public static void ImportCharMesh(string meshPath, string zmsPath)
{
if (!File.Exists(zmsPath)) {
Debug.LogWarning("Failed to find referenced ZMS.");
return;
}
var mesh = new Mesh();
var zms = new Revise.Files.ZMS.ModelFile();
zms.Load(zmsPath);
var verts = new Vector3[zms.Vertices.Count];
var uvs = new Vector2[zms.Vertices.Count];
var bones = new BoneWeight[zms.Vertices.Count];
for (int k = 0; k < zms.Vertices.Count; ++k) {
var v = zms.Vertices[k];
v.TextureCoordinates[0].y = 1 - v.TextureCoordinates[0].y;
verts[k] = rtuPosition(v.Position);
uvs[k] = v.TextureCoordinates[0];
bones[k] = new BoneWeight();
bones[k].boneIndex0 = zms.BoneTable[v.BoneIndices.X];
bones[k].boneIndex1 = zms.BoneTable[v.BoneIndices.Y];
bones[k].boneIndex2 = zms.BoneTable[v.BoneIndices.Z];
bones[k].boneIndex3 = zms.BoneTable[v.BoneIndices.W];
bones[k].weight0 = v.BoneWeights.x;
bones[k].weight1 = v.BoneWeights.y;
bones[k].weight2 = v.BoneWeights.z;
bones[k].weight3 = v.BoneWeights.w;
}
mesh.vertices = verts;
mesh.uv = uvs;
mesh.boneWeights = bones;
int[] indices = new int[zms.Indices.Count * 3];
for (int k = 0; k < zms.Indices.Count; ++k) {
indices[k * 3 + 0] = zms.Indices[k].X;
indices[k * 3 + 2] = zms.Indices[k].Y;
indices[k * 3 + 1] = zms.Indices[k].Z;
}
mesh.triangles = indices;
mesh.RecalculateNormals();
AssetDatabase.CreateAsset(mesh, meshPath);
}
public void ImportModels()
{
_meshLookup = new Mesh[_f.ModelFiles.Count];
for (int i = 0; i < _f.ModelFiles.Count; ++i)
{
var zmsPath = rootPath + _f.ModelFiles[i];
if (!File.Exists(zmsPath))
{
Debug.LogWarning("Failed to find referenced ZMS.");
continue;
}
var mesh = new Mesh();
var zms = new Revise.Files.ZMS.ModelFile();
zms.Load(zmsPath);
var verts = new Vector3[zms.Vertices.Count];
var uvs = new Vector2[zms.Vertices.Count];
for (int k = 0; k < zms.Vertices.Count; ++k)
{
var v = zms.Vertices[k];
v.TextureCoordinates[0].y = 1 - v.TextureCoordinates[0].y;
verts[k] = rtuPosition(v.Position);
uvs[k] = v.TextureCoordinates[0];
}
mesh.vertices = verts;
mesh.uv = uvs;
int[] indices = new int[zms.Indices.Count * 3];
for (int k = 0; k < zms.Indices.Count; ++k)
{
indices[k * 3 + 0] = zms.Indices[k].X;
indices[k * 3 + 2] = zms.Indices[k].Y;
indices[k * 3 + 1] = zms.Indices[k].Z;
}
mesh.triangles = indices;
mesh.RecalculateNormals();
Unwrapping.GenerateSecondaryUVSet(mesh);
var meshPath = _basePath + "Mesh_" + i.ToString() + ".asset";
AssetDatabase.CreateAsset(mesh, meshPath);
_meshLookup[i] = mesh;
}
_matLookup = new Material[_f.TextureFiles.Count];
for (int i = 0; i < _f.TextureFiles.Count; ++i)
{
var tex = _f.TextureFiles[i];
var texPath = _basePath + "Tex_" + texLookup[i].ToString() + ".DDS";
if (!File.Exists(texPath))
{
continue;
}
var tex2d = AssetDatabase.LoadAssetAtPath(texPath, typeof(Texture2D)) as Texture2D;
Shader shader = null;
if (tex.TwoSided) {
if (tex.AlphaTestEnabled)
shader = Shader.Find("Transparent/Cutout/DoubleSided");
else if (tex.AlphaEnabled)
shader = Shader.Find("Transparent/DoubleSided");
else {
Debug.LogWarning("Two-sided non-alpha material encountered.");
}
} else if (tex.AlphaTestEnabled)
shader = Shader.Find("Transparent/Cutout/Diffuse");
else if (tex.AlphaEnabled)
shader = Shader.Find("Transparent/Diffuse");
else
shader = Shader.Find("Diffuse");
if (!shader)
{
Debug.LogWarning("Failed to find appropriate shader for material.");
continue;
}
var mat = new Material(shader);
if (tex.AlphaTestEnabled)
mat.SetFloat("_Cutoff", (float)tex.AlphaReference / 256);
mat.mainTexture = tex2d;
var matPath = _basePath + "Mat_" + i.ToString() + ".mat";
AssetDatabase.CreateAsset(mat, matPath);
_matLookup[i] = mat;
}
for (int i = 0; i < _f.Objects.Count; ++i)
{
var obj = _f.Objects[i];
var mdl = ScriptableObject.CreateInstance<RoseMapObjectData>();
for (int j = 0; j < obj.Parts.Count; ++j)
{
var part = obj.Parts[j];
var subObj = new RoseMapObjectData.SubObject();
subObj.mesh = _meshLookup[part.Model];
subObj.material = _matLookup[part.Texture];
subObj.animation = null;
subObj.parent = part.Parent;
subObj.position = rtuPosition(part.Position) / 100;
subObj.rotation = rtuRotation(part.Rotation);
subObj.scale = rtuScale(part.Scale);
if (part.Collision == Revise.Files.ZSC.CollisionType.None) {
subObj.colMode = 0;
} else {
subObj.colMode = 1;
}
if (part.AnimationFilePath != "") {
var animPath = _basePath + "Anim_" + i.ToString() + "_" + j.ToString() + ".asset";
var clip = ImportNodeAnimation(animPath, part.AnimationFilePath);
subObj.animation = clip;
}
mdl.subObjects.Add(subObj);
}
var mdlPath = _basePath + "Model_" + i.ToString() + ".asset";
AssetDatabase.CreateAsset(mdl, mdlPath);
EditorUtility.SetDirty(mdl);
}
}
/// <summary>
/// Tests the load method.
/// </summary>
private void TestLoadMethod(string filePath)
{
Stream stream = File.OpenRead(filePath);
stream.Seek(0, SeekOrigin.End);
long fileSize = stream.Position;
stream.Seek(0, SeekOrigin.Begin);
ModelFile modelFile = new ModelFile();
modelFile.Load(stream);
long streamPosition = stream.Position;
stream.Close();
Assert.AreEqual(fileSize, streamPosition, "Not all of the file was read");
}
/// <summary>
/// Tests the save method.
/// </summary>
private void TestSaveMethod(string filePath)
{
ModelFile modelFile = new ModelFile();
modelFile.Load(filePath);
MemoryStream savedStream = new MemoryStream();
modelFile.Save(savedStream);
savedStream.Seek(0, SeekOrigin.Begin);
ModelFile savedModelFile = new ModelFile();
savedModelFile.Load(savedStream);
savedStream.Close();
Assert.AreEqual(modelFile.Pool, savedModelFile.Pool, "Pool values do not match");
Assert.AreEqual(modelFile.BoneTable.Count, savedModelFile.BoneTable.Count, "Bone table counts do not match");
for (int i = 0; i < modelFile.BoneTable.Count; i++) {
Assert.AreEqual(modelFile.BoneTable[i], savedModelFile.BoneTable[i], "Bone table values do not match");
}
Assert.AreEqual(modelFile.Vertices.Count, savedModelFile.Vertices.Count, "Vertex counts do not match");
for (int i = 0; i < modelFile.Vertices.Count; i++) {
Assert.AreEqual(modelFile.Vertices[i].Position, savedModelFile.Vertices[i].Position, "Vertex position values do not match");
Assert.AreEqual(modelFile.Vertices[i].Normal, savedModelFile.Vertices[i].Normal, "Vertex normal values do not match");
Assert.AreEqual(modelFile.Vertices[i].Colour, savedModelFile.Vertices[i].Colour, "Vertex colour values do not match");
Assert.AreEqual(modelFile.Vertices[i].BoneWeights, savedModelFile.Vertices[i].BoneWeights, "Vertex bone weight values do not match");
Assert.AreEqual(modelFile.Vertices[i].BoneIndices, savedModelFile.Vertices[i].BoneIndices, "Vertex bone index values do not match");
Assert.AreEqual(modelFile.Vertices[i].TextureCoordinates[0], savedModelFile.Vertices[i].TextureCoordinates[0], "Vertex texture coordinate values do not match");
Assert.AreEqual(modelFile.Vertices[i].TextureCoordinates[1], savedModelFile.Vertices[i].TextureCoordinates[1], "Vertex texture coordinate values do not match");
Assert.AreEqual(modelFile.Vertices[i].TextureCoordinates[2], savedModelFile.Vertices[i].TextureCoordinates[2], "Vertex texture coordinate values do not match");
Assert.AreEqual(modelFile.Vertices[i].TextureCoordinates[3], savedModelFile.Vertices[i].TextureCoordinates[3], "Vertex texture coordinate values do not match");
Assert.AreEqual(modelFile.Vertices[i].Tangent, savedModelFile.Vertices[i].Tangent, "Vertex tangent values do not match");
}
Assert.AreEqual(modelFile.Indices.Count, savedModelFile.Indices.Count, "Index counts do not match");
for (int i = 0; i < modelFile.Indices.Count; i++) {
Assert.AreEqual(modelFile.Indices[i], savedModelFile.Indices[i], "Index values do not match");
}
Assert.AreEqual(modelFile.Materials.Count, savedModelFile.Materials.Count, "Material counts do not match");
for (int i = 0; i < modelFile.Materials.Count; i++) {
Assert.AreEqual(modelFile.Materials[i], savedModelFile.Materials[i], "Material values do not match");
}
Assert.AreEqual(modelFile.Strips.Count, savedModelFile.Strips.Count, "Strip counts do not match");
for (int i = 0; i < modelFile.Strips.Count; i++) {
Assert.AreEqual(modelFile.Strips[i], savedModelFile.Strips[i], "Strip values do not match");
}
}
