public Model(IDisposableResource parent, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals, string contentDirectory, Dictionary<string,Type> materialTypes, List<MaterialFieldBinder> value1BinderTypes, List<MaterialFieldBinder> value2BinderTypes, List<MaterialFieldBinder> value3BinderTypes, List<MaterialFieldBinder> value4BinderTypes, List<MaterialFieldBinder> textureBinderTypes, Dictionary<string,string> fileExtOverrides, int classicInstanceCount, Loader.LoadedCallbackMethod loadedCallback)
: base(parent)
{
Loader.AddLoadable(this);
new LoadWaiter(new ILoadable[]{softwareModel},
delegate(object sender, bool succeeeded)
{
if (succeeeded)
{
using (var stream = new MemoryStream())
{
try
{
Model.Save(stream, false, softwareModel, loadColors, loadUVs, loadNormals);
stream.Position = 0;
}
catch (Exception e)
{
FailedToLoad = true;
Dispose();
if (loadedCallback != null) loadedCallback(this, false);
}
if (!FailedToLoad) init(null, stream, contentDirectory, materialTypes, value1BinderTypes, value2BinderTypes, value3BinderTypes, value4BinderTypes, textureBinderTypes, fileExtOverrides, classicInstanceCount, loadedCallback);
}
}
else
{
FailedToLoad = true;
Dispose();
if (loadedCallback != null) loadedCallback(this, false);
}
});
}
public static void Save(string filename, bool compress, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals)
{
using (var file = Streams.SaveFile(filename, FolderLocations.Unknown))
#endif
{
Save(file, compress, softwareModel, loadColors, loadUVs, loadNormals);
}
}
public static void Write(BinaryWriter writer, SoftwareModel softwareModel, SoftwareMesh softwareMesh, bool loadColors, bool loadUVs, bool loadNormals)
{
List <BufferLayoutElement> elements;
float[] vertices;
int[] indices;
initData(softwareMesh, loadColors, loadUVs, loadNormals, out elements, out vertices, out indices);
// name
writer.Write(softwareMesh.Name);
// material
int materialIndex = -1;
if (softwareMesh.Material != null)
{
for (int i = 0; i != softwareModel.Materials.Count; ++i)
{
if (softwareMesh.Material == softwareModel.Materials[i])
{
materialIndex = i;
break;
}
}
}
writer.Write(materialIndex);
// elements
writer.Write(elements.Count);
foreach (var element in elements)
{
writer.Write((int)element.Type);
writer.Write((int)element.Usage);
writer.Write(element.StreamIndex);
writer.Write(element.UsageIndex);
writer.Write(element.FloatOffset);
}
// vertices
writer.Write(vertices.Length);
foreach (var vertex in vertices)
{
writer.Write(vertex);
}
// indices
writer.Write(indices.Length);
foreach (var index in indices)
{
writer.Write(index);
}
}
public SoftwareObjectArmature(SoftwareModel model, RMX_Object o)
: base(model, o)
{
// find armature
foreach (var armature in model.Armatures)
{
if (o.Armature.Name == armature.Name)
{
Armature = armature;
break;
}
}
if (Armature == null) Debug.ThrowError("SoftwareObjectArmature", "Failed to find Armature: " + o.Armature.Name);
}
public SoftwareObject(SoftwareModel model, RMX_Object o)
{
Model = model;
Name = o.Name;
// transform
foreach (var input in o.Transform.Inputs)
{
switch (input.Type)
{
case "EulerRotation": Rotation = new Vector3(input.Values[0], input.Values[1], input.Values[2]); break;
case "Scale": Scale = new Vector3(input.Values[0], input.Values[1], input.Values[2]); break;
case "Position": Position = new Vector3(input.Values[0], input.Values[1], input.Values[2]); break;
default: Debug.ThrowError("SoftwareMesh", "Unsuported Transform Type: " + input.Type); break;
}
}
// find action
if (o.DefaultAction != null)
{
foreach (var action in model.Actions)
{
if (o.DefaultAction.Name == action.Name)
{
DefaultAction = action;
break;
}
}
if (DefaultAction == null)
{
Debug.ThrowError("SoftwareObjectArmature", "Failed to find Action: " + o.DefaultAction.Name);
}
}
// bone groups
BoneGroups = new List <SoftwareObjectBoneGroup>();
if (o.BoneGroups != null)
{
foreach (var bonegroup in o.BoneGroups.BoneGroups)
{
BoneGroups.Add(new SoftwareObjectBoneGroup(bonegroup));
}
}
}
public SoftwareObjectArmature(SoftwareModel model, RMX_Object o)
: base(model, o)
{
// find armature
foreach (var armature in model.Armatures)
{
if (o.Armature.Name == armature.Name)
{
Armature = armature;
break;
}
}
if (Armature == null)
{
Debug.ThrowError("SoftwareObjectArmature", "Failed to find Armature: " + o.Armature.Name);
}
}
public Model(IDisposableResource parent, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals, string contentDirectory, Dictionary <string, Type> materialTypes, List <MaterialFieldBinder> value1BinderTypes, List <MaterialFieldBinder> value2BinderTypes, List <MaterialFieldBinder> value3BinderTypes, List <MaterialFieldBinder> value4BinderTypes, List <MaterialFieldBinder> textureBinderTypes, Dictionary <string, string> fileExtOverrides, int classicInstanceCount, Loader.LoadedCallbackMethod loadedCallback)
: base(parent)
{
Loader.AddLoadable(this);
new LoadWaiter(new ILoadable[] { softwareModel },
delegate(object sender, bool succeeeded)
{
if (succeeeded)
{
using (var stream = new MemoryStream())
{
try
{
Model.Save(stream, false, softwareModel, loadColors, loadUVs, loadNormals);
stream.Position = 0;
}
catch (Exception e)
{
FailedToLoad = true;
Dispose();
if (loadedCallback != null)
{
loadedCallback(this, false);
}
}
if (!FailedToLoad)
{
init(null, stream, contentDirectory, materialTypes, value1BinderTypes, value2BinderTypes, value3BinderTypes, value4BinderTypes, textureBinderTypes, fileExtOverrides, classicInstanceCount, loadedCallback);
}
}
}
else
{
FailedToLoad = true;
Dispose();
if (loadedCallback != null)
{
loadedCallback(this, false);
}
}
});
}
public SoftwareObject(SoftwareModel model, RMX_Object o)
{
Model = model;
Name = o.Name;
// transform
foreach (var input in o.Transform.Inputs)
{
switch (input.Type)
{
case "EulerRotation": Rotation = new Vector3(input.Values[0], input.Values[1], input.Values[2]); break;
case "Scale": Scale = new Vector3(input.Values[0], input.Values[1], input.Values[2]); break;
case "Position": Position = new Vector3(input.Values[0], input.Values[1], input.Values[2]); break;
default: Debug.ThrowError("SoftwareMesh", "Unsuported Transform Type: " + input.Type); break;
}
}
// find action
if (o.DefaultAction != null)
{
foreach (var action in model.Actions)
{
if (o.DefaultAction.Name == action.Name)
{
DefaultAction = action;
break;
}
}
if (DefaultAction == null) Debug.ThrowError("SoftwareObjectArmature", "Failed to find Action: " + o.DefaultAction.Name);
}
// bone groups
BoneGroups = new List<SoftwareObjectBoneGroup>();
if (o.BoneGroups != null)
{
foreach (var bonegroup in o.BoneGroups.BoneGroups)
{
BoneGroups.Add(new SoftwareObjectBoneGroup(bonegroup));
}
}
}
public SoftwareObjectMesh(SoftwareModel model, RMX_Object o)
: base(model, o)
{
if (o.Mesh != null)
{
foreach (var mesh in model.Meshes)
{
if (o.Mesh.Name == mesh.Name)
{
Mesh = mesh;
break;
}
}
if (Mesh == null)
{
Debug.ThrowError("SoftwareObjectMesh", "Failed to find mesh");
}
}
else
{
Debug.ThrowError("SoftwareObjectMesh", "RMX_Object be linked to a Mesh object");
}
}
public SoftwareMesh(SoftwareModel model, RMX_Mesh mesh)
{
Model = model;
Name = mesh.Name;
Verticies = new List <SoftwareVertex>();
Triangles = new List <SoftwareTriangle>();
Edges = new List <SoftwareEdge>();
VetexComponents = new List <object>();
TriangleComponents = new List <object>();
EdgeComponents = new List <object>();
VertexComponentKeys = new Dictionary <VertexComponentKeyTypes, int>();
TriangleComponentKeys = new Dictionary <TriangleComponentKeyTypes, int>();
EdgeComponentKeys = new Dictionary <EdgeComponentKeyTypes, int>();
// material
if (!string.IsNullOrEmpty(mesh.Material))
{
foreach (var material in model.Materials)
{
if (material.Name == mesh.Material)
{
this.Material = material;
}
}
if (Material == null)
{
Debug.ThrowError("SoftwareMesh", "Failed to find material: " + mesh.Material);
}
}
// verticies
var channels = mesh.Verticies.Channels;
int positionStep = 0;
for (int i = 0; i != channels.Length; ++i)
{
var channel = channels[i];
if (channel.ID != "Position")
{
continue;
}
Dimensions = channel.Step;
positionStep = channel.Step;
if (channel.Step == 3)
{
var vertexPostions = new Vector3[channel.Values.Length / 3];
var positions = channel.Values;
int i2 = 0;
for (int i3 = 0; i3 != vertexPostions.Length; ++i3)
{
Verticies.Add(new SoftwareVertex(i3));
vertexPostions[i3] = new Vector3(positions[i2], positions[i2 + 1], positions[i2 + 2]);
i2 += 3;
}
VetexComponents.Add(vertexPostions);
}
else if (channel.Step == 2)
{
var vertexPostions = new Vector2[channel.Values.Length / 2];
var positions = channel.Values;
int i2 = 0;
for (int i3 = 0; i3 != vertexPostions.Length; ++i3)
{
Verticies.Add(new SoftwareVertex(i3));
vertexPostions[i3] = new Vector2(positions[i2], positions[i2 + 1]);
i2 += 2;
}
VetexComponents.Add(vertexPostions);
}
else
{
Debug.ThrowError("SoftwareMesh", "Unsupotred position step count");
}
VertexComponentKeys.Add(VertexComponentKeyTypes.Positions, i);
}
// vertex bone groups
var counts = mesh.Verticies.BoneGroups.Counts.Values;
var indices = mesh.Verticies.BoneGroups.Indices.Values;
var weights = mesh.Verticies.BoneGroups.Weights.Values;
if (counts.Length != Verticies.Count)
{
Debug.ThrowError("SoftwareMesh", "BoneGroup counts do not match vertex count");
}
int bg = 0;
for (int i = 0; i != counts.Length; ++i)
{
for (int i2 = 0; i2 != counts[i]; ++i2)
{
int i3 = bg + i2;
Verticies[i].BoneGroups.Add(new SoftwareVertexBoneGroup(indices[i3], weights[i3]));
}
bg += counts[i];
}
// triangles
bool hasPositionData = false;
float[] colors = null, normals = null, uvs = null;
foreach (var channel in channels)
{
switch (channel.ID)
{
case "Position": hasPositionData = true; break;
case "Color": colors = channel.Values; break;
case "Normal": normals = channel.Values; break;
case "UV": uvs = channel.Values; break;
}
}
if (!hasPositionData)
{
Debug.ThrowError("SoftwareMesh", "Vertices missing position data");
}
int[] positionIndices = null, colorIndices = null, normalIndices = null, uvIndices = null;
foreach (var index in mesh.Faces.Indices)
{
switch (index.ID)
{
case "Position": positionIndices = index.Values; break;
case "Color": colorIndices = index.Values; break;
case "Normal": normalIndices = index.Values; break;
case "UV": uvIndices = index.Values; break;
}
}
if (positionIndices == null)
{
Debug.ThrowError("SoftwareMesh", "Faces missing position data");
}
var triangleColors = new List <TriangleColorComponent>();
var triangleNormals = new List <TriangleNormalComponent>();
var triangleUVs = new List <TriangleUVComponent>();
int ti = 0, vi = 0;
if (positionStep == 3)
{
foreach (int step in mesh.Faces.Steps.Values)
{
int loop = step - 2;
int vi2 = vi + 1, vi3 = vi + 2;
for (int i2 = 0; i2 != loop; ++i2)
{
var triangle = new SoftwareTriangle(ti, Verticies[positionIndices[vi]], Verticies[positionIndices[vi2]], Verticies[positionIndices[vi3]]);
Triangles.Add(triangle);
if (colorIndices != null)
{
int cii = colorIndices[vi] * 3, cii2 = colorIndices[vi2] * 3, cii3 = colorIndices[vi3] * 3;
triangleColors.Add(new TriangleColorComponent
(
new Vector4(colors[cii], colors[cii + 1], colors[cii + 2], colors[cii + 3]),
new Vector4(colors[cii2], colors[cii2 + 1], colors[cii2 + 2], colors[cii2 + 3]),
new Vector4(colors[cii3], colors[cii3 + 1], colors[cii3 + 2], colors[cii3 + 3]))
);
}
if (normalIndices != null)
{
int nii = normalIndices[vi] * 3, nii2 = normalIndices[vi2] * 3, nii3 = normalIndices[vi3] * 3;
triangleNormals.Add(new TriangleNormalComponent
(
new Vector3(normals[nii], normals[nii + 1], normals[nii + 2]),
new Vector3(normals[nii2], normals[nii2 + 1], normals[nii2 + 2]),
new Vector3(normals[nii3], normals[nii3 + 1], normals[nii3 + 2]))
);
}
if (uvIndices != null)
{
int uii = uvIndices[vi] * 2, uii2 = uvIndices[vi2] * 2, uii3 = uvIndices[vi3] * 2;
triangleUVs.Add(new TriangleUVComponent
(
new Vector2(uvs[uii], uvs[uii + 1]),
new Vector2(uvs[uii2], uvs[uii2 + 1]),
new Vector2(uvs[uii3], uvs[uii3 + 1]))
);
}
++ti;
++vi2;
++vi3;
}
vi += step;
}
}
else
{
Debug.ThrowError("SoftwareMesh", "Position step not implemented yet: Step value = " + positionStep);
}
int componentIndex = 0;
if (colors != null)
{
TriangleComponents.Add(triangleColors.ToArray());
TriangleComponentKeys.Add(TriangleComponentKeyTypes.ColorComponents, componentIndex);
++componentIndex;
}
if (normals != null)
{
TriangleComponents.Add(triangleNormals.ToArray());
TriangleComponentKeys.Add(TriangleComponentKeyTypes.NormalComponents, componentIndex);
++componentIndex;
}
if (uvs != null)
{
TriangleComponents.Add(triangleUVs.ToArray());
TriangleComponentKeys.Add(TriangleComponentKeyTypes.UVComponents, componentIndex);
++componentIndex;
}
}
public static void Save(Stream stream, bool compress, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals)
{
var writer = new BinaryWriter(stream);
// meta data
writer.Write(Streams.MakeFourCC('R', 'M', 'F', 'T'));// tag
writer.Write(1.0f);// version
writer.Write(false);//compress);// TODO: add zip compression
// frames
writer.Write(softwareModel.FrameStart);
writer.Write(softwareModel.FrameEnd);
writer.Write(softwareModel.FPS);
// materials
writer.Write(softwareModel.Materials.Count);
foreach (var material in softwareModel.Materials)
{
writer.Write(material.Name);
// values1
writer.Write(material.Values1.Count);
foreach (var value in material.Values1)
{
writer.Write(value.Key);
writer.Write(value.Value);
}
// values2
writer.Write(material.Values2.Count);
foreach (var value in material.Values2)
{
writer.Write(value.Key);
writer.WriteVector(value.Value);
}
// values3
writer.Write(material.Values3.Count);
foreach (var value in material.Values3)
{
writer.Write(value.Key);
writer.WriteVector(value.Value);
}
// values4
writer.Write(material.Values4.Count);
foreach (var value in material.Values4)
{
writer.Write(value.Key);
writer.WriteVector(value.Value);
}
// textures
writer.Write(material.Textures.Count);
foreach (var texture in material.Textures)
{
writer.Write(texture.Key);
writer.Write(texture.Value);
}
}
// meshes
writer.Write(softwareModel.Meshes.Count);
foreach (var mesh in softwareModel.Meshes)
{
Mesh.Write(writer, softwareModel, mesh, loadColors, loadUVs, loadNormals);
}
// actions
writer.Write(softwareModel.Actions.Count);
foreach (var action in softwareModel.Actions)
{
Action.Write(writer, action);
}
// armatures
writer.Write(softwareModel.Armatures.Count);
foreach (var armature in softwareModel.Armatures)
{
Armature.Write(writer, armature);
}
// objects
writer.Write(softwareModel.Objects.Count);
foreach (var o in softwareModel.Objects)
{
Object.Write(writer, o);
}
}
public static void Save(string filename, bool compress, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals)
{
using (var file = Streams.SaveFile(filename, FolderLocations.Unknown))
#endif
{
Save(file, compress, softwareModel, loadColors, loadUVs, loadNormals);
}
}
public static async void Save(string filename, bool compress, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals)
{
using (var file = await Streams.SaveFile(filename, FolderLocations.Unknown))
public static void Write(BinaryWriter writer, SoftwareModel softwareModel, SoftwareMesh softwareMesh, bool loadColors, bool loadUVs, bool loadNormals)
{
List<BufferLayoutElement> elements;
float[] vertices;
int[] indices;
initData(softwareMesh, loadColors, loadUVs, loadNormals, out elements, out vertices, out indices);
// name
writer.Write(softwareMesh.Name);
// material
int materialIndex = -1;
if (softwareMesh.Material != null)
{
for (int i = 0; i != softwareModel.Materials.Count; ++i)
{
if (softwareMesh.Material == softwareModel.Materials[i])
{
materialIndex = i;
break;
}
}
}
writer.Write(materialIndex);
// elements
writer.Write(elements.Count);
foreach (var element in elements)
{
writer.Write((int)element.Type);
writer.Write((int)element.Usage);
writer.Write(element.StreamIndex);
writer.Write(element.UsageIndex);
writer.Write(element.FloatOffset);
}
// vertices
writer.Write(vertices.Length);
foreach (var vertex in vertices)
{
writer.Write(vertex);
}
// indices
writer.Write(indices.Length);
foreach (var index in indices)
{
writer.Write(index);
}
}
public static void Save(Stream stream, bool compress, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals)
{
var writer = new BinaryWriter(stream);
// meta data
writer.Write(Streams.MakeFourCC('R', 'M', 'F', 'T')); // tag
writer.Write(1.0f); // version
writer.Write(false); //compress);// TODO: add zip compression
// frames
writer.Write(softwareModel.FrameStart);
writer.Write(softwareModel.FrameEnd);
writer.Write(softwareModel.FPS);
// materials
writer.Write(softwareModel.Materials.Count);
foreach (var material in softwareModel.Materials)
{
writer.Write(material.Name);
// values1
writer.Write(material.Values1.Count);
foreach (var value in material.Values1)
{
writer.Write(value.Key);
writer.Write(value.Value);
}
// values2
writer.Write(material.Values2.Count);
foreach (var value in material.Values2)
{
writer.Write(value.Key);
writer.WriteVector(value.Value);
}
// values3
writer.Write(material.Values3.Count);
foreach (var value in material.Values3)
{
writer.Write(value.Key);
writer.WriteVector(value.Value);
}
// values4
writer.Write(material.Values4.Count);
foreach (var value in material.Values4)
{
writer.Write(value.Key);
writer.WriteVector(value.Value);
}
// textures
writer.Write(material.Textures.Count);
foreach (var texture in material.Textures)
{
writer.Write(texture.Key);
writer.Write(texture.Value);
}
}
// meshes
writer.Write(softwareModel.Meshes.Count);
foreach (var mesh in softwareModel.Meshes)
{
Mesh.Write(writer, softwareModel, mesh, loadColors, loadUVs, loadNormals);
}
// actions
writer.Write(softwareModel.Actions.Count);
foreach (var action in softwareModel.Actions)
{
Action.Write(writer, action);
}
// armatures
writer.Write(softwareModel.Armatures.Count);
foreach (var armature in softwareModel.Armatures)
{
Armature.Write(writer, armature);
}
// objects
writer.Write(softwareModel.Objects.Count);
foreach (var o in softwareModel.Objects)
{
Object.Write(writer, o);
}
}
public static async void Save(string filename, bool compress, SoftwareModel softwareModel, bool loadColors, bool loadUVs, bool loadNormals)
{
using (var file = await Streams.SaveFile(filename, FolderLocations.Unknown))
