using System; using System.Collections.Generic; using System.Linq; using System.Windows.Forms; using Toolbox.Library; using Toolbox.Library.IO; using Toolbox.Library.Rendering; using Toolbox.Library.Forms; using OpenTK; using GL_EditorFramework.GL_Core; using OpenTK.Graphics.OpenGL; namespace FirstPlugin { class MOD : TreeNodeFile, IFileFormat { public FileType FileType { get; set; } = FileType.Model; public bool CanSave { get; set; } public string[] Description { get; set; } = new string[] { "Pikmin 1 Model Format" }; public string[] Extension { get; set; } = new string[] { "*.mod" }; public string FileName { get; set; } public string FilePath { get; set; } public IFileInfo IFileInfo { get; set; } public bool Identify(System.IO.Stream stream) { return Utils.HasExtension(FileName, ".mod"); } public Type[] Types { get { List types = new List(); return types.ToArray(); } } //Check for the viewport in the object editor //This is attached to it to load multiple file formats within the object editor to the viewer Viewport viewport { get { var editor = LibraryGUI.GetObjectEditor(); return editor.GetViewport(); } set { var editor = LibraryGUI.GetObjectEditor(); editor.LoadViewport(value); } } bool DrawablesLoaded = false; public override void OnClick(TreeView treeView) { //Make sure opengl is enabled if (Runtime.UseOpenGL) { //Open the viewport if (viewport == null) { viewport = new Viewport(ObjectEditor.GetDrawableContainers()); viewport.Dock = DockStyle.Fill; } //Make sure to load the drawables only once so set it to true! if (!DrawablesLoaded) { ObjectEditor.AddContainer(DrawableContainer); DrawablesLoaded = true; } //Reload which drawable to display viewport.ReloadDrawables(DrawableContainer); LibraryGUI.LoadEditor(viewport); viewport.Text = Text; } } public MDL_Renderer Renderer; public DrawableContainer DrawableContainer = new DrawableContainer(); private STSkeleton Skeleton; private Vector3[] Vertices; private Vector3[] VertexNormals; private Vector4[] Colors; private enum ChunkNames { Header, VertexPosition = 0x0010, VertexNormal = 0x0011, VertexNBT = 0x0012, VertexColor = 0x0013, VertexUV0 = 0x0018, VertexUV1 = 0x0019, VertexUV2 = 0x001A, VertexUV3 = 0x001B, VertexUV4 = 0x001C, VertexUV5 = 0x001D, VertexUV6 = 0x001E, VertexUV7 = 0x001F, Texture = 0x0020, TextureAttribute = 0x0022, Material = 0x0030, VertexMatrix = 0x0040, Envelope = 0x0041, Mesh = 0x0050, Joint = 0x0060, JointName = 0x0061, CollisionPrism = 0x0100, CollisionGrid = 0x0110, EoF = 0xFFFF } private void SkipPadding(FileReader stream, int offset) { stream.Seek((~(offset - 1) & (stream.Position + offset - 1)) - stream.Position); } public void Load(System.IO.Stream stream) { CanSave = true; Text = FileName; //Set renderer //Load it to a drawables list Renderer = new MDL_Renderer(); Skeleton = new STSkeleton(); DrawableContainer.Name = FileName; DrawableContainer.Drawables.Add(Renderer); DrawableContainer.Drawables.Add(Skeleton); using (var reader = new FileReader(stream)) { reader.SetByteOrder(true); while (reader.EndOfStream == false) { long chunkStart = reader.Position; int opcode = reader.ReadInt32(); int lengthOfStruct = reader.ReadInt32(); // basic error checking if ((chunkStart & 0x1F) != 0) throw new Exception($"Chunk start ({chunkStart}) not on boundary!"); switch ((ChunkNames)opcode) { case ChunkNames.VertexPosition: Vertices = ReadVector3Array(reader); break; case ChunkNames.VertexNormal: VertexNormals = ReadVector3Array(reader); break; case ChunkNames.VertexColor: Colors = ReadVertexColors(reader); break; case ChunkNames.Mesh: ReadMeshChunk(reader); break; default: reader.Seek(lengthOfStruct, System.IO.SeekOrigin.Current); break; } } } } private Vector4[] ReadVertexColors(FileReader reader) { int count = reader.ReadInt32(); Vector4[] vertexData = new Vector4[count]; SkipPadding(reader, 0x20); for (int i = 0; i < count; i++) Colors[i] = new Vector4( reader.ReadByte() / 255f, reader.ReadByte() / 255f, reader.ReadByte() / 255f, reader.ReadByte() / 255f); SkipPadding(reader, 0x20); return vertexData; } private Vector3[] ReadVector3Array(FileReader reader) { int count = reader.ReadInt32(); Vector3[] vertexData = new Vector3[count]; SkipPadding(reader, 0x20); for (int i = 0; i < count; i++) vertexData[i] = reader.ReadVec3(); SkipPadding(reader, 0x20); return vertexData; } private void ReadMeshChunk(FileReader reader) { int meshCount = reader.ReadInt32(); SkipPadding(reader, 0x20); for (int mIdx = 0; mIdx < meshCount; mIdx++) { //Create a renderable object for our mesh var renderedMesh = new GenericRenderedObject { Checked = true, ImageKey = "mesh", SelectedImageKey = "mesh", Text = $"Mesh {mIdx}" }; Nodes.Add(renderedMesh); Renderer.Meshes.Add(renderedMesh); STGenericPolygonGroup polyGroup = new STGenericPolygonGroup(); renderedMesh.PolygonGroups.Add(polyGroup); renderedMesh.BoneIndex = reader.ReadInt32(); int vtxDescriptor = reader.ReadInt32(); int mtxGroupCount = reader.ReadInt32(); for (int mgIdx = 0; mgIdx < mtxGroupCount; mgIdx++) { int dependencyCount = reader.ReadInt32(); for (int ll = 0; ll < dependencyCount; ll++) reader.ReadInt16(); int dListCount = reader.ReadInt32(); for (int dlIdx = 0; dlIdx < dListCount; dlIdx++) { int flags = reader.ReadInt32(); int unk1 = reader.ReadInt32(); int dataSize = reader.ReadInt32(); SkipPadding(reader, 0x20); long endPosition = reader.Position + dataSize; while (reader.Position < endPosition) { byte faceType = reader.ReadByte(); if (faceType == 0x98 || faceType == 0xA0) { short faceCount = reader.ReadInt16(); int[] polygons = new int[faceCount]; for (int fIdx = 0; fIdx < faceCount; fIdx++) { if ((vtxDescriptor & 1) == 1) reader.ReadByte(); // posmat index if ((vtxDescriptor & 2) == 2) reader.ReadByte(); // tex1 index ushort vtxIdx = reader.ReadUInt16(); ushort nrmIdx = 0; if (VertexNormals.Length > 0) nrmIdx = reader.ReadUInt16(); ushort colIdx = 0; if ((vtxDescriptor & 4) == 4) colIdx = reader.ReadUInt16(); int txCoordIdx = 0; int txCoordDescriptor = vtxDescriptor >> 3; for (int tcoordIdx = 0; tcoordIdx < 8; tcoordIdx++) { if ((txCoordDescriptor & 1) == 0x1) { // Only read for the first texcoord txCoordIdx = reader.ReadInt16(); txCoordDescriptor >>= 1; } } Vertex newVertex = new Vertex { pos = Vertices[vtxIdx] }; if (VertexNormals != null) newVertex.nrm = VertexNormals[nrmIdx]; if (Colors != null) newVertex.col = Colors[colIdx]; polygons[fIdx] = renderedMesh.vertices.Count; renderedMesh.vertices.Add(newVertex); } List currentPolygons = ToTris(polygons, faceType); Console.WriteLine($"faceType {faceType} polygons {polygons.Length} "); foreach (Triangle triangle in currentPolygons) { if (faceType == 0x98) { polyGroup.faces.Add(triangle.B); polyGroup.faces.Add(triangle.C); polyGroup.faces.Add(triangle.A); } else { polyGroup.faces.Add(triangle.C); polyGroup.faces.Add(triangle.B); polyGroup.faces.Add(triangle.A); } } } } } } } } private static List ToTris(int[] polys, byte opcode) { if (polys.Length == 3) return new List() { new Triangle() { A = polys[0], B = polys[1], C = polys[2] } }; var tris = new List(); if (opcode == 0x98) { int n = 2; for (int x = 0; x < polys.Length - 2; x++) { int[] tri = new int[3]; bool isEven = (n % 2) == 0; tri[0] = polys[n - 2]; tri[1] = isEven ? polys[n] : polys[n - 1]; tri[2] = isEven ? polys[n - 1] : polys[n]; if (tri[0] != tri[1] && tri[1] != tri[2] && tri[2] != tri[0]) tris.Add(new Triangle() { A = tri[0], B = tri[1], C = tri[2], }); n++; } } if (opcode == 0xA0) { for (int n = 1; n < polys.Length - 1; n++) { int[] tri = new int[3]; tri[0] = polys[n]; tri[1] = polys[n + 1]; tri[2] = polys[0]; if (tri[0] != tri[1] && tri[1] != tri[2] && tri[2] != tri[0]) tris.Add(new Triangle() { A = tri[0], B = tri[1], C = tri[2], }); } } return tris; } public class Triangle { public int A; public int B; public int C; } public class Vector3Holder { public Vector3 value; public void Read(FileReader reader) { value.X = reader.ReadSingle(); value.Y = reader.ReadSingle(); value.Z = reader.ReadSingle(); } } public void Unload() { } public void Save(System.IO.Stream stream) { } public class MaterialTextureMap : STGenericMatTexture { //The index of a texture //Some formats will map them by index, some by name, some by a hash, it's up to how the user handles it public int TextureIndex { get; set; } } public class MDL_Renderer : GenericModelRenderer { //A list of textures to display on the model public List TextureList = new List(); public override void OnRender(GLControl control) { //Here we can add things on each frame rendered } //Render data to display by per material and per mesh public override void SetRenderData(STGenericMaterial mat, ShaderProgram shader, STGenericObject m) { } //Custom bind texture method public override int BindTexture(STGenericMatTexture tex, ShaderProgram shader) { //By default we bind to the default texture to use //This will be used if no texture is found GL.ActiveTexture(TextureUnit.Texture0 + tex.textureUnit + 1); GL.BindTexture(TextureTarget.Texture2D, RenderTools.defaultTex.RenderableTex.TexID); string activeTex = tex.Name; //We want to cast our custom texture map class to get any custom properties we may need //If you don't need any custom way of mapping, you can just stick with the generic one var matTexture = (MaterialTextureMap)tex; //Go through our texture maps in the material and see if the index matches foreach (var texture in TextureList) { if (TextureList.IndexOf(texture) == matTexture.TextureIndex) { BindGLTexture(tex, shader, TextureList[matTexture.TextureIndex]); return tex.textureUnit + 1; } //You can also check if the names match if (texture.Text == tex.Name) { BindGLTexture(tex, shader, TextureList[matTexture.TextureIndex]); return tex.textureUnit + 1; } } //Return our texture uint id. return tex.textureUnit + 1; } } } }