounding sphere info; note that below we can return bounds without cone information for degenerate cones
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bounds.center[0] = center[0];
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bounds.center[1] = center[1];
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bounds.center[2] = center[2];
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bounds.radius = psphere[3];
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// degenerate cluster, normal cone is larger than a hemisphere => trivial accept
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// note that if mindp is positive but close to 0, the triangle intersection code below gets less stable
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// we arbitrarily decide that if a normal cone is ~168 degrees wide or more, the cone isn't useful
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if (mindp <= 0.1f)
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{
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bounds.cone_cutoff = 1;
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bounds.cone_cutoff_s8 = 127;
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return bounds;
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}
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float maxt = 0;
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// we need to find the point on center-t*axis ray that lies in negative half-space of all triangles
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for (size_t i = 0; i < triangles; ++i)
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{
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// dot(center-t*axis-corner, trinormal) = 0
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// dot(center-corner, trinormal) - t * dot(axis, trinormal) = 0
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float cx = center[0] - corners[i][0][0];
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float cy = center[1] - corners[i][0][1];
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float cz = center[2] - corners[i][0][2];
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float dc = cx * normals[i][0] + cy * normals[i][1] + cz * normals[i][2];
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float dn = axis[0] * normals[i][0] + axis[1] * normals[i][1] + axis[2] * normals[i][2];
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// dn should be larger than mindp cutoff above
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assert(dn > 0.f);
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float t = dc / dn;
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maxt = (t > maxt) ? t : maxt;
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}
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// cone apex should be in the negative half-space of all cluster triangles by construction
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bounds.cone_apex[0] = center[0] - axis[0] * maxt;
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bounds.cone_apex[1] = center[1] - axis[1] * maxt;
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bounds.cone_apex[2] = center[2] - axis[2] * maxt;
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// note: this axis is the axis of the normal cone, but our test for perspective camera effectively negates the axis
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bounds.cone_axis[0] = axis[0];
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bounds.cone_axis[1] = axis[1];
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bounds.cone_axis[2] = axis[2];
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// cos(a) for normal cone is mindp; we need to add 90 degrees on both sides and invert the cone
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// which gives us -cos(a+90) = -(-sin(a)) = sin(a) = sqrt(1 - cos^2(a))
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bounds.cone_cutoff = sqrtf(1 - mindp * mindp);
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// quantize axis & cutoff to 8-bit SNORM format
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bounds.cone_axis_s8[0] = (signed char)(meshopt_quantizeSnorm(bounds.cone_axis[0], 8));
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bounds.cone_axis_s8[1] = (signed char)(meshopt_quantizeSnorm(bounds.cone_axis[1], 8));
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bounds.cone_axis_s8[2] = (signed char)(meshopt_quantizeSnorm(bounds.cone_axis[2], 8));
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// for the 8-bit test to be conservative, we need to adjust the cutoff by measuring the max. error
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float cone_axis_s8_e0 = fabsf(bounds.cone_axis_s8[0] / 127.f - bounds.cone_axis[0]);
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float cone_axis_s8_e1 = fabsf(bounds.cone_axis_s8[1] / 127.f - bounds.cone_axis[1]);
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float cone_axis_s8_e2 = fabsf(bounds.cone_axis_s8[2] / 127.f - bounds.cone_axis[2]);
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// note that we need to round this up instead of rounding to nearest, hence +1
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int cone_cutoff_s8 = int(127 * (bounds.cone_cutoff + cone_axis_s8_e0 + cone_axis_s8_e1 + cone_axis_s8_e2) + 1);
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bounds.cone_cutoff_s8 = (cone_cutoff_s8 > 127) ? 127 : (signed char)(cone_cutoff_s8);
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return bounds;
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}
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meshopt_Bounds meshopt_computeMeshletBounds(const meshopt_Meshlet* meshlet, const float* vertex_positions, size_t vertex_count, size_t vertex_positions_stride)
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{
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assert(vertex_positions_stride > 0 && vertex_positions_stride <= 256);
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assert(vertex_positions_stride % sizeof(float) == 0);
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unsigned int indices[sizeof(meshlet->indices) / sizeof(meshlet->indices[0][0])];
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for (size_t i = 0; i < meshlet->triangle_count; ++i)
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{
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unsigned int a = meshlet->vertices[meshlet->indices[i][0]];
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unsigned int b = meshlet->vertices[meshlet->indices[i][1]];
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unsigned int c = meshlet->vertices[meshlet->indices[i][2]];
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assert(a < vertex_count && b < vertex_count && c < vertex_count);
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indices[i * 3 + 0] = a;
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indices[i * 3 + 1] = b;
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indices[i * 3 + 2] = c;
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}
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return meshopt_computeClusterBounds(indices, meshlet->triangle_count * 3, vertex_positions, vertex_count, vertex_positions_stride);
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}
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