Exemplo n.º 1
0
        public VoxelizationOutput Generate(VoxelizationInput input, Action<VoxelizationProgress> progress)
        {
            this.input = input;
            VoxelizationOutput output = new VoxelizationOutput();
            output.Octree = input.Octree;

            List<List<VoxelizingOctreeCell>> cellList = new List<List<VoxelizingOctreeCell>>();
            input.Octree.AccumulateChildren(out cellList);

            VolumeAccumulator volume = new VolumeAccumulator();
            VolumeAccumulator[] volumeAtLevel = new VolumeAccumulator[input.Octree.MaxLevels];
            for (int i = 0; i < input.Octree.MaxLevels; i++)
            {
                List<VoxelizingOctreeCell> childernAtDepth = cellList[i];

                VolumeAccumulator levelVolumeTotal = new VolumeAccumulator();

                Parallel.For(0, childernAtDepth.Count, () => new VolumeAccumulator(), (n, loop, partial) =>
                {
                    VoxelizingOctreeCell cell = childernAtDepth[n];
                    float sideLength = cell.Length;

                    switch (cell.Status)
                    {
                        case CellStatus.Inside:
                            partial.InsideTotal += (sideLength * sideLength * sideLength);
                            break;
                        case CellStatus.Outside:
                            partial.OutsideTotal += (sideLength * sideLength * sideLength);
                            break;
                        case CellStatus.Intersecting:
                        case CellStatus.IntersectingBounds:
                            if (cell.IsLeaf)
                                partial.IntersectingTotal += (sideLength * sideLength * sideLength);
                            break;
                    }

                    return partial;
                },
                partial =>
                {
                    lock (levelVolumeTotal)
                    {
                        levelVolumeTotal.InsideTotal += partial.InsideTotal;
                        levelVolumeTotal.OutsideTotal += partial.OutsideTotal;
                        levelVolumeTotal.IntersectingTotal += partial.IntersectingTotal;
                    }
                });

                volume.InsideTotal += levelVolumeTotal.InsideTotal;
                volume.OutsideTotal += levelVolumeTotal.OutsideTotal;
                volume.IntersectingTotal += levelVolumeTotal.IntersectingTotal;

                volumeAtLevel[i] = levelVolumeTotal;
            }

            Debug.WriteLine("Percentage of inner volume at each octree level");
            for (int i = 0; i < input.Octree.MaxLevels; i++)
            {
                Debug.WriteLine("Level {0}: Inner Volume {1}%", i, (volumeAtLevel[i].InsideTotal / volume.InsideTotal) * 100);
            }

            // A good check to perform is to compare the ratio of intersecting volume leaf nodes to the total volume
            // we've determined is inside.  A tool could use this ratio to automatically determine a good octree level
            // by iterative optimization.  If a mesh for example fails to get at least a 1 : 0.5 ratio of intersecting:inner
            // volume ratio it's a good bet that the octree does not subdivide enough levels in order to find enough inner volume
            // to meet our occlusion needs.  If further subdivision up to some maximum, lets say 8 fails to ever meet this ratio
            // one could say the mesh is not a good candidate for automating occluder generation.
            Debug.WriteLine("");
            float intersecting_inside_ratio = volume.InsideTotal / volume.IntersectingTotal;
            Debug.WriteLine("Intersecting : Inner = 1:{0}", intersecting_inside_ratio);
            Debug.WriteLine("Inner / (Inner + Intersecting) = {0}", volume.InsideTotal / (volume.InsideTotal + volume.IntersectingTotal));

            const float MINIMUM_INTERSECTING_TO_INSIDE_RATIO = 0.25f;

            AABBf meshBounds = input.Octree.MeshBounds;
            double dX = meshBounds.MaxX - meshBounds.MinX;
            double dY = meshBounds.MaxY - meshBounds.MinY;
            double dZ = meshBounds.MaxZ - meshBounds.MinZ;

            double reduction = 0.5;
            for (int i = 0; i <= input.Octree.MaxLevels * 2; i++)
                reduction *= 0.5;

            dX = dX * reduction;
            dY = dY * reduction;
            dZ = dZ * reduction;

            if (intersecting_inside_ratio > MINIMUM_INTERSECTING_TO_INSIDE_RATIO)
            {
                List<AABBi> innerBounds = new List<AABBi>();
                float innerVolumeGathered = 0.0f;
                for (int i = 0; i < input.Octree.MaxLevels; i++)
                {
                    for (int n = 0; n < cellList[i].Count; n++)
                    {
                        if (cellList[i][n].Status == CellStatus.Inside)
                        {
                            AABBf bound = cellList[i][n].Bounds;

                            AABBi bi = new AABBi();
                            bi.MaxX = (int)Math.Round(((double)bound.MaxX - (double)meshBounds.MinX) / dX, MidpointRounding.AwayFromZero);
                            bi.MaxY = (int)Math.Round(((double)bound.MaxY - (double)meshBounds.MinY) / dY, MidpointRounding.AwayFromZero);
                            bi.MaxZ = (int)Math.Round(((double)bound.MaxZ - (double)meshBounds.MinZ) / dZ, MidpointRounding.AwayFromZero);
                            bi.MinX = (int)Math.Round(((double)bound.MinX - (double)meshBounds.MinX) / dX, MidpointRounding.AwayFromZero);
                            bi.MinY = (int)Math.Round(((double)bound.MinY - (double)meshBounds.MinY) / dY, MidpointRounding.AwayFromZero);
                            bi.MinZ = (int)Math.Round(((double)bound.MinZ - (double)meshBounds.MinZ) / dZ, MidpointRounding.AwayFromZero);
                            innerBounds.Add(bi);
                        }
                    }

                    innerVolumeGathered += volumeAtLevel[i].InsideTotal / volume.InsideTotal;
                    if (innerVolumeGathered > input.MinimumVolume)
                    {
                        break;
                    }
                }

                Debug.WriteLine("Enough inner volume found {0}%", innerVolumeGathered * 100.0f);

                Mesh mesh = MeshBuilder.BuildMesh(innerBounds);

                for (int i = 0; i < mesh.Vertices.Length; i++)
                {
                    mesh.Vertices[i].X = (float)(((double)meshBounds.MinX) + (mesh.Vertices[i].X * dX));
                    mesh.Vertices[i].Y = (float)(((double)meshBounds.MinY) + (mesh.Vertices[i].Y * dY));
                    mesh.Vertices[i].Z = (float)(((double)meshBounds.MinZ) + (mesh.Vertices[i].Z * dZ));
                }

                if (input.Retriangulate)
                {
                    Mesh triangulatedMesh = MeshOptimizer.Retriangulate(input, mesh, out output.DebugLines);
                    if (triangulatedMesh != null)
                        mesh = triangulatedMesh;
                }

                mesh = PolygonFilter.Filter(input, mesh);

                output.OccluderMesh = new RenderableMesh(mesh, true);
            }
            else
            {
                Debug.WriteLine("Not enough inner volume found to continue.");
            }

            return output;
        }
Exemplo n.º 2
0
        public VoxelizationOutput Generate(VoxelizationInput input, Action <VoxelizationProgress> progress)
        {
            this.input = input;
            VoxelizationOutput output = new VoxelizationOutput();

            output.Octree = input.Octree;

            List <List <VoxelizingOctreeCell> > cellList = new List <List <VoxelizingOctreeCell> >();

            input.Octree.AccumulateChildren(out cellList);

            VolumeAccumulator volume = new VolumeAccumulator();

            VolumeAccumulator[] volumeAtLevel = new VolumeAccumulator[input.Octree.MaxLevels];
            for (int i = 0; i < input.Octree.MaxLevels; i++)
            {
                List <VoxelizingOctreeCell> childernAtDepth = cellList[i];

                VolumeAccumulator levelVolumeTotal = new VolumeAccumulator();

                Parallel.For(0, childernAtDepth.Count, () => new VolumeAccumulator(), (n, loop, partial) =>
                {
                    VoxelizingOctreeCell cell = childernAtDepth[n];
                    float sideLength          = cell.Length;

                    switch (cell.Status)
                    {
                    case CellStatus.Inside:
                        partial.InsideTotal += (sideLength * sideLength * sideLength);
                        break;

                    case CellStatus.Outside:
                        partial.OutsideTotal += (sideLength * sideLength * sideLength);
                        break;

                    case CellStatus.Intersecting:
                    case CellStatus.IntersectingBounds:
                        if (cell.IsLeaf)
                        {
                            partial.IntersectingTotal += (sideLength * sideLength * sideLength);
                        }
                        break;
                    }

                    return(partial);
                },
                             partial =>
                {
                    lock (levelVolumeTotal)
                    {
                        levelVolumeTotal.InsideTotal       += partial.InsideTotal;
                        levelVolumeTotal.OutsideTotal      += partial.OutsideTotal;
                        levelVolumeTotal.IntersectingTotal += partial.IntersectingTotal;
                    }
                });

                volume.InsideTotal       += levelVolumeTotal.InsideTotal;
                volume.OutsideTotal      += levelVolumeTotal.OutsideTotal;
                volume.IntersectingTotal += levelVolumeTotal.IntersectingTotal;

                volumeAtLevel[i] = levelVolumeTotal;
            }


            Debug.WriteLine("Percentage of inner volume at each octree level");
            for (int i = 0; i < input.Octree.MaxLevels; i++)
            {
                Debug.WriteLine("Level {0}: Inner Volume {1}%", i, (volumeAtLevel[i].InsideTotal / volume.InsideTotal) * 100);
            }

            // A good check to perform is to compare the ratio of intersecting volume leaf nodes to the total volume
            // we've determined is inside.  A tool could use this ratio to automatically determine a good octree level
            // by iterative optimization.  If a mesh for example fails to get at least a 1 : 0.5 ratio of intersecting:inner
            // volume ratio it's a good bet that the octree does not subdivide enough levels in order to find enough inner volume
            // to meet our occlusion needs.  If further subdivision up to some maximum, lets say 8 fails to ever meet this ratio
            // one could say the mesh is not a good candidate for automating occluder generation.
            Debug.WriteLine("");
            float intersecting_inside_ratio = volume.InsideTotal / volume.IntersectingTotal;

            Debug.WriteLine("Intersecting : Inner = 1:{0}", intersecting_inside_ratio);
            Debug.WriteLine("Inner / (Inner + Intersecting) = {0}", volume.InsideTotal / (volume.InsideTotal + volume.IntersectingTotal));

            const float MINIMUM_INTERSECTING_TO_INSIDE_RATIO = 0.25f;

            AABBf  meshBounds = input.Octree.MeshBounds;
            double dX         = meshBounds.MaxX - meshBounds.MinX;
            double dY         = meshBounds.MaxY - meshBounds.MinY;
            double dZ         = meshBounds.MaxZ - meshBounds.MinZ;

            double reduction = 0.5;

            for (int i = 0; i <= input.Octree.MaxLevels * 2; i++)
            {
                reduction *= 0.5;
            }

            dX = dX * reduction;
            dY = dY * reduction;
            dZ = dZ * reduction;

            if (intersecting_inside_ratio > MINIMUM_INTERSECTING_TO_INSIDE_RATIO)
            {
                List <AABBi> innerBounds         = new List <AABBi>();
                float        innerVolumeGathered = 0.0f;
                for (int i = 0; i < input.Octree.MaxLevels; i++)
                {
                    for (int n = 0; n < cellList[i].Count; n++)
                    {
                        if (cellList[i][n].Status == CellStatus.Inside)
                        {
                            AABBf bound = cellList[i][n].Bounds;

                            AABBi bi = new AABBi();
                            bi.MaxX = (int)Math.Round(((double)bound.MaxX - (double)meshBounds.MinX) / dX, MidpointRounding.AwayFromZero);
                            bi.MaxY = (int)Math.Round(((double)bound.MaxY - (double)meshBounds.MinY) / dY, MidpointRounding.AwayFromZero);
                            bi.MaxZ = (int)Math.Round(((double)bound.MaxZ - (double)meshBounds.MinZ) / dZ, MidpointRounding.AwayFromZero);
                            bi.MinX = (int)Math.Round(((double)bound.MinX - (double)meshBounds.MinX) / dX, MidpointRounding.AwayFromZero);
                            bi.MinY = (int)Math.Round(((double)bound.MinY - (double)meshBounds.MinY) / dY, MidpointRounding.AwayFromZero);
                            bi.MinZ = (int)Math.Round(((double)bound.MinZ - (double)meshBounds.MinZ) / dZ, MidpointRounding.AwayFromZero);
                            innerBounds.Add(bi);
                        }
                    }

                    innerVolumeGathered += volumeAtLevel[i].InsideTotal / volume.InsideTotal;
                    if (innerVolumeGathered > input.MinimumVolume)
                    {
                        break;
                    }
                }

                Debug.WriteLine("Enough inner volume found {0}%", innerVolumeGathered * 100.0f);

                Mesh mesh = MeshBuilder.BuildMesh(innerBounds);

                for (int i = 0; i < mesh.Vertices.Length; i++)
                {
                    mesh.Vertices[i].X = (float)(((double)meshBounds.MinX) + (mesh.Vertices[i].X * dX));
                    mesh.Vertices[i].Y = (float)(((double)meshBounds.MinY) + (mesh.Vertices[i].Y * dY));
                    mesh.Vertices[i].Z = (float)(((double)meshBounds.MinZ) + (mesh.Vertices[i].Z * dZ));
                }

                if (input.Retriangulate)
                {
                    Mesh triangulatedMesh = MeshOptimizer.Retriangulate(input, mesh, out output.DebugLines);
                    if (triangulatedMesh != null)
                    {
                        mesh = triangulatedMesh;
                    }
                }

                mesh = PolygonFilter.Filter(input, mesh);

                output.OccluderMesh = new RenderableMesh(mesh, true);
            }
            else
            {
                Debug.WriteLine("Not enough inner volume found to continue.");
            }

            return(output);
        }