public void BuildNormals()
{
if (HasNormals)
{
return;
}
int i, j;
// Find vertices to share.
// We are using very simple algorithm here: to share all vertices with the same position
// independently on normals of faces which share this vertex.
CVec3[] tmpNorm = new CVec3[NumVerts]; // really will use Points.Num() items, which value is smaller than NumVerts
CVertexShare Share = new CVertexShare();
Share.Prepare(Verts, NumVerts, 48);
for (i = 0; i < NumVerts; i++)
{
CPackedNormal NullVec;
NullVec.Data = 0;
Share.AddVertex(Verts[i].Position, NullVec);
}
for (i = 0; i < Indices.Length / 3; i++)
{
CSkelMeshVertex[] V = new CSkelMeshVertex[3];
CVec3[] N = new CVec3[3];
for (j = 0; j < 3; j++)
{
int idx = (int)Indices[i * 3 + j]; // index in Verts[]
V[j] = Verts[idx];
N[j] = tmpNorm[Share.WedgeToVert[idx]]; // remap to shared verts
}
// compute edges
CVec3[] D = new CVec3[]
{
V[1].Position - V[0].Position,
V[2].Position - V[1].Position,
V[0].Position - V[2].Position
};
// compute face normal
CVec3 norm = CVec3.Cross(D[1], D[0]);
norm.Normalize();
// compute angles
for (j = 0; j < 3; j++)
{
D[j].Normalize();
}
float[] angle = new float[]
{
(float)Math.Acos(-CVec3.Dot(D[0], D[2])),
(float)Math.Acos(-CVec3.Dot(D[0], D[1])),
(float)Math.Acos(-CVec3.Dot(D[1], D[2]))
};
// add normals for triangle verts
for (j = 0; j < 3; j++)
{
N[j].VectorMA(angle[j], norm);
}
for (j = 0; j < 3; j++)
{
int idx = (int)Indices[i * 3 + j];
Verts[idx] = V[j];
tmpNorm[Share.WedgeToVert[idx]] = N[j];
}
}
// TODO: add "hard angle threshold" - do not share vertex between faces when angle between them
// is too large.
// normalize shared normals ...
for (i = 0; i < Share.Points.Count; i++)
{
tmpNorm[i].Normalize();
}
// ... then place ("unshare") normals to Verts
for (i = 0; i < NumVerts; i++)
{
Verts[i].Normal.Pack(tmpNorm[Share.WedgeToVert[i]]);
}
HasNormals = true;
}
static void ExportCommonMeshData(BinaryWriter writer, CMeshSection[] Sections, CSkelMeshVertex[] Verts, CIndexBuffer Indices, CVertexShare Share)
{
VChunkHeader MainHdr = new VChunkHeader(), PtsHdr, WedgHdr, FacesHdr, MatrHdr;
int i;
// main psk header
SAVE_CHUNK(writer, MainHdr, "ACTRHEAD");
PtsHdr = new VChunkHeader
{
DataCount = Share.Points.Count,
DataSize = 12
};
SAVE_CHUNK(writer, PtsHdr, "PNTS0000");
for (i = 0; i < Share.Points.Count; i++)
{
FVector V = Share.Points[i];
V.Y = -V.Y;
V.Write(writer);
}
// get number of faces (some Gears3 meshes may have index buffer larger than needed)
// get wedge-material mapping
int numFaces = 0;
int[] WedgeMat = new int[Verts.Length];
for (i = 0; i < Sections.Length; i++)
{
CMeshSection Sec = Sections[i];
numFaces += Sec.NumFaces;
for (int j = 0; j < Sec.NumFaces * 3; j++)
{
WedgeMat[Indices[j + Sec.FirstIndex]] = i;
}
}
WedgHdr = new VChunkHeader
{
DataCount = Verts.Length,
DataSize = 16
};
SAVE_CHUNK(writer, WedgHdr, "VTXW0000");
for (i = 0; i < Verts.Length; i++)
{
CSkelMeshVertex S = Verts[i];
VVertex W = new VVertex
{
PointIndex = Share.WedgeToVert[i],
U = S.UV.U,
V = S.UV.V,
MatIndex = (byte)WedgeMat[i],
Reserved = 0,
Pad = 0
};
W.Write(writer);
}
if (Verts.Length <= 65536)
{
FacesHdr = new VChunkHeader
{
DataCount = numFaces,
DataSize = 12
};
SAVE_CHUNK(writer, FacesHdr, "FACE0000");
for (i = 0; i < Sections.Length; i++)
{
CMeshSection Sec = Sections[i];
for (int j = 0; j < Sec.NumFaces; j++)
{
VTriangle16 T = new VTriangle16 {
WedgeIndex = new ushort[3]
};
for (int k = 0; k < 3; k++)
{
int idx = (int)Indices[Sec.FirstIndex + j * 3 + k];
if (idx < 0 || idx >= 65536)
{
throw new FileLoadException("Invalid section index");
}
T.WedgeIndex[k] = (ushort)idx;
}
T.MatIndex = (byte)i;
T.AuxMatIndex = 0;
T.SmoothingGroups = 1;
ushort tmp = T.WedgeIndex[0];
T.WedgeIndex[0] = T.WedgeIndex[1];
T.WedgeIndex[1] = tmp;
T.Write(writer);
}
}
}
else
{
// pskx extension
FacesHdr = new VChunkHeader
{
DataCount = numFaces,
DataSize = 18
};
SAVE_CHUNK(writer, FacesHdr, "FACE3200");
for (i = 0; i < Sections.Length; i++)
{
CMeshSection Sec = Sections[i];
for (int j = 0; j < Sec.NumFaces; j++)
{
VTriangle32 T = new VTriangle32 {
WedgeIndex = new int[3]
};
for (int k = 0; k < 3; k++)
{
int idx = (int)Indices[Sec.FirstIndex + j * 3 + k];
T.WedgeIndex[k] = idx;
}
T.MatIndex = (byte)i;
T.AuxMatIndex = 0;
T.SmoothingGroups = 1;
int tmp = T.WedgeIndex[0];
T.WedgeIndex[0] = T.WedgeIndex[1];
T.WedgeIndex[1] = tmp;
T.Write(writer);
}
}
}
MatrHdr = new VChunkHeader
{
DataCount = Sections.Length,
DataSize = 88
};
SAVE_CHUNK(writer, MatrHdr, "MATT0000");
for (i = 0; i < Sections.Length; i++)
{
VMaterial M = new VMaterial {
MaterialName = new byte[64]
};
UUnrealMaterial Tex = Sections[i].Material;
M.TextureIndex = i; // could be required for UT99
//!! this will not handle (UMaterialWithPolyFlags->Material==NULL) correctly - will make MaterialName=="None"
//!! (the same valid for md5mesh export)
Tex = null;
if (Tex != null)
{
//Extensions.StrCpy(M.MaterialName, Tex.Name);
//ExportObject(Tex);
}
else
{
Extensions.StrCpy(M.MaterialName, $"material_{i}");
}
M.Write(writer);
}
}
public static void ExportMesh(BinaryWriter writer, CSkeletalMesh Mesh, CSkelMeshLod Lod)
{
VChunkHeader BoneHdr, InfHdr;
int i, j;
CVertexShare Share = new CVertexShare();
// weld vertices
// The code below differs from similar code for StaticMesh export: it relies on vertex weight
// information to not perform occasional welding of vertices which has the same position and
// normal, but belongs to different bones.
Share.Prepare(Lod.Verts, Lod.NumVerts, 48);
for (i = 0; i < Lod.NumVerts; i++)
{
CSkelMeshVertex S = Lod.Verts[i];
// Here we relies on high possibility that vertices which should be shared between
// triangles will have the same order of weights and bones (because most likely
// these vertices were duplicated by copying). Doing more complicated comparison
// will reduce performance with possibly reducing size of exported mesh by a few
// more vertices.
uint WeightsHash = S.PackedWeights;
for (j = 0; j < S.Bone.Length; j++)
{
WeightsHash ^= (uint)(S.Bone[j] << j);
}
Share.AddVertex(S.Position, S.Normal, WeightsHash);
}
ExportCommonMeshData(writer, Lod.Sections, Lod.Verts, Lod.Indices, Share);
int numBones = Mesh.RefSkeleton.Length;
BoneHdr = new VChunkHeader
{
DataCount = numBones,
DataSize = 120
};
SAVE_CHUNK(writer, BoneHdr, "REFSKELT");
for (i = 0; i < numBones; i++)
{
VBone B = new VBone {
Name = new byte[64]
};
CSkelMeshBone S = Mesh.RefSkeleton[i];
Extensions.StrCpy(B.Name, S.Name);
// count NumChildren
int NumChildren = 0;
for (j = 0; j < numBones; j++)
{
if ((j != i) && (Mesh.RefSkeleton[j].ParentIndex == i))
{
NumChildren++;
}
}
B.NumChildren = NumChildren;
B.ParentIndex = S.ParentIndex;
B.BonePos.Position = S.Position;
B.BonePos.Orientation = S.Orientation;
B.BonePos.Orientation.Y *= -1;
B.BonePos.Orientation.W *= -1;
B.BonePos.Position.Y *= -1;
B.Write(writer);
}
// count influences
int NumInfluences = 0;
for (i = 0; i < Share.Points.Count; i++)
{
int WedgeIndex = Share.VertToWedge[i];
CSkelMeshVertex V = Lod.Verts[WedgeIndex];
for (j = 0; j < 4; j++)
{
if (V.Bone[j] < 0)
{
break;
}
NumInfluences++;
}
}
// write influences
InfHdr = new VChunkHeader
{
DataCount = NumInfluences,
DataSize = 12
};
SAVE_CHUNK(writer, InfHdr, "RAWWEIGHTS");
for (i = 0; i < Share.Points.Count; i++)
{
int WedgeIndex = Share.VertToWedge[i];
CSkelMeshVertex V = Lod.Verts[WedgeIndex];
CVec4 UnpackedWeights = V.UnpackWeights();
for (j = 0; j < 4; j++)
{
if (V.Bone[j] < 0)
{
break;
}
NumInfluences--; // just for verification
VRawBoneInfluence I;
I.Weight = UnpackedWeights.v[j];
I.BoneIndex = V.Bone[j];
I.PointIndex = i;
I.Write(writer);
}
}
if (NumInfluences != 0)
{
throw new FileLoadException("Did not write to all influences");
}
ExportExtraUV(writer, Lod.ExtraUV, Lod.NumVerts, Lod.NumTexCoords);
}
