/// <summary>
/// Releases the static buffers.
/// </summary>
public void ReleaseSharedBuffers()
{
if (OwnSharedBuffers())
{
gVertices.SetActiveSize(0);
vertices = null;
gNormals.SetActiveSize(0);
normals = null;
gTangents.SetActiveSize(0);
tangents = null;
gUV.SetActiveSize(0);
uv = null;
gUV2.SetActiveSize(0);
uv2 = null;
gUV3.SetActiveSize(0);
uv3 = null;
gUV4.SetActiveSize(0);
uv4 = null;
gColors32.SetActiveSize(0);
colors32 = null;
for (int i = 0; i < gSubmeshTris.Length; i++)
{
gSubmeshTriIndices[i] = UNUSED_SUBMESH;
gSubmeshTris[i].SetActiveSize(0);
}
boneWeights = null;
unityBoneWeights = null;
bufferLockOwner = null;
}
}
public void InitializeFromMeshData(UMAMeshData meshData)
{
if (meshData == null)
{
if (Debug.isDebugBuild)
{
Debug.LogError("InitializeFromMeshData: meshData is null!");
}
return;
}
_sharedMesh = new Mesh();
#if UMA_32BITBUFFERS
_sharedMesh.indexFormat = UnityEngine.Rendering.IndexFormat.UInt32;
#endif
_sharedMesh.subMeshCount = meshData.subMeshCount;
_sharedMesh.vertices = meshData.vertices;
_sharedMesh.normals = meshData.normals;
_sharedMesh.tangents = meshData.tangents;
_sharedMesh.uv = meshData.uv;
_sharedMesh.uv2 = meshData.uv2;
_sharedMesh.uv3 = meshData.uv3;
_sharedMesh.uv4 = meshData.uv4;
_sharedMesh.colors32 = meshData.colors32;
for (int i = 0; i < meshData.subMeshCount; i++)
{
_sharedMesh.SetTriangles(meshData.submeshes[i].triangles, i);
}
Initialize();
}
public void UpdateOcclusionMesh(UMAMeshData meshData, float offset, Vector3 pos, Vector3 rot, Vector3 s)
{
//Let's call CreateOcclusionMesh to reset it.
CreateOcclusionMesh(meshData);
UpdateOcclusionMesh(offset, pos, rot, s);
}
protected void RecalculateUV(UMAMeshData umaMesh)
{
int idx = 0;
//Handle Atlassed Verts
for (int materialIndex = 0; materialIndex < umaData.generatedMaterials.materials.Count; materialIndex++)
{
var generatedMaterial = umaData.generatedMaterials.materials[materialIndex];
if (generatedMaterial.umaMaterial.materialType != UMAMaterial.MaterialType.Atlas)
{
continue;
}
for (int materialDefinitionIndex = 0; materialDefinitionIndex < generatedMaterial.materialFragments.Count; materialDefinitionIndex++)
{
var fragment = generatedMaterial.materialFragments[materialDefinitionIndex];
var tempAtlasRect = fragment.atlasRegion;
int vertexCount = fragment.slotData.asset.meshData.vertices.Length;
float atlasXMin = tempAtlasRect.xMin / atlasResolution;
float atlasXMax = tempAtlasRect.xMax / atlasResolution;
float atlasXRange = atlasXMax - atlasXMin;
float atlasYMin = tempAtlasRect.yMin / atlasResolution;
float atlasYMax = tempAtlasRect.yMax / atlasResolution;
float atlasYRange = atlasYMax - atlasYMin;
while (vertexCount-- > 0)
{
umaMesh.uv[idx].x = atlasXMin + atlasXRange * umaMesh.uv[idx].x;
umaMesh.uv[idx].y = atlasYMin + atlasYRange * umaMesh.uv[idx].y;
idx++;
}
}
}
}
public void InitializeFromMeshData(UMAMeshData meshData)
{
if (meshData == null)
{
if (Debug.isDebugBuild)
{
Debug.LogError("InitializeFromMeshData: meshData is null!");
}
return;
}
_sharedMesh = new Mesh();
#if UMA_32BITBUFFERS
_sharedMesh.indexFormat = UnityEngine.Rendering.IndexFormat.UInt32;
#endif
_sharedMesh.subMeshCount = 1; // we're only copying the current submesh
_sharedMesh.vertices = meshData.vertices;
_sharedMesh.normals = meshData.normals;
_sharedMesh.tangents = meshData.tangents;
_sharedMesh.uv = meshData.uv;
_sharedMesh.uv2 = meshData.uv2;
_sharedMesh.uv3 = meshData.uv3;
_sharedMesh.uv4 = meshData.uv4;
_sharedMesh.colors32 = meshData.colors32;
_sharedMesh.SetTriangles(meshData.submeshes[meshAsset.asset.subMeshIndex].triangles, 0);
Initialize();
}
public void InitializeFromMeshData(UMAMeshData meshData)
{
if (meshData == null)
{
Debug.LogError("InitializeFromMeshData: meshData is null!");
return;
}
_sharedMesh = new Mesh();
_sharedMesh.subMeshCount = meshData.subMeshCount;
_sharedMesh.vertices = meshData.vertices;
_sharedMesh.normals = meshData.normals;
_sharedMesh.tangents = meshData.tangents;
_sharedMesh.uv = meshData.uv;
_sharedMesh.uv2 = meshData.uv2;
_sharedMesh.uv3 = meshData.uv3;
_sharedMesh.uv4 = meshData.uv4;
_sharedMesh.colors32 = meshData.colors32;
for (int i = 0; i < meshData.subMeshCount; i++)
{
_sharedMesh.SetTriangles(meshData.submeshes[i].triangles, i);
}
Initialize();
}
public void CreateOcclusionMesh(UMAMeshData meshData)
{
if (meshData == null)
{
return;
}
;
if (_occlusionMesh == null)
{
_occlusionMesh = new Mesh();
}
else
{
_occlusionMesh.Clear();
}
_occlusionMesh.subMeshCount = meshData.subMeshCount;
_occlusionMesh.vertices = meshData.vertices;
_occlusionMesh.normals = meshData.normals;
_occlusionMesh.tangents = meshData.tangents;
_occlusionMesh.uv = meshData.uv;
_occlusionMesh.uv2 = meshData.uv2;
_occlusionMesh.uv3 = meshData.uv3;
_occlusionMesh.uv4 = meshData.uv4;
_occlusionMesh.colors32 = meshData.colors32;
_occlusionMesh.triangles = new int[0];
_occlusionMesh.subMeshCount = meshData.subMeshCount;
for (int i = 0; i < meshData.subMeshCount; i++)
{
occlusionMesh.SetTriangles(meshData.submeshes[i].triangles, i);
}
}
public void UpdateMeshData(SkinnedMeshRenderer meshRenderer)
{
meshData = new UMAMeshData();
meshData.RetrieveDataFromUnityMesh(meshRenderer);
#if UNITY_EDITOR
UnityEditor.EditorUtility.SetDirty(this);
#endif
}
public static UMAMeshData ShallowInstanceMesh(UMAMeshData source, BitArray[] triangleMask = null)
{
var target = new UMAMeshData();
target.bindPoses = source.bindPoses;
target.boneNameHashes = source.boneNameHashes;
target.unityBoneWeights = UMABoneWeight.Convert(source.boneWeights);
target.colors32 = source.colors32;
target.normals = source.normals;
target.rootBoneHash = source.rootBoneHash;
target.subMeshCount = source.subMeshCount;
target.tangents = source.tangents;
target.umaBoneCount = source.umaBoneCount;
target.umaBones = source.umaBones;
target.uv = source.uv;
target.uv2 = source.uv2;
target.uv3 = source.uv3;
target.uv4 = source.uv4;
target.vertexCount = source.vertexCount;
target.vertices = source.vertices;
target.blendShapes = source.blendShapes;
if (triangleMask != null)
{
target.submeshes = new SubMeshTriangles[source.subMeshCount];
for (int i = 0; i < source.subMeshCount; i++)
{
int sourceLength = source.submeshes[i].triangles.Length;
int triangleLength = sourceLength - (UMAUtils.GetCardinality(triangleMask[i]) * 3);
int[] destTriangles = new int[triangleLength];
MaskedCopyIntArrayAdd(source.submeshes[i].triangles, 0, destTriangles, 0, sourceLength, 0, triangleMask[i]);
target.submeshes[i].triangles = destTriangles;
}
}
else
{
target.submeshes = source.submeshes;
}
if (source.clothSkinningSerialized != null && source.clothSkinningSerialized.Length != 0)
{
target.clothSkinning = new ClothSkinningCoefficient[source.clothSkinningSerialized.Length];
for (int i = 0; i < source.clothSkinningSerialized.Length; i++)
{
ConvertData(ref source.clothSkinningSerialized[i], ref target.clothSkinning[i]);
}
}
else
{
target.clothSkinning = null;
}
return(target);
}
public void Assign(SlotDataAsset source)
{
slotName = source.slotName;
nameHash = source.nameHash;
material = source.material;
overlayScale = source.overlayScale;
animatedBoneNames = source.animatedBoneNames;
animatedBoneHashes = source.animatedBoneHashes;
meshData = source.meshData;
subMeshIndex = source.subMeshIndex;
slotGroup = source.slotGroup;
tags = source.tags;
}
/// <summary>
/// Updates the UMA mesh and skeleton to match current slots.
/// </summary>
/// <param name="updatedAtlas">If set to <c>true</c> atlas has changed.</param>
/// <param name="umaData">UMA data.</param>
/// <param name="atlasResolution">Atlas resolution.</param>
public override void UpdateUMAMesh(bool updatedAtlas, UMAData umaData, int atlasResolution)
{
this.umaData = umaData;
this.atlasResolution = atlasResolution;
combinedMeshList = new List <SkinnedMeshCombiner.CombineInstance>(umaData.umaRecipe.slotDataList.Length);
combinedMaterialList = new List <Material>();
BuildCombineInstances();
EnsureUMADataSetup(umaData);
umaData.skeleton.BeginSkeletonUpdate();
UMAMeshData umaMesh = new UMAMeshData();
umaMesh.ClaimSharedBuffers();
SkinnedMeshCombiner.CombineMeshes(umaMesh, combinedMeshList.ToArray(), umaData.ignoreBlendShapes);
if (updatedAtlas)
{
RecalculateUV(umaMesh);
}
umaMesh.ApplyDataToUnityMesh(umaData.myRenderer, umaData.skeleton);
umaMesh.ReleaseSharedBuffers();
umaData.umaRecipe.ClearDNAConverters();
for (int i = 0; i < umaData.umaRecipe.slotDataList.Length; i++)
{
SlotData slotData = umaData.umaRecipe.slotDataList[i];
if (slotData != null)
{
// umaData.EnsureBoneData(slotData.umaBoneData, slotData.animatedBones, boneMap);
umaData.umaRecipe.AddDNAUpdater(slotData.asset.slotDNA);
}
}
umaData.myRenderer.quality = SkinQuality.Bone4;
//umaData.myRenderer.useLightProbes = true;
var materials = combinedMaterialList.ToArray();
umaData.myRenderer.sharedMaterials = materials;
//umaData.myRenderer.sharedMesh.RecalculateBounds();
umaData.myRenderer.sharedMesh.name = "UMAMesh";
umaData.firstBake = false;
//FireSlotAtlasNotification(umaData, materials);
}
/*private static void BuildBoneWeights(NativeArray<BoneWeight1> source, NativeArray<BoneWeight1> dest, int destIndex, int destBoneweightIndex, int count, int[] bones, Matrix4x4[] bindPoses, Dictionary<int, BoneIndexEntry> bonesCollection, List<Matrix4x4> bindPosesList, List<int> bonesList)
* {
* int[] boneMapping = new int[bones.Length];
*
* for (int i = 0; i < boneMapping.Length; i++)
* {
* boneMapping[i] = TranslateBoneIndex(i, bones, bindPoses, bonesCollection, bindPosesList, bonesList);
* }
*
* NativeArray<BoneWeight1>.Copy(source, 0, dest, destBoneweightIndex, source.Length);
* BoneWeight1 b = new BoneWeight1();
* for (int i=0;i<source.Length;i++)
* {
* b.boneIndex = boneMapping[source[i].boneIndex];
* b.weight = source[i].weight;
*
* dest[i + destBoneweightIndex] = b;
* }
* } */
private static void BuildBoneWeights(UMAMeshData data, NativeArray <BoneWeight1> dest, NativeArray <byte> destBonesPerVertex, int destIndex, int destBoneweightIndex, int count, int[] bones, Matrix4x4[] bindPoses, Dictionary <int, BoneIndexEntry> bonesCollection, List <Matrix4x4> bindPosesList, List <int> bonesList)
{
int[] boneMapping = new int[bones.Length];
for (int i = 0; i < boneMapping.Length; i++)
{
boneMapping[i] = TranslateBoneIndex(i, bones, bindPoses, bonesCollection, bindPosesList, bonesList);
}
#if USE_NATIVE_ARRAYS
NativeArray <byte> sourceBonesPerIndex = data.unityBonesPerVertex;
int sourcecount = sourceBonesPerIndex.Length;
int destcount = destBonesPerVertex.Length; // should be 0.
NativeArray <byte> .Copy(sourceBonesPerIndex, 0, destBonesPerVertex, destIndex, sourceBonesPerIndex.Length);
NativeArray <BoneWeight1> .Copy(data.unityBoneWeights, 0, dest, destBoneweightIndex, data.unityBoneWeights.Length);
BoneWeight1 b = new BoneWeight1();
for (int i = 0; i < data.unityBoneWeights.Length; i++)
{
b.boneIndex = boneMapping[data.unityBoneWeights[i].boneIndex];
b.weight = data.unityBoneWeights[i].weight;
dest[i + destBoneweightIndex] = b;
}
#else
NativeArray <byte> .Copy(data.ManagedBonesPerVertex, 0, destBonesPerVertex, destIndex, data.ManagedBonesPerVertex.Length);
NativeArray <BoneWeight1> .Copy(data.ManagedBoneWeights, 0, dest, destBoneweightIndex, data.ManagedBoneWeights.Length);
BoneWeight1 b = new BoneWeight1();
for (int i = 0; i < data.ManagedBoneWeights.Length; i++)
{
b.boneIndex = boneMapping[data.ManagedBoneWeights[i].boneIndex];
b.weight = data.ManagedBoneWeights[i].weight;
dest[i + destBoneweightIndex] = b;
}
#endif
}
public void CreateOcclusionMesh(UMAMeshData meshData)
{
if (meshData == null)
{
return;
}
;
if (_occlusionMesh == null)
{
_occlusionMesh = new Mesh();
#if UMA_32BITBUFFERS
_occlusionMesh.indexFormat = UnityEngine.Rendering.IndexFormat.UInt32;
#endif
}
else
{
_occlusionMesh.Clear();
}
_occlusionMesh.subMeshCount = meshData.subMeshCount;
_occlusionMesh.vertices = meshData.vertices;
_occlusionMesh.normals = meshData.normals;
_occlusionMesh.tangents = meshData.tangents;
_occlusionMesh.uv = meshData.uv;
_occlusionMesh.uv2 = meshData.uv2;
_occlusionMesh.uv3 = meshData.uv3;
_occlusionMesh.uv4 = meshData.uv4;
_occlusionMesh.colors32 = meshData.colors32;
_occlusionMesh.triangles = new int[0];
_occlusionMesh.subMeshCount = meshData.subMeshCount;
for (int i = 0; i < meshData.subMeshCount; i++)
{
occlusionMesh.SetTriangles(meshData.submeshes[i].triangles, i);
}
}
public static UMAMeshData ShallowInstanceMesh(UMAMeshData source)
{
var target = new UMAMeshData();
target.bindPoses = source.bindPoses;
target.boneNameHashes = source.boneNameHashes;
target.unityBoneWeights = UMABoneWeight.Convert(source.boneWeights);
target.colors32 = source.colors32;
target.normals = source.normals;
target.rootBoneHash = source.rootBoneHash;
target.subMeshCount = source.subMeshCount;
target.submeshes = source.submeshes;
target.tangents = source.tangents;
target.umaBoneCount = source.umaBoneCount;
target.umaBones = source.umaBones;
target.uv = source.uv;
target.uv2 = source.uv2;
target.uv3 = source.uv3;
target.uv4 = source.uv4;
target.vertexCount = source.vertexCount;
target.vertices = source.vertices;
target.blendShapes = source.blendShapes;
if (source.clothSkinningSerialized != null && source.clothSkinningSerialized.Length != 0)
{
target.clothSkinning = new ClothSkinningCoefficient[source.clothSkinningSerialized.Length];
for (int i = 0; i < source.clothSkinningSerialized.Length; i++)
{
ConvertData(ref source.clothSkinningSerialized[i], ref target.clothSkinning[i]);
}
}
else
{
target.clothSkinning = null;
}
return(target);
}
/// <summary>
/// Creates a deep copy of an UMAMeshData object.
/// </summary>
/// <returns>The new copy of the UMAMeshData</returns>
public UMAMeshData DeepCopy()
{
UMAMeshData newMeshData = new UMAMeshData();
if (bindPoses != null)
{
newMeshData.bindPoses = new Matrix4x4[bindPoses.Length];
Array.Copy(bindPoses, newMeshData.bindPoses, bindPoses.Length);
}
if (boneWeights != null)
{
newMeshData.boneWeights = new UMABoneWeight[boneWeights.Length];
Array.Copy(boneWeights, newMeshData.boneWeights, boneWeights.Length);
}
if (unityBoneWeights != null)
{
newMeshData.unityBoneWeights = new BoneWeight[unityBoneWeights.Length];
Array.Copy(unityBoneWeights, newMeshData.unityBoneWeights, unityBoneWeights.Length);
}
if (vertices != null)
{
newMeshData.vertices = new Vector3[vertices.Length];
Array.Copy(vertices, newMeshData.vertices, vertices.Length);
}
if (normals != null)
{
newMeshData.normals = new Vector3[normals.Length];
Array.Copy(normals, newMeshData.normals, normals.Length);
}
if (tangents != null)
{
newMeshData.tangents = new Vector4[tangents.Length];
Array.Copy(tangents, newMeshData.tangents, tangents.Length);
}
if (colors32 != null)
{
newMeshData.colors32 = new Color32[colors32.Length];
Array.Copy(colors32, newMeshData.colors32, colors32.Length);
}
if (uv != null)
{
newMeshData.uv = new Vector2[uv.Length];
Array.Copy(uv, newMeshData.uv, uv.Length);
}
if (uv2 != null)
{
newMeshData.uv2 = new Vector2[uv2.Length];
Array.Copy(uv2, newMeshData.uv2, uv2.Length);
}
if (uv3 != null)
{
newMeshData.uv3 = new Vector2[uv3.Length];
Array.Copy(uv3, newMeshData.uv3, uv3.Length);
}
if (uv4 != null)
{
newMeshData.uv4 = new Vector2[uv4.Length];
Array.Copy(uv4, newMeshData.uv4, uv4.Length);
}
if (blendShapes != null)
{
newMeshData.blendShapes = new UMABlendShape[blendShapes.Length];
Array.Copy(blendShapes, newMeshData.blendShapes, blendShapes.Length);
}
if (clothSkinning != null)
{
newMeshData.clothSkinning = new ClothSkinningCoefficient[clothSkinning.Length];
Array.Copy(clothSkinning, newMeshData.clothSkinning, clothSkinning.Length);
}
if (clothSkinningSerialized != null)
{
newMeshData.clothSkinningSerialized = new Vector2[clothSkinningSerialized.Length];
Array.Copy(clothSkinningSerialized, newMeshData.clothSkinningSerialized, clothSkinningSerialized.Length);
}
if (submeshes != null)
{
newMeshData.submeshes = new SubMeshTriangles[submeshes.Length];
Array.Copy(submeshes, newMeshData.submeshes, submeshes.Length);
}
if (bones != null)
{
newMeshData.bones = bones.Clone() as Transform[];
}
if (rootBone != null)
{
newMeshData.rootBone = rootBone;
}
if (umaBones != null)
{
newMeshData.umaBones = new UMATransform[umaBones.Length];
Array.Copy(umaBones, newMeshData.umaBones, umaBones.Length);
}
newMeshData.umaBoneCount = umaBoneCount;
newMeshData.rootBoneHash = rootBoneHash;
if (boneNameHashes != null)
{
newMeshData.boneNameHashes = new int[boneNameHashes.Length];
Array.Copy(boneNameHashes, newMeshData.boneNameHashes, boneNameHashes.Length);
}
newMeshData.subMeshCount = subMeshCount;
newMeshData.vertexCount = vertexCount;
newMeshData.RootBoneName = RootBoneName;
return(newMeshData);
}
public bool Equals(UMAMeshData other)
{
return(this == other);
}
protected void RecalculateUV(UMAMeshData umaMesh)
{
int idx = 0;
//Handle Atlassed Verts
for (int materialIndex = 0; materialIndex < umaData.generatedMaterials.materials.Count; materialIndex++)
{
var generatedMaterial = umaData.generatedMaterials.materials[materialIndex];
if (generatedMaterial.rendererAsset != umaData.GetRendererAsset(currentRendererIndex))
{
continue;
}
if (generatedMaterial.umaMaterial.materialType != UMAMaterial.MaterialType.Atlas)
{
var fragment = generatedMaterial.materialFragments[0];
int vertexCount = fragment.slotData.asset.meshData.vertices.Length;
idx += vertexCount;
continue;
}
for (int materialDefinitionIndex = 0; materialDefinitionIndex < generatedMaterial.materialFragments.Count; materialDefinitionIndex++)
{
var fragment = generatedMaterial.materialFragments[materialDefinitionIndex];
var tempAtlasRect = fragment.atlasRegion;
int vertexCount = fragment.slotData.asset.meshData.vertices.Length;
float atlasXMin = tempAtlasRect.xMin / atlasResolution;
float atlasXMax = tempAtlasRect.xMax / atlasResolution;
float atlasXRange = atlasXMax - atlasXMin;
float atlasYMin = tempAtlasRect.yMin / atlasResolution;
float atlasYMax = tempAtlasRect.yMax / atlasResolution;
float atlasYRange = atlasYMax - atlasYMin;
// code below is for UVs remap based on rel pos in the atlas
if (fragment.isRectShared && fragment.slotData.useAtlasOverlay)
{
var foundRect = fragment.overlayList.FirstOrDefault(szname => fragment.slotData.slotName != null && szname.overlayName.Contains(fragment.slotData.slotName));
if (null != foundRect && foundRect.rect != Rect.zero)
{
var size = foundRect.rect.size * generatedMaterial.resolutionScale;
var offsetX = foundRect.rect.x * generatedMaterial.resolutionScale.x;
var offsetY = foundRect.rect.y * generatedMaterial.resolutionScale.y;
atlasXMin += (offsetX / generatedMaterial.cropResolution.x);
atlasXRange = size.x / generatedMaterial.cropResolution.x;
atlasYMin += (offsetY / generatedMaterial.cropResolution.y);
atlasYRange = size.y / generatedMaterial.cropResolution.y;
}
}
while (vertexCount-- > 0)
{
umaMesh.uv[idx].x = atlasXMin + atlasXRange * umaMesh.uv[idx].x;
umaMesh.uv[idx].y = atlasYMin + atlasYRange * umaMesh.uv[idx].y;
idx++;
}
}
}
}
/// <summary>
/// Combines a set of meshes into the target mesh.
/// </summary>
/// <param name="target">Target.</param>
/// <param name="sources">Sources.</param>
public static void CombineMeshes(UMAMeshData target, CombineInstance[] sources, bool ignoreBlendShapes = false)
{
int vertexCount = 0;
int bindPoseCount = 0;
int transformHierarchyCount = 0;
int blendShapeCount = 0;
MeshComponents meshComponents = MeshComponents.none;
int subMeshCount = FindTargetSubMeshCount(sources);
var subMeshTriangleLength = new int[subMeshCount];
AnalyzeSources(sources, subMeshTriangleLength, ref vertexCount, ref bindPoseCount, ref transformHierarchyCount, ref meshComponents, ref blendShapeCount);
int[][] submeshTriangles = new int[subMeshCount][];
for (int i = 0; i < subMeshTriangleLength.Length; i++)
{
submeshTriangles[i] = new int[subMeshTriangleLength[i]];
subMeshTriangleLength[i] = 0;
}
bool has_normals = (meshComponents & MeshComponents.has_normals) != MeshComponents.none;
bool has_tangents = (meshComponents & MeshComponents.has_tangents) != MeshComponents.none;
bool has_uv = (meshComponents & MeshComponents.has_uv) != MeshComponents.none;
bool has_uv2 = (meshComponents & MeshComponents.has_uv2) != MeshComponents.none;
bool has_uv3 = (meshComponents & MeshComponents.has_uv3) != MeshComponents.none;
bool has_uv4 = (meshComponents & MeshComponents.has_uv4) != MeshComponents.none;
bool has_colors32 = (meshComponents & MeshComponents.has_colors32) != MeshComponents.none;
bool has_blendShapes = (meshComponents & MeshComponents.has_blendShapes) != MeshComponents.none;
if (ignoreBlendShapes)
{
has_blendShapes = false;
}
Vector3[] vertices = EnsureArrayLength(target.vertices, vertexCount);
BoneWeight[] boneWeights = EnsureArrayLength(target.unityBoneWeights, vertexCount);
Vector3[] normals = has_normals ? EnsureArrayLength(target.normals, vertexCount) : null;
Vector4[] tangents = has_tangents ? EnsureArrayLength(target.tangents, vertexCount) : null;
Vector2[] uv = has_uv ? EnsureArrayLength(target.uv, vertexCount) : null;
Vector2[] uv2 = has_uv2 ? EnsureArrayLength(target.uv2, vertexCount) : null;
Vector2[] uv3 = has_uv3 ? EnsureArrayLength(target.uv3, vertexCount) : null;
Vector2[] uv4 = has_uv4 ? EnsureArrayLength(target.uv4, vertexCount) : null;
Color32[] colors32 = has_colors32 ? EnsureArrayLength(target.colors32, vertexCount) : null;
UMABlendShape[] blendShapes = has_blendShapes ? new UMABlendShape[blendShapeCount] : null;
UMATransform[] umaTransforms = EnsureArrayLength(target.umaBones, transformHierarchyCount);
int boneCount = 0;
foreach (var source in sources)
{
MergeSortedTransforms(umaTransforms, ref boneCount, source.meshData.umaBones);
}
int vertexIndex = 0;
if (bonesCollection == null)
{
bonesCollection = new Dictionary <int, BoneIndexEntry>(boneCount);
}
else
{
bonesCollection.Clear();
}
if (bindPoses == null)
{
bindPoses = new List <Matrix4x4>(bindPoseCount);
}
else
{
bindPoses.Clear();
}
if (bonesList == null)
{
bonesList = new List <int>(boneCount);
}
else
{
bonesList.Clear();
}
int blendShapeIndex = 0;
foreach (var source in sources)
{
vertexCount = source.meshData.vertices.Length;
BuildBoneWeights(source.meshData.boneWeights, 0, boneWeights, vertexIndex, vertexCount, source.meshData.boneNameHashes, source.meshData.bindPoses, bonesCollection, bindPoses, bonesList);
Array.Copy(source.meshData.vertices, 0, vertices, vertexIndex, vertexCount);
if (has_normals)
{
if (source.meshData.normals != null && source.meshData.normals.Length > 0)
{
Array.Copy(source.meshData.normals, 0, normals, vertexIndex, vertexCount);
}
else
{
FillArray(tangents, vertexIndex, vertexCount, Vector3.zero);
}
}
if (has_tangents)
{
if (source.meshData.tangents != null && source.meshData.tangents.Length > 0)
{
Array.Copy(source.meshData.tangents, 0, tangents, vertexIndex, vertexCount);
}
else
{
FillArray(tangents, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_uv)
{
if (source.meshData.uv != null && source.meshData.uv.Length >= vertexCount)
{
Array.Copy(source.meshData.uv, 0, uv, vertexIndex, vertexCount);
}
else
{
FillArray(uv, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_uv2)
{
if (source.meshData.uv2 != null && source.meshData.uv2.Length >= vertexCount)
{
Array.Copy(source.meshData.uv2, 0, uv2, vertexIndex, vertexCount);
}
else
{
FillArray(uv2, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_uv3)
{
if (source.meshData.uv3 != null && source.meshData.uv3.Length >= vertexCount)
{
Array.Copy(source.meshData.uv3, 0, uv3, vertexIndex, vertexCount);
}
else
{
FillArray(uv3, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_uv4)
{
if (source.meshData.uv4 != null && source.meshData.uv4.Length >= vertexCount)
{
Array.Copy(source.meshData.uv4, 0, uv4, vertexIndex, vertexCount);
}
else
{
FillArray(uv4, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_colors32)
{
if (source.meshData.colors32 != null && source.meshData.colors32.Length > 0)
{
Array.Copy(source.meshData.colors32, 0, colors32, vertexIndex, vertexCount);
}
else
{
Color32 white32 = Color.white;
FillArray(colors32, vertexIndex, vertexCount, white32);
}
}
if (has_blendShapes)
{
if (source.meshData.blendShapes != null && source.meshData.blendShapes.Length > 0)
{
for (int shapeIndex = 0; shapeIndex < source.meshData.blendShapes.Length; shapeIndex++)
{
bool nameAlreadyExists = false;
int i = 0;
//Probably this would be better with a dictionary
for (i = 0; i < blendShapeIndex; i++)
{
if (blendShapes [i].shapeName == source.meshData.blendShapes [shapeIndex].shapeName)
{
nameAlreadyExists = true;
break;
}
}
if (nameAlreadyExists) //Lets add the vertices data to the existing blendShape
{
if (blendShapes [i].frames.Length != source.meshData.blendShapes [shapeIndex].frames.Length)
{
Debug.LogError("SkinnedMeshCombiner: mesh blendShape frame counts don't match!");
break;
}
for (int frameIndex = 0; frameIndex < source.meshData.blendShapes [shapeIndex].frames.Length; frameIndex++)
{
Array.Copy(source.meshData.blendShapes [shapeIndex].frames [frameIndex].deltaVertices, 0, blendShapes [i].frames [frameIndex].deltaVertices, vertexIndex, vertexCount);
Array.Copy(source.meshData.blendShapes [shapeIndex].frames [frameIndex].deltaNormals, 0, blendShapes [i].frames [frameIndex].deltaNormals, vertexIndex, vertexCount);
Array.Copy(source.meshData.blendShapes [shapeIndex].frames [frameIndex].deltaTangents, 0, blendShapes [i].frames [frameIndex].deltaTangents, vertexIndex, vertexCount);
}
}
else
{
blendShapes [blendShapeIndex] = new UMABlendShape();
blendShapes [blendShapeIndex].shapeName = source.meshData.blendShapes [shapeIndex].shapeName;
blendShapes [blendShapeIndex].frames = new UMABlendFrame[source.meshData.blendShapes [shapeIndex].frames.Length];
for (int frameIndex = 0; frameIndex < source.meshData.blendShapes [shapeIndex].frames.Length; frameIndex++)
{
blendShapes [blendShapeIndex].frames [frameIndex] = new UMABlendFrame(vertices.Length);
blendShapes [blendShapeIndex].frames [frameIndex].frameWeight = source.meshData.blendShapes [shapeIndex].frames [frameIndex].frameWeight;
Array.Copy(source.meshData.blendShapes [shapeIndex].frames [frameIndex].deltaVertices, 0, blendShapes [blendShapeIndex].frames [frameIndex].deltaVertices, vertexIndex, vertexCount);
Array.Copy(source.meshData.blendShapes [shapeIndex].frames [frameIndex].deltaNormals, 0, blendShapes [blendShapeIndex].frames [frameIndex].deltaNormals, vertexIndex, vertexCount);
Array.Copy(source.meshData.blendShapes [shapeIndex].frames [frameIndex].deltaTangents, 0, blendShapes [blendShapeIndex].frames [frameIndex].deltaTangents, vertexIndex, vertexCount);
}
blendShapeIndex++;
}
}
}
}
for (int i = 0; i < source.meshData.subMeshCount; i++)
{
if (source.targetSubmeshIndices[i] >= 0)
{
int[] subTriangles = source.meshData.submeshes[i].triangles;
int triangleLength = subTriangles.Length;
int destMesh = source.targetSubmeshIndices[i];
CopyIntArrayAdd(subTriangles, 0, submeshTriangles[destMesh], subMeshTriangleLength[destMesh], triangleLength, vertexIndex);
subMeshTriangleLength[destMesh] += triangleLength;
}
}
vertexIndex += vertexCount;
}
vertexCount = vertexIndex;
// fill in new values.
target.vertexCount = vertexCount;
target.vertices = vertices;
target.unityBoneWeights = boneWeights;
target.bindPoses = bindPoses.ToArray();
target.normals = normals;
target.tangents = tangents;
target.uv = uv;
target.uv2 = uv2;
target.uv3 = uv3;
target.uv4 = uv4;
target.colors32 = colors32;
if (has_blendShapes)
{
target.blendShapes = blendShapes;
}
target.subMeshCount = subMeshCount;
target.submeshes = new SubMeshTriangles[subMeshCount];
target.umaBones = umaTransforms;
target.umaBoneCount = boneCount;
for (int i = 0; i < subMeshCount; i++)
{
target.submeshes[i].triangles = submeshTriangles[i];
}
target.boneNameHashes = bonesList.ToArray();
}
/// <summary>
/// Combines a set of meshes into the target mesh.
/// </summary>
/// <param name="target">Target.</param>
/// <param name="sources">Sources.</param>
/// <param name="blendShapeSettings">BlendShape Settings.</param>
public static void CombineMeshes(UMAMeshData target, CombineInstance[] sources, UMAData.BlendShapeSettings blendShapeSettings = null)
{
if (blendShapeSettings == null)
{
blendShapeSettings = new UMAData.BlendShapeSettings();
}
int vertexCount = 0;
int bindPoseCount = 0;
int transformHierarchyCount = 0;
int blendShapeCount = 0;
MeshComponents meshComponents = MeshComponents.none;
int subMeshCount = FindTargetSubMeshCount(sources);
var subMeshTriangleLength = new int[subMeshCount];
AnalyzeSources(sources, subMeshTriangleLength, ref vertexCount, ref bindPoseCount, ref transformHierarchyCount, ref meshComponents, ref blendShapeCount);
int[][] submeshTriangles = new int[subMeshCount][];
for (int i = 0; i < subMeshTriangleLength.Length; i++)
{
submeshTriangles[i] = target.GetSubmeshBuffer(subMeshTriangleLength[i], i);
subMeshTriangleLength[i] = 0;
}
bool has_normals = (meshComponents & MeshComponents.has_normals) != MeshComponents.none;
bool has_tangents = (meshComponents & MeshComponents.has_tangents) != MeshComponents.none;
bool has_uv = (meshComponents & MeshComponents.has_uv) != MeshComponents.none;
bool has_uv2 = (meshComponents & MeshComponents.has_uv2) != MeshComponents.none;
bool has_uv3 = (meshComponents & MeshComponents.has_uv3) != MeshComponents.none;
bool has_uv4 = (meshComponents & MeshComponents.has_uv4) != MeshComponents.none;
bool has_colors32 = (meshComponents & MeshComponents.has_colors32) != MeshComponents.none;
bool has_blendShapes = (meshComponents & MeshComponents.has_blendShapes) != MeshComponents.none;
if (blendShapeSettings.ignoreBlendShapes)
{
has_blendShapes = false;
}
bool has_clothSkinning = (meshComponents & MeshComponents.has_clothSkinning) != MeshComponents.none;
Vector3[] vertices = EnsureArrayLength(target.vertices, vertexCount);
BoneWeight[] boneWeights = EnsureArrayLength(target.unityBoneWeights, vertexCount);
Vector3[] normals = has_normals ? EnsureArrayLength(target.normals, vertexCount) : null;
Vector4[] tangents = has_tangents ? EnsureArrayLength(target.tangents, vertexCount) : null;
Vector2[] uv = has_uv ? EnsureArrayLength(target.uv, vertexCount) : null;
Vector2[] uv2 = has_uv2 ? EnsureArrayLength(target.uv2, vertexCount) : null;
Vector2[] uv3 = has_uv3 ? EnsureArrayLength(target.uv3, vertexCount) : null;
Vector2[] uv4 = has_uv4 ? EnsureArrayLength(target.uv4, vertexCount) : null;
Color32[] colors32 = has_colors32 ? EnsureArrayLength(target.colors32, vertexCount) : null;
UMABlendShape[] blendShapes = has_blendShapes ? new UMABlendShape[blendShapeCount] : null;
UMATransform[] umaTransforms = EnsureArrayLength(target.umaBones, transformHierarchyCount);
ClothSkinningCoefficient[] clothSkinning = has_clothSkinning ? EnsureArrayLength(target.clothSkinning, vertexCount) : null;
Dictionary <Vector3, int> clothVertices = has_clothSkinning ? new Dictionary <Vector3, int>(vertexCount) : null;
Dictionary <Vector3, int> localClothVertices = has_clothSkinning ? new Dictionary <Vector3, int>(vertexCount) : null;
int boneCount = 0;
foreach (var source in sources)
{
MergeSortedTransforms(umaTransforms, ref boneCount, source.meshData.umaBones);
}
int vertexIndex = 0;
if (bonesCollection == null)
{
bonesCollection = new Dictionary <int, BoneIndexEntry>(boneCount);
}
else
{
bonesCollection.Clear();
}
if (bindPoses == null)
{
bindPoses = new List <Matrix4x4>(bindPoseCount);
}
else
{
bindPoses.Clear();
}
if (bonesList == null)
{
bonesList = new List <int>(boneCount);
}
else
{
bonesList.Clear();
}
int blendShapeIndex = 0;
foreach (var source in sources)
{
int sourceVertexCount = source.meshData.vertices.Length;
BuildBoneWeights(source.meshData.boneWeights, 0, boneWeights, vertexIndex, sourceVertexCount, source.meshData.boneNameHashes, source.meshData.bindPoses, bonesCollection, bindPoses, bonesList);
Array.Copy(source.meshData.vertices, 0, vertices, vertexIndex, sourceVertexCount);
if (has_normals)
{
if (source.meshData.normals != null && source.meshData.normals.Length > 0)
{
Array.Copy(source.meshData.normals, 0, normals, vertexIndex, sourceVertexCount);
}
else
{
FillArray(tangents, vertexIndex, sourceVertexCount, Vector3.zero);
}
}
if (has_tangents)
{
if (source.meshData.tangents != null && source.meshData.tangents.Length > 0)
{
Array.Copy(source.meshData.tangents, 0, tangents, vertexIndex, sourceVertexCount);
}
else
{
FillArray(tangents, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv)
{
if (source.meshData.uv != null && source.meshData.uv.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv, 0, uv, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv2)
{
if (source.meshData.uv2 != null && source.meshData.uv2.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv2, 0, uv2, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv2, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv3)
{
if (source.meshData.uv3 != null && source.meshData.uv3.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv3, 0, uv3, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv3, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv4)
{
if (source.meshData.uv4 != null && source.meshData.uv4.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv4, 0, uv4, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv4, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_colors32)
{
if (source.meshData.colors32 != null && source.meshData.colors32.Length > 0)
{
Array.Copy(source.meshData.colors32, 0, colors32, vertexIndex, sourceVertexCount);
}
else
{
Color32 white32 = Color.white;
FillArray(colors32, vertexIndex, sourceVertexCount, white32);
}
}
if (has_blendShapes)
{
if (source.meshData.blendShapes != null && source.meshData.blendShapes.Length > 0)
{
for (int shapeIndex = 0; shapeIndex < source.meshData.blendShapes.Length; shapeIndex++)
{
#region BlendShape Baking
if (blendShapeSettings.bakeBlendShapes != null && blendShapeSettings.bakeBlendShapes.Count > 0)
{
// If there are names in the bakeBlendShape dictionary and we find them in the meshData blendshape list, then lets bake them instead of adding them.
UMABlendShape currentShape = source.meshData.blendShapes[shapeIndex];
if (blendShapeSettings.bakeBlendShapes.ContainsKey(currentShape.shapeName))
{
float weight = blendShapeSettings.bakeBlendShapes[currentShape.shapeName] * 100.0f;
if (weight <= 0f)
{
continue; // Baking in nothing, so skip it entirely
}
// Let's find the frame this weight is in
int frameIndex;
int prevIndex;
for (frameIndex = 0; frameIndex < currentShape.frames.Length; frameIndex++)
{
if (currentShape.frames[frameIndex].frameWeight >= weight)
{
break;
}
}
// Let's calculate the weight for the frame we're in
float frameWeight = 1f;
float prevWeight = 0f;
bool doLerp = false;
// Weight is higher than the last frame, shape is over 100%
if (frameIndex >= currentShape.frames.Length)
{
frameIndex = currentShape.frames.Length - 1;
frameWeight = (weight / currentShape.frames[frameIndex].frameWeight);
}
else if (frameIndex > 0)
{
doLerp = true;
prevWeight = currentShape.frames[frameIndex - 1].frameWeight;
frameWeight = ((weight - prevWeight) / (currentShape.frames[frameIndex].frameWeight - prevWeight));
prevWeight = 1f - frameWeight;
}
else
{
frameWeight = (weight / currentShape.frames[frameIndex].frameWeight);
}
prevIndex = frameIndex - 1;
// The blend shape frames lerp between the deltas of two adjacent frames.
int vertIndex = vertexIndex;
for (int bakeIndex = 0; bakeIndex < currentShape.frames[frameIndex].deltaVertices.Length; bakeIndex++, vertIndex++)
{
// Add the current frame's deltas
vertices[vertIndex] += currentShape.frames[frameIndex].deltaVertices[bakeIndex] * frameWeight;
// Add in the previous frame's deltas
if (doLerp)
{
vertices[vertIndex] += currentShape.frames[prevIndex].deltaVertices[bakeIndex] * prevWeight;
}
}
if (has_normals)
{
vertIndex = vertexIndex;
for (int bakeIndex = 0; bakeIndex < currentShape.frames[frameIndex].deltaNormals.Length; bakeIndex++, vertIndex++)
{
normals[vertIndex] += currentShape.frames[frameIndex].deltaNormals[bakeIndex] * frameWeight;
if (doLerp)
{
normals[vertIndex] += currentShape.frames[prevIndex].deltaNormals[bakeIndex] * prevWeight;
}
}
}
if (has_tangents)
{
vertIndex = vertexIndex;
for (int bakeIndex = 0; bakeIndex < currentShape.frames[frameIndex].deltaTangents.Length; bakeIndex++, vertIndex++)
{
tangents[vertIndex] += (Vector4)currentShape.frames[frameIndex].deltaTangents[bakeIndex] * frameWeight;
if (doLerp)
{
tangents[vertIndex] += (Vector4)currentShape.frames[prevIndex].deltaTangents[bakeIndex] * prevWeight;
}
}
}
continue; // If we bake then don't perform the rest of this interation of the loop.
}
}
#endregion
bool nameAlreadyExists = false;
int i = 0;
//Probably this would be better with a dictionary
for (i = 0; i < blendShapeIndex; i++)
{
if (blendShapes[i].shapeName == source.meshData.blendShapes[shapeIndex].shapeName)
{
nameAlreadyExists = true;
break;
}
}
if (nameAlreadyExists) //Lets add the vertices data to the existing blendShape
{
if (blendShapes[i].frames.Length != source.meshData.blendShapes[shapeIndex].frames.Length)
{
Debug.LogError("SkinnedMeshCombiner: mesh blendShape frame counts don't match!");
break;
}
for (int frameIndex = 0; frameIndex < source.meshData.blendShapes[shapeIndex].frames.Length; frameIndex++)
{
Array.Copy(source.meshData.blendShapes[shapeIndex].frames[frameIndex].deltaVertices, 0, blendShapes[i].frames[frameIndex].deltaVertices, vertexIndex, sourceVertexCount);
Array.Copy(source.meshData.blendShapes[shapeIndex].frames[frameIndex].deltaNormals, 0, blendShapes[i].frames[frameIndex].deltaNormals, vertexIndex, sourceVertexCount);
Array.Copy(source.meshData.blendShapes[shapeIndex].frames[frameIndex].deltaTangents, 0, blendShapes[i].frames[frameIndex].deltaTangents, vertexIndex, sourceVertexCount);
}
}
else
{
blendShapes[blendShapeIndex] = new UMABlendShape();
blendShapes[blendShapeIndex].shapeName = source.meshData.blendShapes[shapeIndex].shapeName;
blendShapes[blendShapeIndex].frames = new UMABlendFrame[source.meshData.blendShapes[shapeIndex].frames.Length];
for (int frameIndex = 0; frameIndex < source.meshData.blendShapes[shapeIndex].frames.Length; frameIndex++)
{
blendShapes[blendShapeIndex].frames[frameIndex] = new UMABlendFrame(vertexCount);
blendShapes[blendShapeIndex].frames[frameIndex].frameWeight = source.meshData.blendShapes[shapeIndex].frames[frameIndex].frameWeight;
Array.Copy(source.meshData.blendShapes[shapeIndex].frames[frameIndex].deltaVertices, 0, blendShapes[blendShapeIndex].frames[frameIndex].deltaVertices, vertexIndex, sourceVertexCount);
Array.Copy(source.meshData.blendShapes[shapeIndex].frames[frameIndex].deltaNormals, 0, blendShapes[blendShapeIndex].frames[frameIndex].deltaNormals, vertexIndex, sourceVertexCount);
Array.Copy(source.meshData.blendShapes[shapeIndex].frames[frameIndex].deltaTangents, 0, blendShapes[blendShapeIndex].frames[frameIndex].deltaTangents, vertexIndex, sourceVertexCount);
}
blendShapeIndex++;
}
}
}
}
if (has_clothSkinning)
{
localClothVertices.Clear();
if (source.meshData.clothSkinningSerialized != null && source.meshData.clothSkinningSerialized.Length > 0)
{
for (int i = 0; i < source.meshData.vertexCount; i++)
{
var vertice = source.meshData.vertices[i];
if (!localClothVertices.ContainsKey(vertice))
{
int localCount = localClothVertices.Count;
localClothVertices.Add(vertice, localCount);
if (!clothVertices.ContainsKey(vertice))
{
ConvertData(ref source.meshData.clothSkinningSerialized[localCount], ref clothSkinning[clothVertices.Count]);
clothVertices.Add(vertice, clothVertices.Count);
}
else
{
ConvertData(ref source.meshData.clothSkinningSerialized[localCount], ref clothSkinning[clothVertices[vertice]]);
}
}
}
}
else
{
for (int i = 0; i < source.meshData.vertexCount; i++)
{
var vertice = source.meshData.vertices[i];
if (!clothVertices.ContainsKey(vertice))
{
clothSkinning[clothVertices.Count].maxDistance = 0;
clothSkinning[clothVertices.Count].collisionSphereDistance = float.MaxValue;
clothVertices.Add(vertice, clothVertices.Count);
localClothVertices.Add(vertice, clothVertices.Count);
}
}
}
}
for (int i = 0; i < source.meshData.subMeshCount; i++)
{
if (source.targetSubmeshIndices[i] >= 0)
{
int[] subTriangles = source.meshData.submeshes[i].triangles;
int triangleLength = subTriangles.Length;
int destMesh = source.targetSubmeshIndices[i];
if (source.triangleMask == null)
{
CopyIntArrayAdd(subTriangles, 0, submeshTriangles[destMesh], subMeshTriangleLength[destMesh], triangleLength, vertexIndex);
subMeshTriangleLength[destMesh] += triangleLength;
}
else
{
MaskedCopyIntArrayAdd(subTriangles, 0, submeshTriangles[destMesh], subMeshTriangleLength[destMesh], triangleLength, vertexIndex, source.triangleMask[i]);
subMeshTriangleLength[destMesh] += (triangleLength - (UMAUtils.GetCardinality(source.triangleMask[i]) * 3));
}
}
}
vertexIndex += sourceVertexCount;
}
if (vertexCount != vertexIndex)
{
Debug.LogError("Combined vertices size didn't match precomputed value!");
}
// fill in new values.
target.vertexCount = vertexCount;
target.vertices = vertices;
target.unityBoneWeights = boneWeights;
target.bindPoses = bindPoses.ToArray();
target.normals = normals;
target.tangents = tangents;
target.uv = uv;
target.uv2 = uv2;
target.uv3 = uv3;
target.uv4 = uv4;
target.colors32 = colors32;
if (has_blendShapes)
{
target.blendShapes = blendShapes;
}
if (has_clothSkinning)
{
Array.Resize(ref clothSkinning, clothVertices.Count);
}
target.clothSkinning = clothSkinning;
target.subMeshCount = subMeshCount;
target.submeshes = new SubMeshTriangles[subMeshCount];
target.umaBones = umaTransforms;
target.umaBoneCount = boneCount;
for (int i = 0; i < subMeshCount; i++)
{
target.submeshes[i].triangles = submeshTriangles[i];
}
target.boneNameHashes = bonesList.ToArray();
}
public void Initialize()
{
gameObject.name = "GeometrySelector";
if (_sharedMesh == null)
{
if (Debug.isDebugBuild)
{
Debug.LogWarning("GeometrySelector: Initializing with no mesh!");
}
return;
}
if (meshAsset != null)
{
UMAMeshData meshData = meshAsset.asset.meshData;
/* Todo: figure out how to get the races root bone orientation
* Transform root = meshData.rootBone;
* if (root == null)
* {
* SkeletonTools.RecursiveFindBone(meshData.bones[0],"Global");
* }
*/
if (meshData.rootBoneHash == UMAUtils.StringToHash("Global"))
{
gameObject.transform.localRotation = Quaternion.Euler(-90f, 0f, 0f);
}
}
gameObject.transform.hideFlags = HideFlags.NotEditable | HideFlags.HideInInspector;
if (selectedTriangles == null)
{
selectedTriangles = new BitArray(_sharedMesh.triangles.Length / 3);
}
if (!gameObject.GetComponent <MeshFilter>())
{
MeshFilter meshFilter = gameObject.AddComponent <MeshFilter>();
meshFilter.mesh = _sharedMesh;
meshFilter.hideFlags = HideFlags.HideInInspector;
}
if (!gameObject.GetComponent <MeshRenderer>())
{
_meshRenderer = gameObject.AddComponent <MeshRenderer>();
_meshRenderer.shadowCastingMode = UnityEngine.Rendering.ShadowCastingMode.Off;
_meshRenderer.receiveShadows = false;
_meshRenderer.hideFlags = HideFlags.HideInInspector;
}
if (!gameObject.GetComponent <MeshCollider>())
{
_meshCollider = gameObject.AddComponent <MeshCollider>();
_meshCollider.convex = false;
_meshCollider.sharedMesh = _sharedMesh;
_meshCollider.hideFlags = HideFlags.HideInInspector;
}
if (GraphicsSettings.renderPipelineAsset == null)
{
_Shader = Shader.Find("Standard");
}
else
{
//Expand this to find shaders that work with other SRPs in the future.
_Shader = Shader.Find("Unlit/Color");
}
if (_Materials == null && _Shader != null)
{
_Materials = new Material[2];
//Selected
_Materials[1] = new Material(_Shader);
_Materials[1].name = "Selected";
_Materials[1].color = Color.red;
//UnSelected
_Materials[0] = new Material(_Shader);
_Materials[0].name = "UnSelected";
_Materials[0].color = Color.gray;
_sharedMesh.subMeshCount = 2;
_meshRenderer.sharedMaterials = _Materials;
_meshRenderer.sharedMaterials[0].hideFlags = HideFlags.HideInInspector;
_meshRenderer.sharedMaterials[1].hideFlags = HideFlags.HideInInspector;
}
}
/// <summary>
/// Updates the UMA mesh and skeleton to match current slots.
/// </summary>
/// <param name="updatedAtlas">If set to <c>true</c> atlas has changed.</param>
/// <param name="umaData">UMA data.</param>
/// <param name="atlasResolution">Atlas resolution.</param>
public override void UpdateUMAMesh(bool updatedAtlas, UMAData umaData, int atlasResolution)
{
this.umaData = umaData;
this.atlasResolution = atlasResolution;
combinedMeshList = new List <SkinnedMeshCombiner.CombineInstance>(umaData.umaRecipe.slotDataList.Length);
combinedMaterialList = new List <Material>();
EnsureUMADataSetup(umaData);
umaData.skeleton.BeginSkeletonUpdate();
for (currentRendererIndex = 0; currentRendererIndex < umaData.generatedMaterials.rendererCount; currentRendererIndex++)
{
//Move umaMesh creation to with in the renderer loops
//May want to make sure to set all it's buffers to null instead of creating a new UMAMeshData
UMAMeshData umaMesh = new UMAMeshData();
umaMesh.ClaimSharedBuffers();
umaMesh.subMeshCount = 0;
umaMesh.vertexCount = 0;
combinedMeshList.Clear();
combinedMaterialList.Clear();
clothProperties = null;
BuildCombineInstances();
if (combinedMeshList.Count == 1)
{
// fast track
var tempMesh = SkinnedMeshCombiner.ShallowInstanceMesh(combinedMeshList[0].meshData);
tempMesh.ApplyDataToUnityMesh(renderers[currentRendererIndex], umaData.skeleton);
}
else
{
SkinnedMeshCombiner.CombineMeshes(umaMesh, combinedMeshList.ToArray(), umaData.blendShapeSettings);
if (updatedAtlas)
{
RecalculateUV(umaMesh);
}
umaMesh.ApplyDataToUnityMesh(renderers[currentRendererIndex], umaData.skeleton);
}
var cloth = renderers[currentRendererIndex].GetComponent <Cloth>();
if (clothProperties != null)
{
if (cloth != null)
{
clothProperties.ApplyValues(cloth);
}
}
else
{
Destroy(cloth);
}
var materials = combinedMaterialList.ToArray();
renderers[currentRendererIndex].sharedMaterials = materials;
umaMesh.ReleaseSharedBuffers();
}
umaData.umaRecipe.ClearDNAConverters();
for (int i = 0; i < umaData.umaRecipe.slotDataList.Length; i++)
{
SlotData slotData = umaData.umaRecipe.slotDataList[i];
if (slotData != null)
{
umaData.umaRecipe.AddDNAUpdater(slotData.asset.slotDNA);
}
}
umaData.firstBake = false;
}
/// <summary>
/// Claims the static buffers.
/// </summary>
/// <returns><c>true</c>, if shared buffers were claimed, <c>false</c> otherwise.</returns>
public bool ClaimSharedBuffers()
{
if (!buffersInitialized)
{
buffersInitialized = true;
haveBackingArrays = true;
gVerticesArray = gVertices.GetBackingArray();
if (gVerticesArray == null)
{
haveBackingArrays = false;
}
gNormalsArray = gNormals.GetBackingArray();
if (gNormalsArray == null)
{
haveBackingArrays = false;
}
gTangentsArray = gTangents.GetBackingArray();
if (gTangentsArray == null)
{
haveBackingArrays = false;
}
gUVArray = gUV.GetBackingArray();
if (gUVArray == null)
{
haveBackingArrays = false;
}
gUV2Array = gUV2.GetBackingArray();
if (gUV2Array == null)
{
haveBackingArrays = false;
}
gUV3Array = gUV3.GetBackingArray();
if (gUV3Array == null)
{
haveBackingArrays = false;
}
gUV4Array = gUV4.GetBackingArray();
if (gUV4Array == null)
{
haveBackingArrays = false;
}
gColors32Array = gColors32.GetBackingArray();
if (gColors32Array == null)
{
haveBackingArrays = false;
}
gSubmeshTriIndices = new int[gSubmeshTris.Length];
gSubmeshTriArrays = new int[gSubmeshTris.Length][];
for (int i = 0; i < gSubmeshTris.Length; i++)
{
gSubmeshTriIndices[i] = UNUSED_SUBMESH;
gSubmeshTriArrays[i] = gSubmeshTris[i].GetBackingArray();
if (gSubmeshTriArrays[i] == null)
{
haveBackingArrays = false;
}
}
if (haveBackingArrays == false)
{
if (Debug.isDebugBuild)
{
Debug.LogError("Unable to access backing arrays for shared UMAMeshData!");
}
}
}
if (!haveBackingArrays)
{
return(false);
}
if (bufferLockOwner == null)
{
bufferLockOwner = this;
vertices = gVerticesArray;
normals = gNormalsArray;
tangents = gTangentsArray;
uv = gUVArray;
uv2 = gUV2Array;
uv3 = gUV3Array;
uv4 = gUV4Array;
colors32 = gColors32Array;
boneWeights = null;
#if USE_UNSAFE_CODE
unityBoneWeights = gBoneWeightsArray;
#endif
return(true);
}
if (Debug.isDebugBuild)
{
Debug.LogWarning("Unable to claim UMAMeshData global buffers!");
}
return(false);
}
/// <summary>
/// Combines a set of meshes into the target mesh.
/// </summary>
/// <param name="target">Target.</param>
/// <param name="sources">Sources.</param>
/// <param name="blendShapeSettings">BlendShape Settings.</param>
public static void CombineMeshes(UMAMeshData target, CombineInstance[] sources, BlendShapeSettings blendShapeSettings = null)
{
if (blendShapeSettings == null)
{
blendShapeSettings = new BlendShapeSettings();
}
int vertexCount = 0;
int bindPoseCount = 0;
int transformHierarchyCount = 0;
Dictionary <string, BlendShapeVertexData> blendShapeNames = new Dictionary <string, BlendShapeVertexData>();
MeshComponents meshComponents = MeshComponents.none;
int subMeshCount = FindTargetSubMeshCount(sources);
var subMeshTriangleLength = new int[subMeshCount];
AnalyzeSources(sources, subMeshTriangleLength, ref vertexCount, ref bindPoseCount, ref transformHierarchyCount, ref meshComponents);
if (!blendShapeSettings.ignoreBlendShapes)
{
AnalyzeBlendShapeSources(sources, blendShapeSettings, ref meshComponents, out blendShapeNames);
}
int[][] submeshTriangles = new int[subMeshCount][];
for (int i = 0; i < subMeshTriangleLength.Length; i++)
{
submeshTriangles[i] = target.GetSubmeshBuffer(subMeshTriangleLength[i], i);
subMeshTriangleLength[i] = 0;
}
bool has_normals = (meshComponents & MeshComponents.has_normals) != MeshComponents.none;
bool has_tangents = (meshComponents & MeshComponents.has_tangents) != MeshComponents.none;
bool has_uv = (meshComponents & MeshComponents.has_uv) != MeshComponents.none;
bool has_uv2 = (meshComponents & MeshComponents.has_uv2) != MeshComponents.none;
bool has_uv3 = (meshComponents & MeshComponents.has_uv3) != MeshComponents.none;
bool has_uv4 = (meshComponents & MeshComponents.has_uv4) != MeshComponents.none;
bool has_colors32 = (meshComponents & MeshComponents.has_colors32) != MeshComponents.none;
bool has_blendShapes = (meshComponents & MeshComponents.has_blendShapes) != MeshComponents.none;
if (blendShapeSettings.ignoreBlendShapes)
{
has_blendShapes = false;
}
bool has_clothSkinning = (meshComponents & MeshComponents.has_clothSkinning) != MeshComponents.none;
#if UNITY_2019_3_OR_NEWER
if (nativeBoneWeights.Length < vertexCount)
{
if (nativeBoneWeights.IsCreated)
{
nativeBoneWeights.Dispose();
}
nativeBoneWeights = new NativeArray <BoneWeight>(vertexCount, Allocator.Persistent);
}
#else
BoneWeight[] boneWeights = EnsureArrayLength(target.unityBoneWeights, vertexCount);
#endif
Vector3[] vertices = EnsureArrayLength(target.vertices, vertexCount);
Vector3[] normals = has_normals ? EnsureArrayLength(target.normals, vertexCount) : null;
Vector4[] tangents = has_tangents ? EnsureArrayLength(target.tangents, vertexCount) : null;
Vector2[] uv = has_uv ? EnsureArrayLength(target.uv, vertexCount) : null;
Vector2[] uv2 = has_uv2 ? EnsureArrayLength(target.uv2, vertexCount) : null;
Vector2[] uv3 = has_uv3 ? EnsureArrayLength(target.uv3, vertexCount) : null;
Vector2[] uv4 = has_uv4 ? EnsureArrayLength(target.uv4, vertexCount) : null;
Color32[] colors32 = has_colors32 ? EnsureArrayLength(target.colors32, vertexCount) : null;
UMABlendShape[] blendShapes = has_blendShapes ? new UMABlendShape[blendShapeNames.Keys.Count] : null;
UMATransform[] umaTransforms = EnsureArrayLength(target.umaBones, transformHierarchyCount);
ClothSkinningCoefficient[] clothSkinning = has_clothSkinning ? EnsureArrayLength(target.clothSkinning, vertexCount) : null;
Dictionary <Vector3, int> clothVertices = has_clothSkinning ? new Dictionary <Vector3, int>(vertexCount) : null;
Dictionary <Vector3, int> localClothVertices = has_clothSkinning ? new Dictionary <Vector3, int>(vertexCount) : null;
InitializeBlendShapeData(ref vertexCount, blendShapeNames, blendShapes);
int boneCount = 0;
foreach (var source in sources)
{
MergeSortedTransforms(umaTransforms, ref boneCount, source.meshData.umaBones);
}
int vertexIndex = 0;
if (bonesCollection == null)
{
bonesCollection = new Dictionary <int, BoneIndexEntry>(boneCount);
}
else
{
bonesCollection.Clear();
}
if (bindPoses == null)
{
bindPoses = new List <Matrix4x4>(bindPoseCount);
}
else
{
bindPoses.Clear();
}
if (bonesList == null)
{
bonesList = new List <int>(boneCount);
}
else
{
bonesList.Clear();
}
foreach (var source in sources)
{
int sourceVertexCount = source.meshData.vertices.Length;
#if UNITY_2019_3_OR_NEWER
BuildBoneWeights(source.meshData.boneWeights, 0, nativeBoneWeights, vertexIndex, sourceVertexCount, source.meshData.boneNameHashes, source.meshData.bindPoses, bonesCollection, bindPoses, bonesList);
#else
BuildBoneWeights(source.meshData.boneWeights, 0, boneWeights, vertexIndex, sourceVertexCount, source.meshData.boneNameHashes, source.meshData.bindPoses, bonesCollection, bindPoses, bonesList);
#endif
Array.Copy(source.meshData.vertices, 0, vertices, vertexIndex, sourceVertexCount);
if (has_normals)
{
if (source.meshData.normals != null && source.meshData.normals.Length > 0)
{
Array.Copy(source.meshData.normals, 0, normals, vertexIndex, sourceVertexCount);
}
else
{
FillArray(tangents, vertexIndex, sourceVertexCount, Vector3.zero);
}
}
if (has_tangents)
{
if (source.meshData.tangents != null && source.meshData.tangents.Length > 0)
{
Array.Copy(source.meshData.tangents, 0, tangents, vertexIndex, sourceVertexCount);
}
else
{
FillArray(tangents, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv)
{
if (source.meshData.uv != null && source.meshData.uv.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv, 0, uv, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv2)
{
if (source.meshData.uv2 != null && source.meshData.uv2.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv2, 0, uv2, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv2, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv3)
{
if (source.meshData.uv3 != null && source.meshData.uv3.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv3, 0, uv3, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv3, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_uv4)
{
if (source.meshData.uv4 != null && source.meshData.uv4.Length >= sourceVertexCount)
{
Array.Copy(source.meshData.uv4, 0, uv4, vertexIndex, sourceVertexCount);
}
else
{
FillArray(uv4, vertexIndex, sourceVertexCount, Vector4.zero);
}
}
if (has_colors32)
{
if (source.meshData.colors32 != null && source.meshData.colors32.Length > 0)
{
Array.Copy(source.meshData.colors32, 0, colors32, vertexIndex, sourceVertexCount);
}
else
{
Color32 white32 = Color.white;
FillArray(colors32, vertexIndex, sourceVertexCount, white32);
}
}
if (has_blendShapes)
{
if (source.meshData.blendShapes != null && source.meshData.blendShapes.Length > 0)
{
int sourceBlendShapeLength = source.meshData.blendShapes.Length;
for (int shapeIndex = 0; shapeIndex < sourceBlendShapeLength; shapeIndex++)
{
string shapeName = source.meshData.blendShapes[shapeIndex].shapeName;
//If we aren't loading all blendshapes and we don't find the blendshape name in the list of explicit blendshapes to combine, then skip to the next one.
if (!blendShapeSettings.loadAllBlendShapes && !blendShapeSettings.blendShapes.ContainsKey(shapeName))
{
continue;
}
#region BlendShape Baking
if (BakeBlendShape(blendShapeSettings.blendShapes, source.meshData.blendShapes[shapeIndex], ref vertexIndex, vertices, normals, tangents, has_normals, has_tangents))
{
continue; //If we baked this blendshape, then continue to the next one and skip adding the regular blendshape.
}
#endregion
//If our dictionary contains the shape name, which it should
if (blendShapeNames.ContainsKey(shapeName))
{
UMABlendShape[] sourceBlendShapes = source.meshData.blendShapes;
int i = blendShapeNames[shapeName].index;
if (blendShapes[i].frames.Length != sourceBlendShapes[shapeIndex].frames.Length)
{
if (Debug.isDebugBuild)
{
Debug.LogError("SkinnedMeshCombiner: mesh blendShape frame counts don't match!");
}
break;
}
for (int frameIndex = 0; frameIndex < sourceBlendShapes[shapeIndex].frames.Length; frameIndex++)
{
Array.Copy(sourceBlendShapes[shapeIndex].frames[frameIndex].deltaVertices, 0, blendShapes[i].frames[frameIndex].deltaVertices, vertexIndex, sourceVertexCount);
Vector3[] sourceDeltaNormals = sourceBlendShapes[shapeIndex].frames[frameIndex].deltaNormals;
Vector3[] sourceDeltaTangents = sourceBlendShapes[shapeIndex].frames[frameIndex].deltaTangents;
//if out dictionary says at least one source has normals or tangents and the current source has normals or tangents then copy them.
if (blendShapeNames[shapeName].hasNormals && sourceDeltaNormals.Length > 0)
{
Array.Copy(sourceDeltaNormals, 0, blendShapes[i].frames[frameIndex].deltaNormals, vertexIndex, sourceVertexCount);
}
if (blendShapeNames[shapeName].hasTangents && sourceDeltaTangents.Length > 0)
{
Array.Copy(sourceDeltaTangents, 0, blendShapes[i].frames[frameIndex].deltaTangents, vertexIndex, sourceVertexCount);
}
}
}
else
{
if (Debug.isDebugBuild)
{
Debug.LogError("BlendShape " + shapeName + " not found in dictionary!");
}
}
}
}
}
if (has_clothSkinning)
{
localClothVertices.Clear();
if (source.meshData.clothSkinningSerialized != null && source.meshData.clothSkinningSerialized.Length > 0)
{
for (int i = 0; i < source.meshData.vertexCount; i++)
{
var vertice = source.meshData.vertices[i];
if (!localClothVertices.ContainsKey(vertice))
{
int localCount = localClothVertices.Count;
localClothVertices.Add(vertice, localCount);
if (!clothVertices.ContainsKey(vertice))
{
ConvertData(ref source.meshData.clothSkinningSerialized[localCount], ref clothSkinning[clothVertices.Count]);
clothVertices.Add(vertice, clothVertices.Count);
}
else
{
ConvertData(ref source.meshData.clothSkinningSerialized[localCount], ref clothSkinning[clothVertices[vertice]]);
}
}
}
}
else
{
for (int i = 0; i < source.meshData.vertexCount; i++)
{
var vertice = source.meshData.vertices[i];
if (!clothVertices.ContainsKey(vertice))
{
clothSkinning[clothVertices.Count].maxDistance = 0;
clothSkinning[clothVertices.Count].collisionSphereDistance = float.MaxValue;
clothVertices.Add(vertice, clothVertices.Count);
localClothVertices.Add(vertice, clothVertices.Count);
}
}
}
}
for (int i = 0; i < source.meshData.subMeshCount; i++)
{
if (source.targetSubmeshIndices[i] >= 0)
{
int[] subTriangles = source.meshData.submeshes[i].triangles;
int triangleLength = subTriangles.Length;
int destMesh = source.targetSubmeshIndices[i];
if (source.triangleMask == null)
{
CopyIntArrayAdd(subTriangles, 0, submeshTriangles[destMesh], subMeshTriangleLength[destMesh], triangleLength, vertexIndex);
subMeshTriangleLength[destMesh] += triangleLength;
}
else
{
MaskedCopyIntArrayAdd(subTriangles, 0, submeshTriangles[destMesh], subMeshTriangleLength[destMesh], triangleLength, vertexIndex, source.triangleMask[i]);
subMeshTriangleLength[destMesh] += (triangleLength - (UMAUtils.GetCardinality(source.triangleMask[i]) * 3));
}
}
}
vertexIndex += sourceVertexCount;
}
if (vertexCount != vertexIndex)
{
if (Debug.isDebugBuild)
{
Debug.LogError("Combined vertices size didn't match precomputed value!");
}
}
// fill in new values.
target.vertexCount = vertexCount;
target.vertices = vertices;
#if UNITY_2019_3_OR_NEWER
target.unityBoneWeights = nativeBoneWeights.GetSubArray(0, vertexCount).ToArray();
#else
target.unityBoneWeights = boneWeights;
#endif
target.bindPoses = bindPoses.ToArray();
target.normals = normals;
target.tangents = tangents;
target.uv = uv;
target.uv2 = uv2;
target.uv3 = uv3;
target.uv4 = uv4;
target.colors32 = colors32;
if (has_blendShapes)
{
target.blendShapes = blendShapes;
}
if (has_clothSkinning)
{
Array.Resize(ref clothSkinning, clothVertices.Count);
}
target.clothSkinning = clothSkinning;
target.subMeshCount = subMeshCount;
target.submeshes = new SubMeshTriangles[subMeshCount];
target.umaBones = umaTransforms;
target.umaBoneCount = boneCount;
for (int i = 0; i < subMeshCount; i++)
{
target.submeshes[i].triangles = submeshTriangles[i];
}
target.boneNameHashes = bonesList.ToArray();
}
/// <summary>
/// Combines a set of meshes into the target mesh.
/// </summary>
/// <param name="target">Target.</param>
/// <param name="sources">Sources.</param>
public static void CombineMeshes(UMAMeshData target, CombineInstance[] sources)
{
int vertexCount = 0;
int bindPoseCount = 0;
int transformHierarchyCount = 0;
MeshComponents meshComponents = MeshComponents.none;
int subMeshCount = FindTargetSubMeshCount(sources);
var subMeshTriangleLength = new int[subMeshCount];
AnalyzeSources(sources, subMeshTriangleLength, ref vertexCount, ref bindPoseCount, ref transformHierarchyCount, ref meshComponents);
int[][] submeshTriangles = new int[subMeshCount][];
for (int i = 0; i < subMeshTriangleLength.Length; i++)
{
submeshTriangles[i] = new int[subMeshTriangleLength[i]];
subMeshTriangleLength[i] = 0;
}
bool has_normals = (meshComponents & MeshComponents.has_normals) != MeshComponents.none;
bool has_tangents = (meshComponents & MeshComponents.has_tangents) != MeshComponents.none;
bool has_uv = (meshComponents & MeshComponents.has_uv) != MeshComponents.none;
bool has_uv2 = (meshComponents & MeshComponents.has_uv2) != MeshComponents.none;
#if !UNITY_4_6
bool has_uv3 = (meshComponents & MeshComponents.has_uv3) != MeshComponents.none;
bool has_uv4 = (meshComponents & MeshComponents.has_uv4) != MeshComponents.none;
#endif
bool has_colors32 = (meshComponents & MeshComponents.has_colors32) != MeshComponents.none;
Vector3[] vertices = EnsureArrayLength(target.vertices, vertexCount);
BoneWeight[] boneWeights = EnsureArrayLength(target.unityBoneWeights, vertexCount);
Vector3[] normals = has_normals ? EnsureArrayLength(target.normals, vertexCount) : null;
Vector4[] tangents = has_tangents ? EnsureArrayLength(target.tangents, vertexCount) : null;
Vector2[] uv = has_uv ? EnsureArrayLength(target.uv, vertexCount) : null;
Vector2[] uv2 = has_uv2 ? EnsureArrayLength(target.uv2, vertexCount) : null;
#if !UNITY_4_6
Vector2[] uv3 = has_uv3 ? EnsureArrayLength(target.uv3, vertexCount) : null;
Vector2[] uv4 = has_uv4 ? EnsureArrayLength(target.uv4, vertexCount) : null;
#endif
Color32[] colors32 = has_colors32 ? EnsureArrayLength(target.colors32, vertexCount) : null;
UMATransform[] umaTransforms = EnsureArrayLength(target.umaBones, transformHierarchyCount);
int boneCount = 0;
foreach (var source in sources)
{
MergeSortedTransforms(umaTransforms, ref boneCount, source.meshData.umaBones);
}
int vertexIndex = 0;
if (bonesCollection == null)
{
bonesCollection = new Dictionary <int, BoneIndexEntry>(boneCount);
}
else
{
bonesCollection.Clear();
}
if (bindPoses == null)
{
bindPoses = new List <Matrix4x4>(bindPoseCount);
}
else
{
bindPoses.Clear();
}
if (bonesList == null)
{
bonesList = new List <int>(boneCount);
}
else
{
bonesList.Clear();
}
foreach (var source in sources)
{
vertexCount = source.meshData.vertices.Length;
BuildBoneWeights(source.meshData.boneWeights, 0, boneWeights, vertexIndex, vertexCount, source.meshData.boneNameHashes, source.meshData.bindPoses, bonesCollection, bindPoses, bonesList);
Array.Copy(source.meshData.vertices, 0, vertices, vertexIndex, vertexCount);
if (has_normals)
{
if (source.meshData.normals != null && source.meshData.normals.Length > 0)
{
Array.Copy(source.meshData.normals, 0, normals, vertexIndex, vertexCount);
}
else
{
FillArray(tangents, vertexIndex, vertexCount, Vector3.zero);
}
}
if (has_tangents)
{
if (source.meshData.tangents != null && source.meshData.tangents.Length > 0)
{
Array.Copy(source.meshData.tangents, 0, tangents, vertexIndex, vertexCount);
}
else
{
FillArray(tangents, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_uv)
{
if (source.meshData.uv != null && source.meshData.uv.Length >= vertexCount)
{
Array.Copy(source.meshData.uv, 0, uv, vertexIndex, vertexCount);
}
else
{
FillArray(uv, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_uv2)
{
if (source.meshData.uv2 != null && source.meshData.uv2.Length >= vertexCount)
{
Array.Copy(source.meshData.uv2, 0, uv2, vertexIndex, vertexCount);
}
else
{
FillArray(uv2, vertexIndex, vertexCount, Vector4.zero);
}
}
#if !UNITY_4_6
if (has_uv3)
{
if (source.meshData.uv3 != null && source.meshData.uv3.Length >= vertexCount)
{
Array.Copy(source.meshData.uv3, 0, uv3, vertexIndex, vertexCount);
}
else
{
FillArray(uv3, vertexIndex, vertexCount, Vector4.zero);
}
}
if (has_uv4)
{
if (source.meshData.uv4 != null && source.meshData.uv4.Length >= vertexCount)
{
Array.Copy(source.meshData.uv4, 0, uv4, vertexIndex, vertexCount);
}
else
{
FillArray(uv4, vertexIndex, vertexCount, Vector4.zero);
}
}
#endif
if (has_colors32)
{
if (source.meshData.colors32 != null && source.meshData.colors32.Length > 0)
{
Array.Copy(source.meshData.colors32, 0, colors32, vertexIndex, vertexCount);
}
else
{
Color32 white32 = Color.white;
FillArray(colors32, vertexIndex, vertexCount, white32);
}
}
for (int i = 0; i < source.meshData.subMeshCount; i++)
{
if (source.targetSubmeshIndices[i] >= 0)
{
int[] subTriangles = source.meshData.submeshes[i].triangles;
int triangleLength = subTriangles.Length;
int destMesh = source.targetSubmeshIndices[i];
CopyIntArrayAdd(subTriangles, 0, submeshTriangles[destMesh], subMeshTriangleLength[destMesh], triangleLength, vertexIndex);
subMeshTriangleLength[destMesh] += triangleLength;
}
}
vertexIndex += vertexCount;
}
vertexCount = vertexIndex;
// fill in new values.
target.vertexCount = vertexCount;
target.vertices = vertices;
target.unityBoneWeights = boneWeights;
target.bindPoses = bindPoses.ToArray();
target.normals = normals;
target.tangents = tangents;
target.uv = uv;
target.uv2 = uv2;
#if !UNITY_4_6
target.uv3 = uv3;
target.uv4 = uv4;
#endif
target.colors32 = colors32;
target.subMeshCount = subMeshCount;
target.submeshes = new SubMeshTriangles[subMeshCount];
target.umaBones = umaTransforms;
target.umaBoneCount = boneCount;
for (int i = 0; i < subMeshCount; i++)
{
target.submeshes[i].triangles = submeshTriangles[i];
}
target.boneNameHashes = bonesList.ToArray();
}
