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mirror of synced 2024-12-04 20:08:00 +01:00
Switch-Toolbox/File_Format_Library/GL/BFRES/BFRESRenderBase.cs

256 lines
8.0 KiB
C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Threading.Tasks;
using Toolbox.Library;
using Toolbox.Library.Rendering;
using GL_EditorFramework.GL_Core;
using GL_EditorFramework.Interfaces;
using Bfres.Structs;
using OpenTK.Graphics.OpenGL;
using OpenTK;
namespace FirstPlugin
{
public class BFRESRenderBase : AbstractGlDrawable, IMeshContainer
{
public Matrix4 ModelTransform = Matrix4.Identity;
// gl buffer objects
internal int vbo_position;
internal int ibo_elements;
public BFRES ResFileNode;
public List<STGenericObject> Meshes
{
get
{
List<STGenericObject> meshes = new List<STGenericObject>();
for (int m = 0; m < models.Count; m++)
{
for (int s = 0; s < models[m].shapes.Count; s++)
meshes.Add(models[m].shapes[s]);
}
return meshes;
}
}
private List<FMDL> _models = new List<FMDL>();
public List<FMDL> models
{
get
{
return _models;
}
}
internal bool Disposing = false;
public void UpdateModelList()
{
_models.Clear();
foreach (var node in ResFileNode.Nodes)
{
if (node is BFRESGroupNode &&
((BFRESGroupNode)node).Type == BRESGroupType.Models)
{
foreach (FMDL mdl in ((BFRESGroupNode)node).Nodes)
_models.Add(mdl);
}
}
}
private void TransformBones()
{
for (int mdl = 0; mdl < models.Count; mdl++)
{
for (int b = 0; b < models[mdl].Skeleton.bones.Count; b++)
{
models[mdl].Skeleton.bones[b].ModelMatrix = ModelTransform;
}
}
}
internal void GenerateBuffers()
{
GL.GenBuffers(1, out vbo_position);
GL.GenBuffers(1, out ibo_elements);
TransformBones();
UpdateVertexData();
UpdateTextureMaps();
}
public void Destroy()
{
bool buffersWereInitialized = ibo_elements != 0 && vbo_position != 0;
if (!buffersWereInitialized)
return;
GL.DeleteBuffer(vbo_position);
GL.DeleteBuffer(ibo_elements);
Disposing = true;
}
public virtual void UpdateVertexData()
{
}
public virtual void UpdateTextureMaps()
{
if (!Runtime.OpenTKInitialized)
return;
foreach (BNTX bntx in PluginRuntime.bntxContainers)
{
if (!bntx.AllGLInitialized)
{
foreach (var tex in bntx.Textures)
{
if (tex.Value.RenderableTex != null && !tex.Value.RenderableTex.GLInitialized)
tex.Value.LoadOpenGLTexture();
}
}
}
foreach (BFRESGroupNode ftexCont in PluginRuntime.ftexContainers)
{
foreach (var tex in ftexCont.ResourceNodes)
{
if (!((FTEX)tex.Value).RenderableTex.GLInitialized)
((FTEX)tex.Value).LoadOpenGLTexture();
}
}
}
public void UpdateSingleMaterialTextureMaps(FMAT mat)
{
if (!Runtime.OpenTKInitialized)
return;
foreach (BNTX bntx in PluginRuntime.bntxContainers)
{
foreach (var t in mat.TextureMaps)
{
if (bntx.Textures.ContainsKey(t.Name))
{
if (!bntx.Textures[t.Name].RenderableTex.GLInitialized)
bntx.Textures[t.Name].LoadOpenGLTexture();
}
}
}
LibraryGUI.UpdateViewport();
}
public override void Prepare(GL_ControlModern control)
{
}
public override void Prepare(GL_ControlLegacy control)
{
}
public override void Draw(GL_ControlLegacy control, Pass pass)
{
if (Disposing || pass == Pass.TRANSPARENT) return;
bool buffersWereInitialized = ibo_elements != 0 && vbo_position != 0;
if (!buffersWereInitialized)
GenerateBuffers();
if (!Runtime.OpenTKInitialized)
return;
Matrix4 mvpMat = control.ModelMatrix * control.CameraMatrix * control.ProjectionMatrix;
Matrix4 invertedCamera = Matrix4.Identity;
if (invertedCamera.Determinant != 0)
invertedCamera = mvpMat.Inverted();
Vector3 lightDirection = new Vector3(0f, 0f, -1f);
Vector3 difLightDirection = Vector3.TransformNormal(lightDirection, invertedCamera).Normalized();
GL.Enable(EnableCap.Texture2D);
GL.Enable(EnableCap.DepthTest);
foreach (var model in models)
{
foreach (var shape in model.shapes)
{
if (Runtime.RenderModels && model.Checked && shape.Checked)
{
var mat = shape.GetMaterial();
List<int> faces = shape.lodMeshes[shape.DisplayLODIndex].getDisplayFace();
GL.Begin(PrimitiveType.Triangles);
foreach (var index in faces)
{
Vertex vert = shape.vertices[index];
float normal = Vector3.Dot(difLightDirection, vert.nrm) * 0.5f + 0.5f;
GL.Color3(new Vector3(normal));
GL.TexCoord2(vert.uv0);
GL.Vertex3(vert.pos);
}
GL.End();
}
}
}
GL.Enable(EnableCap.Texture2D);
}
public void CenterCamera(GL_ControlBase control)
{
if (!Runtime.FrameCamera)
return;
var spheres = new List<Vector4>();
for (int mdl = 0; mdl < models.Count; mdl++)
{
for (int shp = 0; shp < models[mdl].shapes.Count; shp++)
{
var vertexPositions = models[mdl].shapes[shp].vertices.Select(x => x.pos).Distinct();
spheres.Add(control.GenerateBoundingSphere(vertexPositions));
}
}
control.FrameSelect(spheres);
}
public static Vector4 GenerateBoundingSphere(IEnumerable<Vector4> boundingSpheres)
{
// The initial max/min should be the first point.
Vector3 min = boundingSpheres.FirstOrDefault().Xyz - new Vector3(boundingSpheres.FirstOrDefault().W);
Vector3 max = boundingSpheres.FirstOrDefault().Xyz + new Vector3(boundingSpheres.FirstOrDefault().W);
// Calculate the end points using the center and radius
foreach (var sphere in boundingSpheres)
{
min = Vector3.ComponentMin(min, sphere.Xyz - new Vector3(sphere.W));
max = Vector3.ComponentMax(max, sphere.Xyz + new Vector3(sphere.W));
}
return GetBoundingSphereFromSpheres(min, max);
}
private static Vector4 GetBoundingSphereFromSpheres(Vector3 min, Vector3 max)
{
Vector3 lengths = max - min;
float maxLength = Math.Max(lengths.X, Math.Max(lengths.Y, lengths.Z));
Vector3 center = (max + min) / 2.0f;
float radius = maxLength / 2.0f;
return new Vector4(center, radius);
}
public override void Draw(GL_ControlModern control, Pass pass) {
}
}
}