void ToSphericalHarmonicsL2(ref SphericalHarmonicsL2 sh) { SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 0, L0); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 1, L1_0); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 2, L1_1); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 3, L1_2); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 4, L2_0); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 5, L2_1); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 6, L2_2); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 7, L2_3); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 8, L2_4); }
internal SphericalHarmonicsL2 ToSphericalHarmonicsL2() { SphericalHarmonicsL2 sh = new SphericalHarmonicsL2(); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 0, L0); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 1, L1_0); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 2, L1_1); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 3, L1_2); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 4, L2_0); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 5, L2_1); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 6, L2_2); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 7, L2_3); SphericalHarmonicsL2Utils.SetCoefficient(ref sh, 8, L2_4); return(sh); }
static void OnAdditionalProbesBakeCompleted() { UnityEditor.Experimental.Lightmapping.additionalBakedProbesCompleted -= OnAdditionalProbesBakeCompleted; var bakingCells = m_BakingBatch.cells; var numCells = bakingCells.Count; int numUniqueProbes = m_BakingBatch.uniqueProbeCount; var sh = new NativeArray <SphericalHarmonicsL2>(numUniqueProbes, Allocator.Temp, NativeArrayOptions.UninitializedMemory); var validity = new NativeArray <float>(numUniqueProbes, Allocator.Temp, NativeArrayOptions.UninitializedMemory); var bakedProbeOctahedralDepth = new NativeArray <float>(numUniqueProbes * 64, Allocator.Temp, NativeArrayOptions.UninitializedMemory); UnityEditor.Experimental.Lightmapping.GetAdditionalBakedProbes(m_BakingBatch.index, sh, validity, bakedProbeOctahedralDepth); // Fetch results of all cells for (int c = 0; c < numCells; ++c) { var cell = bakingCells[c].cell; if (cell.probePositions == null) { continue; } int numProbes = cell.probePositions.Length; Debug.Assert(numProbes > 0); cell.sh = new SphericalHarmonicsL2[numProbes]; cell.validity = new float[numProbes]; for (int i = 0; i < numProbes; ++i) { int j = bakingCells[c].probeIndices[i]; SphericalHarmonicsL2 shv = sh[j]; // Compress the range of all coefficients but the DC component to [0..1] // Upper bounds taken from http://ppsloan.org/publications/Sig20_Advances.pptx // Divide each coefficient by DC*f to get to [-1,1] where f is from slide 33 for (int rgb = 0; rgb < 3; ++rgb) { var l0 = sh[j][rgb, 0]; if (l0 == 0.0f) { continue; } // TODO: We're working on irradiance instead of radiance coefficients // Add safety margin 2 to avoid out-of-bounds values float l1scale = 2.0f; // Should be: 3/(2*sqrt(3)) * 2, but rounding to 2 to issues we are observing. float l2scale = 3.5777088f; // 4/sqrt(5) * 2 // L_1^m shv[rgb, 1] = sh[j][rgb, 1] / (l0 * l1scale * 2.0f) + 0.5f; shv[rgb, 2] = sh[j][rgb, 2] / (l0 * l1scale * 2.0f) + 0.5f; shv[rgb, 3] = sh[j][rgb, 3] / (l0 * l1scale * 2.0f) + 0.5f; // L_2^-2 shv[rgb, 4] = sh[j][rgb, 4] / (l0 * l2scale * 2.0f) + 0.5f; shv[rgb, 5] = sh[j][rgb, 5] / (l0 * l2scale * 2.0f) + 0.5f; shv[rgb, 6] = sh[j][rgb, 6] / (l0 * l2scale * 2.0f) + 0.5f; shv[rgb, 7] = sh[j][rgb, 7] / (l0 * l2scale * 2.0f) + 0.5f; shv[rgb, 8] = sh[j][rgb, 8] / (l0 * l2scale * 2.0f) + 0.5f; for (int coeff = 1; coeff < 9; ++coeff) { Debug.Assert(shv[rgb, coeff] >= 0.0f && shv[rgb, coeff] <= 1.0f); } } SphericalHarmonicsL2Utils.SetL0(ref cell.sh[i], new Vector3(shv[0, 0], shv[1, 0], shv[2, 0])); SphericalHarmonicsL2Utils.SetL1R(ref cell.sh[i], new Vector3(shv[0, 3], shv[0, 1], shv[0, 2])); SphericalHarmonicsL2Utils.SetL1G(ref cell.sh[i], new Vector3(shv[1, 3], shv[1, 1], shv[1, 2])); SphericalHarmonicsL2Utils.SetL1B(ref cell.sh[i], new Vector3(shv[2, 3], shv[2, 1], shv[2, 2])); SphericalHarmonicsL2Utils.SetCoefficient(ref cell.sh[i], 4, new Vector3(shv[0, 4], shv[1, 4], shv[2, 4])); SphericalHarmonicsL2Utils.SetCoefficient(ref cell.sh[i], 5, new Vector3(shv[0, 5], shv[1, 5], shv[2, 5])); SphericalHarmonicsL2Utils.SetCoefficient(ref cell.sh[i], 6, new Vector3(shv[0, 6], shv[1, 6], shv[2, 6])); SphericalHarmonicsL2Utils.SetCoefficient(ref cell.sh[i], 7, new Vector3(shv[0, 7], shv[1, 7], shv[2, 7])); SphericalHarmonicsL2Utils.SetCoefficient(ref cell.sh[i], 8, new Vector3(shv[0, 8], shv[1, 8], shv[2, 8])); cell.validity[i] = validity[j]; } DilateInvalidProbes(cell.probePositions, cell.bricks, cell.sh, cell.validity, m_BakingReferenceVolumeAuthoring.GetDilationSettings()); ProbeReferenceVolume.instance.cells[cell.index] = cell; } m_BakingBatchIndex = 0; // Reset index UnityEditor.Experimental.Lightmapping.SetAdditionalBakedProbes(m_BakingBatch.index, null); // Map from each scene to an existing reference volume var scene2RefVol = new Dictionary <Scene, ProbeReferenceVolumeAuthoring>(); foreach (var refVol in GameObject.FindObjectsOfType <ProbeReferenceVolumeAuthoring>()) { if (refVol.enabled) { scene2RefVol[refVol.gameObject.scene] = refVol; } } // Map from each reference volume to its asset var refVol2Asset = new Dictionary <ProbeReferenceVolumeAuthoring, ProbeVolumeAsset>(); foreach (var refVol in scene2RefVol.Values) { refVol2Asset[refVol] = ProbeVolumeAsset.CreateAsset(refVol.gameObject.scene); } // Put cells into the respective assets foreach (var cell in ProbeReferenceVolume.instance.cells.Values) { foreach (var scene in m_BakingBatch.cellIndex2SceneReferences[cell.index]) { // This scene has a reference volume authoring component in it? ProbeReferenceVolumeAuthoring refVol = null; if (scene2RefVol.TryGetValue(scene, out refVol)) { var asset = refVol2Asset[refVol]; asset.cells.Add(cell); if (hasFoundBounds) { Vector3Int cellsInDir; int cellSizeInMeters = Mathf.CeilToInt((float)refVol.profile.cellSizeInBricks * refVol.profile.brickSize); CellCountInDirections(out cellsInDir, cellSizeInMeters); asset.maxCellIndex.x = cellsInDir.x * (int)refVol.profile.cellSizeInBricks; asset.maxCellIndex.y = cellsInDir.y * (int)refVol.profile.cellSizeInBricks; asset.maxCellIndex.z = cellsInDir.z * (int)refVol.profile.cellSizeInBricks; } else { foreach (var p in cell.probePositions) { float x = Mathf.Abs((float)p.x + refVol.transform.position.x) / refVol.profile.brickSize; float y = Mathf.Abs((float)p.y + refVol.transform.position.y) / refVol.profile.brickSize; float z = Mathf.Abs((float)p.z + refVol.transform.position.z) / refVol.profile.brickSize; asset.maxCellIndex.x = Mathf.Max(asset.maxCellIndex.x, (int)(x * 2)); asset.maxCellIndex.y = Mathf.Max(asset.maxCellIndex.y, (int)(y * 2)); asset.maxCellIndex.z = Mathf.Max(asset.maxCellIndex.z, (int)(z * 2)); } } } } } // Connect the assets to their components foreach (var pair in refVol2Asset) { var refVol = pair.Key; var asset = pair.Value; refVol.volumeAsset = asset; if (UnityEditor.Lightmapping.giWorkflowMode != UnityEditor.Lightmapping.GIWorkflowMode.Iterative) { UnityEditor.EditorUtility.SetDirty(refVol); UnityEditor.EditorUtility.SetDirty(refVol.volumeAsset); } } var probeVolumes = GameObject.FindObjectsOfType <ProbeVolume>(); foreach (var probeVolume in probeVolumes) { probeVolume.OnBakeCompleted(); } UnityEditor.AssetDatabase.SaveAssets(); UnityEditor.AssetDatabase.Refresh(); ProbeReferenceVolume.instance.clearAssetsOnVolumeClear = false; foreach (var refVol in refVol2Asset.Keys) { if (refVol.enabled && refVol.gameObject.activeSelf) { refVol.QueueAssetLoading(); } } }