public void ComposeShape()
{
ColliderShapeChanged = false;
if (ColliderShape != null)
{
if (!ColliderShape.IsPartOfAsset)
{
ColliderShape.Dispose();
ColliderShape = null;
}
else
{
ColliderShape = null;
}
}
CanScaleShape = true;
if (ColliderShapes.Count == 1) //single shape case
{
if (ColliderShapes[0] == null)
{
return;
}
if (ColliderShapes[0].GetType() == typeof(ColliderShapeAssetDesc))
{
CanScaleShape = false;
}
ColliderShape = PhysicsColliderShape.CreateShape(ColliderShapes[0]);
ColliderShape?.UpdateLocalTransformations();
}
else if (ColliderShapes.Count > 1) //need a compound shape in this case
{
var compound = new CompoundColliderShape();
foreach (var desc in ColliderShapes)
{
if (desc == null)
{
continue;
}
if (desc.GetType() == typeof(ColliderShapeAssetDesc))
{
CanScaleShape = false;
}
var subShape = PhysicsColliderShape.CreateShape(desc);
if (subShape != null)
{
compound.AddChildShape(subShape);
}
}
ColliderShape = compound;
ColliderShape.UpdateLocalTransformations();
}
}
protected override Task <ResultStatus> DoCommandOverride(ICommandContext commandContext)
{
var assetManager = new AssetManager();
AssetParameters.ColliderShapes = AssetParameters.ColliderShapes.Where(x => x != null &&
(x.GetType() != typeof(ConvexHullColliderShapeDesc) || ((ConvexHullColliderShapeDesc)x).Model != null)).ToList();
//pre process special types
foreach (var convexHullDesc in
(from shape in AssetParameters.ColliderShapes let type = shape.GetType() where type == typeof(ConvexHullColliderShapeDesc) select shape)
.Cast <ConvexHullColliderShapeDesc>())
{
//decompose and fill vertex data
var loadSettings = new AssetManagerLoaderSettings
{
ContentFilter = AssetManagerLoaderSettings.NewContentFilterByType(typeof(Mesh))
};
var modelAsset = assetManager.Load <Model>(AttachedReferenceManager.GetUrl(convexHullDesc.Model), loadSettings);
if (modelAsset == null)
{
continue;
}
convexHullDesc.ConvexHulls = new List <List <List <Vector3> > >();
convexHullDesc.ConvexHullsIndices = new List <List <List <uint> > >();
commandContext.Logger.Info("Processing convex hull generation, this might take a while!");
var nodeTransforms = new List <Matrix>();
//pre-compute all node transforms, assuming nodes are ordered... see ModelViewHierarchyUpdater
var nodesLength = modelAsset.Hierarchy.Nodes.Length;
for (var i = 0; i < nodesLength; i++)
{
Matrix localMatrix;
TransformComponent.CreateMatrixTRS(
ref modelAsset.Hierarchy.Nodes[i].Transform.Translation,
ref modelAsset.Hierarchy.Nodes[i].Transform.Rotation,
ref modelAsset.Hierarchy.Nodes[i].Transform.Scaling, out localMatrix);
Matrix worldMatrix;
if (modelAsset.Hierarchy.Nodes[i].ParentIndex != -1)
{
var nodeTransform = nodeTransforms[modelAsset.Hierarchy.Nodes[i].ParentIndex];
Matrix.Multiply(ref localMatrix, ref nodeTransform, out worldMatrix);
}
else
{
worldMatrix = localMatrix;
}
nodeTransforms.Add(worldMatrix);
}
for (var i = 0; i < nodesLength; i++)
{
var i1 = i;
if (modelAsset.Meshes.All(x => x.NodeIndex != i1))
{
continue; // no geometry in the node
}
var combinedVerts = new List <float>();
var combinedIndices = new List <uint>();
var hullsList = new List <List <Vector3> >();
convexHullDesc.ConvexHulls.Add(hullsList);
var indicesList = new List <List <uint> >();
convexHullDesc.ConvexHullsIndices.Add(indicesList);
foreach (var meshData in modelAsset.Meshes.Where(x => x.NodeIndex == i1))
{
var indexOffset = (uint)combinedVerts.Count / 3;
var stride = meshData.Draw.VertexBuffers[0].Declaration.VertexStride;
var vertexDataAsset = assetManager.Load <Graphics.Buffer>(AttachedReferenceManager.GetUrl(meshData.Draw.VertexBuffers[0].Buffer));
var vertexData = vertexDataAsset.GetSerializationData().Content;
var vertexIndex = meshData.Draw.VertexBuffers[0].Offset;
for (var v = 0; v < meshData.Draw.VertexBuffers[0].Count; v++)
{
var posMatrix = Matrix.Translation(new Vector3(BitConverter.ToSingle(vertexData, vertexIndex + 0), BitConverter.ToSingle(vertexData, vertexIndex + 4), BitConverter.ToSingle(vertexData, vertexIndex + 8)));
Matrix rotatedMatrix;
var nodeTransform = nodeTransforms[i];
Matrix.Multiply(ref posMatrix, ref nodeTransform, out rotatedMatrix);
combinedVerts.Add(rotatedMatrix.TranslationVector.X);
combinedVerts.Add(rotatedMatrix.TranslationVector.Y);
combinedVerts.Add(rotatedMatrix.TranslationVector.Z);
vertexIndex += stride;
}
var indexDataAsset = assetManager.Load <Graphics.Buffer>(AttachedReferenceManager.GetUrl(meshData.Draw.IndexBuffer.Buffer));
var indexData = indexDataAsset.GetSerializationData().Content;
var indexIndex = meshData.Draw.IndexBuffer.Offset;
for (var v = 0; v < meshData.Draw.IndexBuffer.Count; v++)
{
if (meshData.Draw.IndexBuffer.Is32Bit)
{
combinedIndices.Add(BitConverter.ToUInt32(indexData, indexIndex) + indexOffset);
indexIndex += 4;
}
else
{
combinedIndices.Add(BitConverter.ToUInt16(indexData, indexIndex) + indexOffset);
indexIndex += 2;
}
}
}
var decompositionDesc = new ConvexHullMesh.DecompositionDesc
{
VertexCount = (uint)combinedVerts.Count / 3,
IndicesCount = (uint)combinedIndices.Count,
Vertexes = combinedVerts.ToArray(),
Indices = combinedIndices.ToArray(),
Depth = convexHullDesc.Depth,
PosSampling = convexHullDesc.PosSampling,
PosRefine = convexHullDesc.PosRefine,
AngleSampling = convexHullDesc.AngleSampling,
AngleRefine = convexHullDesc.AngleRefine,
Alpha = convexHullDesc.Alpha,
Threshold = convexHullDesc.Threshold,
SimpleHull = convexHullDesc.SimpleWrap
};
lock (this)
{
convexHullMesh = new ConvexHullMesh();
}
convexHullMesh.Generate(decompositionDesc);
var count = convexHullMesh.Count;
commandContext.Logger.Info("Node generated " + count + " convex hulls");
var vertexCountHull = 0;
for (uint h = 0; h < count; h++)
{
float[] points;
convexHullMesh.CopyPoints(h, out points);
var pointList = new List <Vector3>();
for (var v = 0; v < points.Length; v += 3)
{
var vert = new Vector3(points[v + 0], points[v + 1], points[v + 2]);
pointList.Add(vert);
vertexCountHull++;
}
hullsList.Add(pointList);
uint[] indices;
convexHullMesh.CopyIndices(h, out indices);
for (var t = 0; t < indices.Length; t += 3)
{
Utilities.Swap(ref indices[t], ref indices[t + 2]);
}
var indexList = new List <uint>(indices);
indicesList.Add(indexList);
}
lock (this)
{
convexHullMesh.Dispose();
convexHullMesh = null;
}
commandContext.Logger.Info("For a total of " + vertexCountHull + " vertexes");
}
}
var runtimeShape = new PhysicsColliderShape {
Descriptions = AssetParameters.ColliderShapes
};
assetManager.Save(Url, runtimeShape);
return(Task.FromResult(ResultStatus.Successful));
}
public void ComposeShape()
{
ColliderShapeChanged = false;
if (ColliderShape != null)
{
if (!ColliderShape.DoNotDispose && !SceneSystem.physicsDoNotDisposeNextRemoval)
{
ColliderShape.Dispose();
ColliderShape = null;
}
else
{
ColliderShape = null;
}
}
CanScaleShape = true;
if (ColliderShapes.Count == 1) //single shape case
{
if (ColliderShapes[0] == null)
{
return;
}
if (ColliderShapes[0].GetType() == typeof(ColliderShapeAssetDesc))
{
CanScaleShape = false;
}
ColliderShape = PhysicsColliderShape.CreateShape(ColliderShapes[0]);
}
else if (ColliderShapes.Count > 1) //need a compound shape in this case
{
var compound = new CompoundColliderShape();
foreach (var desc in ColliderShapes)
{
if (desc == null)
{
continue;
}
if (desc.GetType() == typeof(ColliderShapeAssetDesc))
{
CanScaleShape = false;
}
var subShape = PhysicsColliderShape.CreateShape(desc);
if (subShape != null)
{
compound.AddChildShape(subShape);
}
}
ColliderShape = compound;
}
if (ColliderShape != null)
{
// Force update internal shape and gizmo scaling
ColliderShape.Scaling = ColliderShape.Scaling;
}
}
protected override Task <ResultStatus> DoCommandOverride(ICommandContext commandContext)
{
var assetManager = new ContentManager();
// Cloned list of collider shapes
var descriptions = Parameters.ColliderShapes.ToList();
Parameters.ColliderShapes = Parameters.ColliderShapes.Where(x => x != null &&
(x.GetType() != typeof(ConvexHullColliderShapeDesc) || ((ConvexHullColliderShapeDesc)x).Model != null)).ToList();
//pre process special types
foreach (var convexHullDesc in
(from shape in Parameters.ColliderShapes let type = shape.GetType() where type == typeof(ConvexHullColliderShapeDesc) select shape)
.Cast <ConvexHullColliderShapeDesc>())
{
// Clone the convex hull shape description so the fields that should not be serialized can be cleared (Model in this case)
ConvexHullColliderShapeDesc convexHullDescClone = new ConvexHullColliderShapeDesc
{
Scaling = convexHullDesc.Scaling,
LocalOffset = convexHullDesc.LocalOffset,
LocalRotation = convexHullDesc.LocalRotation,
Depth = convexHullDesc.Depth,
PosSampling = convexHullDesc.PosSampling,
AngleSampling = convexHullDesc.AngleSampling,
PosRefine = convexHullDesc.PosRefine,
AngleRefine = convexHullDesc.AngleRefine,
Alpha = convexHullDesc.Alpha,
Threshold = convexHullDesc.Threshold,
};
// Replace shape in final result with cloned description
int replaceIndex = descriptions.IndexOf(convexHullDesc);
descriptions[replaceIndex] = convexHullDescClone;
var loadSettings = new ContentManagerLoaderSettings
{
ContentFilter = ContentManagerLoaderSettings.NewContentFilterByType(typeof(Mesh), typeof(Skeleton))
};
var modelAsset = assetManager.Load <Model>(AttachedReferenceManager.GetUrl(convexHullDesc.Model), loadSettings);
if (modelAsset == null)
{
continue;
}
convexHullDescClone.ConvexHulls = new List <List <List <Vector3> > >();
convexHullDescClone.ConvexHullsIndices = new List <List <List <uint> > >();
commandContext.Logger.Info("Processing convex hull generation, this might take a while!");
var nodeTransforms = new List <Matrix>();
//pre-compute all node transforms, assuming nodes are ordered... see ModelViewHierarchyUpdater
if (modelAsset.Skeleton == null)
{
Matrix baseMatrix;
Matrix.Transformation(ref convexHullDescClone.Scaling, ref convexHullDescClone.LocalRotation, ref convexHullDescClone.LocalOffset, out baseMatrix);
nodeTransforms.Add(baseMatrix);
}
else
{
var nodesLength = modelAsset.Skeleton.Nodes.Length;
for (var i = 0; i < nodesLength; i++)
{
Matrix localMatrix;
Matrix.Transformation(
ref modelAsset.Skeleton.Nodes[i].Transform.Scale,
ref modelAsset.Skeleton.Nodes[i].Transform.Rotation,
ref modelAsset.Skeleton.Nodes[i].Transform.Position, out localMatrix);
Matrix worldMatrix;
if (modelAsset.Skeleton.Nodes[i].ParentIndex != -1)
{
var nodeTransform = nodeTransforms[modelAsset.Skeleton.Nodes[i].ParentIndex];
Matrix.Multiply(ref localMatrix, ref nodeTransform, out worldMatrix);
}
else
{
worldMatrix = localMatrix;
}
if (i == 0)
{
Matrix baseMatrix;
Matrix.Transformation(ref convexHullDescClone.Scaling, ref convexHullDescClone.LocalRotation, ref convexHullDescClone.LocalOffset, out baseMatrix);
nodeTransforms.Add(baseMatrix * worldMatrix);
}
else
{
nodeTransforms.Add(worldMatrix);
}
}
}
for (var i = 0; i < nodeTransforms.Count; i++)
{
var i1 = i;
if (modelAsset.Meshes.All(x => x.NodeIndex != i1))
{
continue; // no geometry in the node
}
var combinedVerts = new List <float>();
var combinedIndices = new List <uint>();
var hullsList = new List <List <Vector3> >();
convexHullDescClone.ConvexHulls.Add(hullsList);
var indicesList = new List <List <uint> >();
convexHullDescClone.ConvexHullsIndices.Add(indicesList);
foreach (var meshData in modelAsset.Meshes.Where(x => x.NodeIndex == i1))
{
var indexOffset = (uint)combinedVerts.Count / 3;
var stride = meshData.Draw.VertexBuffers[0].Declaration.VertexStride;
var vertexBufferRef = AttachedReferenceManager.GetAttachedReference(meshData.Draw.VertexBuffers[0].Buffer);
byte[] vertexData;
if (vertexBufferRef.Data != null)
{
vertexData = ((BufferData)vertexBufferRef.Data).Content;
}
else if (!vertexBufferRef.Url.IsNullOrEmpty())
{
var dataAsset = assetManager.Load <Buffer>(vertexBufferRef.Url);
vertexData = dataAsset.GetSerializationData().Content;
}
else
{
continue;
}
var vertexIndex = meshData.Draw.VertexBuffers[0].Offset;
for (var v = 0; v < meshData.Draw.VertexBuffers[0].Count; v++)
{
var posMatrix = Matrix.Translation(new Vector3(BitConverter.ToSingle(vertexData, vertexIndex + 0), BitConverter.ToSingle(vertexData, vertexIndex + 4), BitConverter.ToSingle(vertexData, vertexIndex + 8)));
Matrix rotatedMatrix;
var nodeTransform = nodeTransforms[i];
Matrix.Multiply(ref posMatrix, ref nodeTransform, out rotatedMatrix);
combinedVerts.Add(rotatedMatrix.TranslationVector.X);
combinedVerts.Add(rotatedMatrix.TranslationVector.Y);
combinedVerts.Add(rotatedMatrix.TranslationVector.Z);
vertexIndex += stride;
}
var indexBufferRef = AttachedReferenceManager.GetAttachedReference(meshData.Draw.IndexBuffer.Buffer);
byte[] indexData;
if (indexBufferRef.Data != null)
{
indexData = ((BufferData)indexBufferRef.Data).Content;
}
else if (!indexBufferRef.Url.IsNullOrEmpty())
{
var dataAsset = assetManager.Load <Buffer>(indexBufferRef.Url);
indexData = dataAsset.GetSerializationData().Content;
}
else
{
throw new Exception("Failed to find index buffer while building a convex hull.");
}
var indexIndex = meshData.Draw.IndexBuffer.Offset;
for (var v = 0; v < meshData.Draw.IndexBuffer.Count; v++)
{
if (meshData.Draw.IndexBuffer.Is32Bit)
{
combinedIndices.Add(BitConverter.ToUInt32(indexData, indexIndex) + indexOffset);
indexIndex += 4;
}
else
{
combinedIndices.Add(BitConverter.ToUInt16(indexData, indexIndex) + indexOffset);
indexIndex += 2;
}
}
}
var decompositionDesc = new ConvexHullMesh.DecompositionDesc
{
VertexCount = (uint)combinedVerts.Count / 3,
IndicesCount = (uint)combinedIndices.Count,
Vertexes = combinedVerts.ToArray(),
Indices = combinedIndices.ToArray(),
Depth = convexHullDesc.Depth,
PosSampling = convexHullDesc.PosSampling,
PosRefine = convexHullDesc.PosRefine,
AngleSampling = convexHullDesc.AngleSampling,
AngleRefine = convexHullDesc.AngleRefine,
Alpha = convexHullDesc.Alpha,
Threshold = convexHullDesc.Threshold,
SimpleHull = convexHullDesc.SimpleWrap
};
var convexHullMesh = new ConvexHullMesh();
convexHullMesh.Generate(decompositionDesc);
var count = convexHullMesh.Count;
commandContext.Logger.Info("Node generated " + count + " convex hulls");
var vertexCountHull = 0;
for (uint h = 0; h < count; h++)
{
float[] points;
convexHullMesh.CopyPoints(h, out points);
var pointList = new List <Vector3>();
for (var v = 0; v < points.Length; v += 3)
{
var vert = new Vector3(points[v + 0], points[v + 1], points[v + 2]);
pointList.Add(vert);
vertexCountHull++;
}
hullsList.Add(pointList);
uint[] indices;
convexHullMesh.CopyIndices(h, out indices);
for (var t = 0; t < indices.Length; t += 3)
{
Utilities.Swap(ref indices[t], ref indices[t + 2]);
}
var indexList = new List <uint>(indices);
indicesList.Add(indexList);
}
convexHullMesh.Dispose();
commandContext.Logger.Info("For a total of " + vertexCountHull + " vertexes");
}
}
var runtimeShape = new PhysicsColliderShape {
Descriptions = descriptions
};
assetManager.Save(Url, runtimeShape);
return(Task.FromResult(ResultStatus.Successful));
}
