public void getMesh(ConvexResult cr, VertexPool vc, List <int> indices)
{
List <int> src = cr.HullIndices;
for (int i = 0; i < src.Count / 3; i++)
{
int i1 = src[i * 3 + 0];
int i2 = src[i * 3 + 1];
int i3 = src[i * 3 + 2];
float3 p1 = cr.HullVertices[i1];
float3 p2 = cr.HullVertices[i2];
float3 p3 = cr.HullVertices[i3];
i1 = vc.getIndex(p1);
i2 = vc.getIndex(p2);
i3 = vc.getIndex(p3);
}
}
public void getMesh(ConvexResult cr, VertexPool vc, List<int> indices)
{
List<int> src = cr.HullIndices;
for (int i = 0; i < src.Count / 3; i++)
{
int i1 = src[i * 3 + 0];
int i2 = src[i * 3 + 1];
int i3 = src[i * 3 + 2];
float3 p1 = cr.HullVertices[i1];
float3 p2 = cr.HullVertices[i2];
float3 p3 = cr.HullVertices[i3];
i1 = vc.getIndex(p1);
i2 = vc.getIndex(p2);
i3 = vc.getIndex(p3);
}
}
public CHull canMerge(CHull a, CHull b)
{
if (!a.overlap(b)) // if their AABB's (with a little slop) don't overlap, then return.
return null;
CHull ret = null;
// ok..we are going to combine both meshes into a single mesh
// and then we are going to compute the concavity...
VertexPool vc = new VertexPool();
List<int> indices = new List<int>();
getMesh(a.mResult, vc, indices);
getMesh(b.mResult, vc, indices);
int vcount = vc.GetSize();
List<float3> vertices = vc.GetVertices();
int tcount = indices.Count / 3;
//don't do anything if hull is empty
if (tcount == 0)
{
vc.Clear();
return null;
}
HullResult hresult = new HullResult();
HullDesc desc = new HullDesc();
desc.SetHullFlag(HullFlag.QF_TRIANGLES);
desc.Vertices = vertices;
HullError hret = HullUtils.CreateConvexHull(desc, ref hresult);
if (hret == HullError.QE_OK)
{
float combineVolume = Concavity.computeMeshVolume(hresult.OutputVertices, hresult.Indices);
float sumVolume = a.mVolume + b.mVolume;
float percent = (sumVolume * 100) / combineVolume;
if (percent >= (100.0f - MERGE_PERCENT))
{
ConvexResult cr = new ConvexResult(hresult.OutputVertices, hresult.Indices);
ret = new CHull(cr);
}
}
vc.Clear();
return ret;
}
public static void calcConvexDecomposition(List <float3> vertices, List <int> indices, ConvexDecompositionCallback callback, float masterVolume, int depth,
int maxDepth, float concavePercent, float mergePercent)
{
float4 plane = new float4();
bool split = false;
if (depth < maxDepth)
{
float volume = 0f;
float c = Concavity.computeConcavity(vertices, indices, ref plane, ref volume);
if (depth == 0)
{
masterVolume = volume;
}
float percent = (c * 100.0f) / masterVolume;
if (percent > concavePercent) // if great than 5% of the total volume is concave, go ahead and keep splitting.
{
split = true;
}
}
if (depth >= maxDepth || !split)
{
HullResult result = new HullResult();
HullDesc desc = new HullDesc();
desc.SetHullFlag(HullFlag.QF_TRIANGLES);
desc.Vertices = vertices;
HullError ret = HullUtils.CreateConvexHull(desc, ref result);
if (ret == HullError.QE_OK)
{
ConvexResult r = new ConvexResult(result.OutputVertices, result.Indices);
callback(r);
}
return;
}
List <int> ifront = new List <int>();
List <int> iback = new List <int>();
VertexPool vfront = new VertexPool();
VertexPool vback = new VertexPool();
// ok..now we are going to 'split' all of the input triangles against this plane!
for (int i = 0; i < indices.Count / 3; i++)
{
int i1 = indices[i * 3 + 0];
int i2 = indices[i * 3 + 1];
int i3 = indices[i * 3 + 2];
FaceTri t = new FaceTri(vertices, i1, i2, i3);
float3[] front = new float3[4];
float3[] back = new float3[4];
int fcount = 0;
int bcount = 0;
PlaneTriResult result = PlaneTri.planeTriIntersection(plane, t, 0.00001f, ref front, out fcount, ref back, out bcount);
if (fcount > 4 || bcount > 4)
{
result = PlaneTri.planeTriIntersection(plane, t, 0.00001f, ref front, out fcount, ref back, out bcount);
}
switch (result)
{
case PlaneTriResult.PTR_FRONT:
Debug.Assert(fcount == 3);
addTri(vfront, ifront, front[0], front[1], front[2]);
break;
case PlaneTriResult.PTR_BACK:
Debug.Assert(bcount == 3);
addTri(vback, iback, back[0], back[1], back[2]);
break;
case PlaneTriResult.PTR_SPLIT:
Debug.Assert(fcount >= 3 && fcount <= 4);
Debug.Assert(bcount >= 3 && bcount <= 4);
addTri(vfront, ifront, front[0], front[1], front[2]);
addTri(vback, iback, back[0], back[1], back[2]);
if (fcount == 4)
{
addTri(vfront, ifront, front[0], front[2], front[3]);
}
if (bcount == 4)
{
addTri(vback, iback, back[0], back[2], back[3]);
}
break;
}
}
// ok... here we recursively call
if (ifront.Count > 0)
{
int vcount = vfront.GetSize();
List <float3> vertices2 = vfront.GetVertices();
for (int i = 0; i < vertices2.Count; i++)
{
vertices2[i] = new float3(vertices2[i]);
}
int tcount = ifront.Count / 3;
calcConvexDecomposition(vertices2, ifront, callback, masterVolume, depth + 1, maxDepth, concavePercent, mergePercent);
}
ifront.Clear();
vfront.Clear();
if (iback.Count > 0)
{
int vcount = vback.GetSize();
List <float3> vertices2 = vback.GetVertices();
int tcount = iback.Count / 3;
calcConvexDecomposition(vertices2, iback, callback, masterVolume, depth + 1, maxDepth, concavePercent, mergePercent);
}
iback.Clear();
vback.Clear();
}