Assignment for RMIT Mixed Reality in 2020
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using System;
using Oculus.Avatar;
using UnityEngine;
using System.Runtime.InteropServices;
public class OvrAvatarAssetMesh : OvrAvatarAsset
{
public Mesh mesh;
private ovrAvatarSkinnedMeshPose skinnedBindPose;
public string[] jointNames;
public OvrAvatarAssetMesh(UInt64 _assetId, IntPtr asset, ovrAvatarAssetType meshType)
{
assetID = _assetId;
mesh = new Mesh();
mesh.name = "Procedural Geometry for asset " + _assetId;
SetSkinnedBindPose(asset, meshType);
long vertexCount = 0;
IntPtr vertexBuffer = IntPtr.Zero;
uint indexCount = 0;
IntPtr indexBuffer = IntPtr.Zero;
GetVertexAndIndexData(asset, meshType, out vertexCount, out vertexBuffer, out indexCount, out indexBuffer);
AvatarLogger.Log("OvrAvatarAssetMesh: " + _assetId + " " + meshType.ToString() + " VertexCount:" + vertexCount);
Vector3[] vertices = new Vector3[vertexCount];
Vector3[] normals = new Vector3[vertexCount];
Vector4[] tangents = new Vector4[vertexCount];
Vector2[] uv = new Vector2[vertexCount];
Color[] colors = new Color[vertexCount];
BoneWeight[] boneWeights = new BoneWeight[vertexCount];
long vertexBufferStart = vertexBuffer.ToInt64();
// We have different underlying vertex types to unpack, so switch on mesh type.
switch (meshType)
{
case ovrAvatarAssetType.Mesh:
{
long vertexSize = (long)Marshal.SizeOf(typeof(ovrAvatarMeshVertex));
for (long i = 0; i < vertexCount; i++)
{
long offset = vertexSize * i;
ovrAvatarMeshVertex vertex = (ovrAvatarMeshVertex)Marshal.PtrToStructure(new IntPtr(vertexBufferStart + offset), typeof(ovrAvatarMeshVertex));
vertices[i] = new Vector3(vertex.x, vertex.y, -vertex.z);
normals[i] = new Vector3(vertex.nx, vertex.ny, -vertex.nz);
tangents[i] = new Vector4(vertex.tx, vertex.ty, -vertex.tz, vertex.tw);
uv[i] = new Vector2(vertex.u, vertex.v);
colors[i] = new Color(0, 0, 0, 1);
boneWeights[i].boneIndex0 = vertex.blendIndices[0];
boneWeights[i].boneIndex1 = vertex.blendIndices[1];
boneWeights[i].boneIndex2 = vertex.blendIndices[2];
boneWeights[i].boneIndex3 = vertex.blendIndices[3];
boneWeights[i].weight0 = vertex.blendWeights[0];
boneWeights[i].weight1 = vertex.blendWeights[1];
boneWeights[i].weight2 = vertex.blendWeights[2];
boneWeights[i].weight3 = vertex.blendWeights[3];
}
}
break;
case ovrAvatarAssetType.CombinedMesh:
{
long vertexSize = (long)Marshal.SizeOf(typeof(ovrAvatarMeshVertexV2));
for (long i = 0; i < vertexCount; i++)
{
long offset = vertexSize * i;
ovrAvatarMeshVertexV2 vertex = (ovrAvatarMeshVertexV2)Marshal.PtrToStructure(new IntPtr(vertexBufferStart + offset), typeof(ovrAvatarMeshVertexV2));
vertices[i] = new Vector3(vertex.x, vertex.y, -vertex.z);
normals[i] = new Vector3(vertex.nx, vertex.ny, -vertex.nz);
tangents[i] = new Vector4(vertex.tx, vertex.ty, -vertex.tz, vertex.tw);
uv[i] = new Vector2(vertex.u, vertex.v);
colors[i] = new Color(vertex.r, vertex.g, vertex.b, vertex.a);
boneWeights[i].boneIndex0 = vertex.blendIndices[0];
boneWeights[i].boneIndex1 = vertex.blendIndices[1];
boneWeights[i].boneIndex2 = vertex.blendIndices[2];
boneWeights[i].boneIndex3 = vertex.blendIndices[3];
boneWeights[i].weight0 = vertex.blendWeights[0];
boneWeights[i].weight1 = vertex.blendWeights[1];
boneWeights[i].weight2 = vertex.blendWeights[2];
boneWeights[i].weight3 = vertex.blendWeights[3];
}
}
break;
default:
throw new Exception("Bad Mesh Asset Type");
}
mesh.vertices = vertices;
mesh.normals = normals;
mesh.uv = uv;
mesh.tangents = tangents;
mesh.boneWeights = boneWeights;
mesh.colors = colors;
LoadBlendShapes(asset, vertexCount);
LoadSubmeshes(asset, indexBuffer, indexCount);
UInt32 jointCount = skinnedBindPose.jointCount;
jointNames = new string[jointCount];
for (UInt32 i = 0; i < jointCount; i++)
{
jointNames[i] = Marshal.PtrToStringAnsi(skinnedBindPose.jointNames[i]);
}
}
private void LoadSubmeshes(IntPtr asset, IntPtr indexBufferPtr, ulong indexCount)
{
UInt32 subMeshCount = CAPI.ovrAvatarAsset_GetSubmeshCount(asset);
AvatarLogger.Log("LoadSubmeshes: " + subMeshCount);
Int16[] indices = new Int16[indexCount];
Marshal.Copy(indexBufferPtr, indices, 0, (int)indexCount);
mesh.subMeshCount = (int)subMeshCount;
uint accumedOffset = 0;
for (UInt32 index = 0; index < subMeshCount; index++)
{
var submeshIndexCount = CAPI.ovrAvatarAsset_GetSubmeshLastIndex(asset, index);
var currSpan = submeshIndexCount - accumedOffset;
Int32[] triangles = new Int32[currSpan];
int triangleOffset = 0;
for (ulong i = accumedOffset; i < submeshIndexCount; i += 3)
{
// NOTE: We are changing the order of each triangle to match unity expectations vs pipeline.
triangles[triangleOffset + 2] = (Int32)indices[i];
triangles[triangleOffset + 1] = (Int32)indices[i + 1];
triangles[triangleOffset] = (Int32)indices[i + 2];
triangleOffset += 3;
}
accumedOffset += currSpan;
mesh.SetIndices(triangles, MeshTopology.Triangles, (int)index);
}
}
private void LoadBlendShapes(IntPtr asset, long vertexCount)
{
UInt32 blendShapeCount = CAPI.ovrAvatarAsset_GetMeshBlendShapeCount(asset);
IntPtr blendShapeVerts = CAPI.ovrAvatarAsset_GetMeshBlendShapeVertices(asset);
AvatarLogger.Log("LoadBlendShapes: " + blendShapeCount);
if (blendShapeVerts != IntPtr.Zero)
{
long offset = 0;
long blendVertexSize = (long)Marshal.SizeOf(typeof(ovrAvatarBlendVertex));
long blendVertexBufferStart = blendShapeVerts.ToInt64();
for (UInt32 blendIndex = 0; blendIndex < blendShapeCount; blendIndex++)
{
Vector3[] blendVerts = new Vector3[vertexCount];
Vector3[] blendNormals = new Vector3[vertexCount];
Vector3[] blendTangents = new Vector3[vertexCount];
for (long i = 0; i < vertexCount; i++)
{
ovrAvatarBlendVertex vertex = (ovrAvatarBlendVertex)Marshal.PtrToStructure(new IntPtr(blendVertexBufferStart + offset), typeof(ovrAvatarBlendVertex));
blendVerts[i] = new Vector3(vertex.x, vertex.y, -vertex.z);
blendNormals[i] = new Vector3(vertex.nx, vertex.ny, -vertex.nz);
blendTangents[i] = new Vector4(vertex.tx, vertex.ty, -vertex.tz);
offset += blendVertexSize;
}
IntPtr namePtr = CAPI.ovrAvatarAsset_GetMeshBlendShapeName(asset, blendIndex);
string name = Marshal.PtrToStringAnsi(namePtr);
const float frameWeight = 100f;
mesh.AddBlendShapeFrame(name, frameWeight, blendVerts, blendNormals, blendTangents);
}
}
}
private void SetSkinnedBindPose(IntPtr asset, ovrAvatarAssetType meshType)
{
switch (meshType)
{
case ovrAvatarAssetType.Mesh:
skinnedBindPose = CAPI.ovrAvatarAsset_GetMeshData(asset).skinnedBindPose;
break;
case ovrAvatarAssetType.CombinedMesh:
skinnedBindPose = CAPI.ovrAvatarAsset_GetCombinedMeshData(asset).skinnedBindPose;
break;
default:
break;
}
}
private void GetVertexAndIndexData(
IntPtr asset,
ovrAvatarAssetType meshType,
out long vertexCount,
out IntPtr vertexBuffer,
out uint indexCount,
out IntPtr indexBuffer)
{
vertexCount = 0;
vertexBuffer = IntPtr.Zero;
indexCount = 0;
indexBuffer = IntPtr.Zero;
switch (meshType)
{
case ovrAvatarAssetType.Mesh:
vertexCount = CAPI.ovrAvatarAsset_GetMeshData(asset).vertexCount;
vertexBuffer = CAPI.ovrAvatarAsset_GetMeshData(asset).vertexBuffer;
indexCount = CAPI.ovrAvatarAsset_GetMeshData(asset).indexCount;
indexBuffer = CAPI.ovrAvatarAsset_GetMeshData(asset).indexBuffer;
break;
case ovrAvatarAssetType.CombinedMesh:
vertexCount = CAPI.ovrAvatarAsset_GetCombinedMeshData(asset).vertexCount;
vertexBuffer = CAPI.ovrAvatarAsset_GetCombinedMeshData(asset).vertexBuffer;
indexCount = CAPI.ovrAvatarAsset_GetCombinedMeshData(asset).indexCount;
indexBuffer = CAPI.ovrAvatarAsset_GetCombinedMeshData(asset).indexBuffer;
break;
default:
break;
}
}
public SkinnedMeshRenderer CreateSkinnedMeshRendererOnObject(GameObject target)
{
SkinnedMeshRenderer skinnedMeshRenderer = target.AddComponent<SkinnedMeshRenderer>();
skinnedMeshRenderer.sharedMesh = mesh;
mesh.name = "AvatarMesh_" + assetID;
UInt32 jointCount = skinnedBindPose.jointCount;
GameObject[] bones = new GameObject[jointCount];
Transform[] boneTransforms = new Transform[jointCount];
Matrix4x4[] bindPoses = new Matrix4x4[jointCount];
for (UInt32 i = 0; i < jointCount; i++)
{
bones[i] = new GameObject();
boneTransforms[i] = bones[i].transform;
bones[i].name = jointNames[i];
int parentIndex = skinnedBindPose.jointParents[i];
if (parentIndex == -1)
{
bones[i].transform.parent = skinnedMeshRenderer.transform;
skinnedMeshRenderer.rootBone = bones[i].transform;
}
else
{
bones[i].transform.parent = bones[parentIndex].transform;
}
// Set the position relative to the parent
Vector3 position = skinnedBindPose.jointTransform[i].position;
position.z = -position.z;
bones[i].transform.localPosition = position;
Quaternion orientation = skinnedBindPose.jointTransform[i].orientation;
orientation.x = -orientation.x;
orientation.y = -orientation.y;
bones[i].transform.localRotation = orientation;
bones[i].transform.localScale = skinnedBindPose.jointTransform[i].scale;
bindPoses[i] = bones[i].transform.worldToLocalMatrix * skinnedMeshRenderer.transform.localToWorldMatrix;
}
skinnedMeshRenderer.bones = boneTransforms;
mesh.bindposes = bindPoses;
return skinnedMeshRenderer;
}
}