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Switch-Toolbox/File_Format_Library/GL/KCL_Render.cs
KillzXGaming 8939687f6a Update files.
Load vertex positions for layouts in rectangle class. This will be used for proper rotation adjusting.
Add latest muunt editor files.
Add somewhat functional mk8 camera bin editor. Points can be moved around. The map orientation determines the position of the icons to map over the model.
Fix window content UV map for layouts.
Add 2D KCL renderer for top down KCL preview for both muunt and camera editors.
2019-10-26 20:28:56 -04:00

458 lines
16 KiB
C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.IO;
using System.Threading.Tasks;
using GL_EditorFramework.GL_Core;
using GL_EditorFramework.Interfaces;
using OpenTK;
using OpenTK.Graphics.OpenGL;
using Toolbox.Library;
using Toolbox.Library.Rendering;
namespace FirstPlugin
{
public class KCLRendering : AbstractGlDrawable
{
public bool DrawGlobalOctrees = false;
public List<KCL.OctreeNode> OctreeNodes = new List<KCL.OctreeNode>();
public MarioKart.MK7.KCL KclFile;
public Vector3 Max = new Vector3(0);
public Vector3 Min = new Vector3(0);
public List<ushort> SelectedTypes = new List<ushort>();
public Vector3 position = new Vector3(0, 0, 0);
protected bool Selected = false;
protected bool Hovered = false;
// public override bool IsSelected() => Selected;
// public override bool IsSelected(int partIndex) => Selected;
public bool IsHovered() => Selected;
// gl buffer objects
int vbo_position;
int ibo_elements;
//Set the game's material list
public KCL.GameSet GameMaterialSet = KCL.GameSet.MarioKart8D;
public List<KCL.KCLModel> models = new List<KCL.KCLModel>();
private void GenerateBuffers()
{
GL.GenBuffers(1, out vbo_position);
GL.GenBuffers(1, out ibo_elements);
}
public void Destroy()
{
GL.DeleteBuffer(vbo_position);
GL.DeleteBuffer(ibo_elements);
}
public void UpdateVertexData()
{
if (!Runtime.OpenTKInitialized)
return;
KCL.DisplayVertex[] Vertices;
int[] Faces;
int poffset = 0;
int voffset = 0;
List<KCL.DisplayVertex> Vs = new List<KCL.DisplayVertex>();
List<int> Ds = new List<int>();
foreach (KCL.KCLModel m in models)
{
m.Offset = poffset * 4;
List<KCL.DisplayVertex> pv = m.CreateDisplayVertices();
Vs.AddRange(pv);
for (int i = 0; i < m.displayFaceSize; i++)
{
Ds.Add(m.display[i] + voffset);
}
poffset += m.displayFaceSize;
voffset += pv.Count;
}
// Binds
Vertices = Vs.ToArray();
Faces = Ds.ToArray();
// Bind only once!
GL.BindBuffer(BufferTarget.ArrayBuffer, vbo_position);
GL.BufferData<KCL.DisplayVertex>(BufferTarget.ArrayBuffer, (IntPtr)(Vertices.Length * KCL.DisplayVertex.Size), Vertices, BufferUsageHint.StaticDraw);
GL.BindBuffer(BufferTarget.ElementArrayBuffer, ibo_elements);
GL.BufferData<int>(BufferTarget.ElementArrayBuffer, (IntPtr)(Faces.Length * sizeof(int)), Faces, BufferUsageHint.StaticDraw);
LibraryGUI.UpdateViewport();
}
public void DrawGlobalOctree(ref Matrix4 mvp)
{
var octreeMax = KclFile.GlobalHeader.OctreeMax;
var octreeOrigin = KclFile.GlobalHeader.OctreeOrigin;
Vector3 max = new Vector3((float)octreeMax.X, (float)octreeMax.Y, (float)octreeMax.Z);
Vector3 min = new Vector3((float)octreeOrigin.X, (float)octreeOrigin.Y, (float)octreeOrigin.Z);
Console.WriteLine("DrawGlobalOctree " + min + " " + max);
var size = max - min;
var BoxSize = size / 2f;
var QuarterSize = BoxSize / 2f;
// DrawableBoundingBox.DrawBoundingBox(mvp, min, max, new Vector3(0));
DrawSubdivision(ref mvp, min, size, OctreeNodes, 0);
}
private void DrawSubdivision(ref Matrix4 mvp, Vector3 min, Vector3 size, List<KCL.OctreeNode> modelOctrees, int subdiv)
{
var BoxSize = size / 2f;
var QuarterSize = BoxSize / 2f;
int index = 0;
for (int z = 0; z < 2; z++)
{
for (int y = 0; y < 2; y++)
{
for (int x = 0; x < 2; x++)
{
var Boxmin = min + BoxSize * new Vector3(x,y,z);
var pos = BoxSize * new Vector3(x, y, z);
if (modelOctrees[index].IsSelected)
DrawableBoundingBox.DrawBoundingBox(mvp, QuarterSize, Boxmin + QuarterSize, System.Drawing.Color.Red);
else
DrawableBoundingBox.DrawBoundingBox(mvp, QuarterSize, Boxmin + QuarterSize, System.Drawing.Color.Green);
if (modelOctrees[index].Nodes.Count > 0)
DrawSubdivision(ref mvp, Boxmin, BoxSize, modelOctrees[index].Children, subdiv++);
index++;
}
}
}
}
public ShaderProgram defaultShaderProgram;
public ShaderProgram solidColorShaderProgram;
public override void Prepare(GL_ControlModern control)
{
string pathFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader") + "\\KCL.frag";
string pathVert = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader") + "\\KCL.vert";
var defaultFrag = new FragmentShader(File.ReadAllText(pathFrag));
var defaultVert = new VertexShader(File.ReadAllText(pathVert));
var solidColorFrag = new FragmentShader(
@"#version 330
uniform vec4 color;
out vec4 FragColor;
void main(){
FragColor = color;
}");
var solidColorVert = new VertexShader(
@"#version 330
in vec3 vPosition;
in vec3 vNormal;
in vec3 vColor;
out vec3 normal;
out vec3 color;
out vec3 position;
uniform mat4 mtxMdl;
uniform mat4 mtxCam;
void main(){
normal = vNormal;
color = vColor;
position = vPosition;
gl_Position = mtxMdl * mtxCam * vec4(vPosition.xyz, 1.0);
}");
defaultShaderProgram = new ShaderProgram(defaultFrag, defaultVert, control);
solidColorShaderProgram = new ShaderProgram(solidColorFrag, solidColorVert, control);
}
public override void Prepare(GL_ControlLegacy control)
{
}
private void CheckBuffers()
{
if (!Runtime.OpenTKInitialized)
return;
bool buffersWereInitialized = ibo_elements != 0 && vbo_position != 0;
if (!buffersWereInitialized)
{
GenerateBuffers();
UpdateVertexData();
}
}
public override void Draw(GL_ControlLegacy control, Pass pass)
{
if (!Runtime.OpenTKInitialized || defaultShaderProgram == null)
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.Disable(EnableCap.Texture2D);
GL.Enable(EnableCap.DepthTest);
foreach (var model in models)
{
if (Runtime.RenderModels && model.Checked && model.Checked)
{
List<int> faces = model.getDisplayFace();
GL.Begin(PrimitiveType.Triangles);
foreach (var index in faces)
{
Vertex vert = model.vertices[index];
float normal = Vector3.Dot(difLightDirection, vert.nrm) * 0.5f + 0.5f;
GL.Color3(new Vector3(normal));
GL.Vertex3(vert.pos);
}
GL.End();
}
}
GL.Enable(EnableCap.Texture2D);
}
public override void Draw(GL_ControlModern control, Pass pass)
{
CheckBuffers();
if (!Runtime.OpenTKInitialized || pass == Pass.TRANSPARENT || defaultShaderProgram == null)
return;
Matrix4 camMat = control.ModelMatrix * control.CameraMatrix * control.ProjectionMatrix;
if (DrawGlobalOctrees)
DrawGlobalOctree(ref camMat);
control.CurrentShader = defaultShaderProgram;
control.UpdateModelMatrix(
Matrix4.CreateScale(Runtime.previewScale));
SetRenderSettings(defaultShaderProgram);
GL.Disable(EnableCap.CullFace);
GL.Uniform3(defaultShaderProgram["difLightDirection"], Vector3.TransformNormal(new Vector3(0f, 0f, -1f), camMat.Inverted()).Normalized());
GL.Uniform3(defaultShaderProgram["difLightColor"], new Vector3(1));
GL.Uniform3(defaultShaderProgram["ambLightColor"], new Vector3(1));
defaultShaderProgram.EnableVertexAttributes();
foreach (KCL.KCLModel mdl in models)
{
DrawModel(mdl, defaultShaderProgram);
}
defaultShaderProgram.DisableVertexAttributes();
GL.UseProgram(0);
GL.Disable(EnableCap.DepthTest);
GL.Enable(EnableCap.DepthTest);
GL.Enable(EnableCap.CullFace);
}
private void SetRenderSettings(ShaderProgram shader)
{
shader.SetBoolToInt("renderVertColor", Runtime.renderVertColor);
GL.Uniform1(defaultShaderProgram["renderType"], (int)Runtime.viewportShading);
}
private void DrawModel(KCL.KCLModel m, ShaderProgram shader, bool drawSelection = false)
{
if (m.faces.Count <= 3)
return;
SetVertexAttributes(m, shader);
if (m.Checked)
{
if ((m.IsSelected))
{
DrawModelSelection(m, shader);
}
else
{
if (Runtime.RenderModelWireframe)
{
DrawModelWireframe(m, shader);
}
if (Runtime.RenderModels)
{
GL.DrawElements(PrimitiveType.Triangles, m.displayFaceSize, DrawElementsType.UnsignedInt, m.Offset);
}
}
}
}
private static void DrawModelSelection(KCL.KCLModel p, ShaderProgram shader)
{
//This part needs to be reworked for proper outline. Currently would make model disappear
GL.DrawElements(PrimitiveType.Triangles, p.displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
GL.Enable(EnableCap.StencilTest);
// use vertex color for wireframe color
GL.Uniform1(shader["colorOverride"], 1);
GL.PolygonMode(MaterialFace.Front, PolygonMode.Line);
GL.Enable(EnableCap.LineSmooth);
GL.LineWidth(1.5f);
GL.DrawElements(PrimitiveType.Triangles, p.displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
GL.PolygonMode(MaterialFace.FrontAndBack, PolygonMode.Fill);
GL.Uniform1(shader["colorOverride"], 0);
GL.Enable(EnableCap.DepthTest);
}
private void SetVertexAttributes(KCL.KCLModel m, ShaderProgram shader)
{
GL.BindBuffer(BufferTarget.ArrayBuffer, vbo_position);
GL.VertexAttribPointer(shader.GetAttribute("vPosition"), 3, VertexAttribPointerType.Float, false, KCL.DisplayVertex.Size, 0);
GL.VertexAttribPointer(shader.GetAttribute("vNormal"), 3, VertexAttribPointerType.Float, false, KCL.DisplayVertex.Size, 12);
GL.VertexAttribPointer(shader.GetAttribute("vColor"), 3, VertexAttribPointerType.Float, false, KCL.DisplayVertex.Size, 24);
GL.BindBuffer(BufferTarget.ElementArrayBuffer, ibo_elements);
}
private static void DrawModelWireframe(KCL.KCLModel p, ShaderProgram shader)
{
// use vertex color for wireframe color
GL.Uniform1(shader["colorOverride"], 1);
GL.PolygonMode(MaterialFace.Front, PolygonMode.Line);
GL.Enable(EnableCap.LineSmooth);
GL.LineWidth(1.5f);
GL.DrawElements(PrimitiveType.Triangles, p.displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
GL.PolygonMode(MaterialFace.FrontAndBack, PolygonMode.Fill);
GL.Uniform1(shader["colorOverride"], 0);
}
/* public override BoundingBox GetSelectionBox()
{
Vector3 Min = new Vector3(0);
Vector3 Max = new Vector3(0);
foreach (var model in models)
{
foreach (var vertex in model.vertices)
{
Min.X = Math.Min(Min.X, vertex.pos.X);
Min.Y = Math.Min(Min.Y, vertex.pos.Y);
Min.Z = Math.Min(Min.Z, vertex.pos.Z);
Max.X = Math.Max(Max.X, vertex.pos.X);
Max.Y = Math.Max(Max.Y, vertex.pos.Y);
Max.Z = Math.Max(Max.Z, vertex.pos.Z);
}
}
return new BoundingBox()
{
minX = Min.X,
minY = Min.Y,
minZ = Min.Z,
maxX = Max.X,
maxY = Max.Y,
maxZ = Max.Z,
};
}
public override LocalOrientation GetLocalOrientation(int partIndex)
{
return new LocalOrientation(position);
}
public override bool TryStartDragging(DragActionType actionType, int hoveredPart, out LocalOrientation localOrientation, out bool dragExclusively)
{
localOrientation = new LocalOrientation(position);
dragExclusively = false;
return Selected;
}
public override bool IsInRange(float range, float rangeSquared, Vector3 pos)
{
range = 20000; //Make the range large for now. Todo go back to this
BoundingBox box = GetSelectionBox();
if (pos.X < box.maxX + range && pos.X > box.minX - range &&
pos.Y < box.maxY + range && pos.Y > box.minY - range &&
pos.Z < box.maxZ + range && pos.Z > box.minZ - range)
return true;
return false;
}
public override uint SelectAll(GL_ControlBase control)
{
Selected = true;
return REDRAW;
}
public override uint SelectDefault(GL_ControlBase control)
{
Selected = true;
return REDRAW;
}
public override uint Select(int partIndex, GL_ControlBase control)
{
Selected = true;
return REDRAW;
}
public override uint Deselect(int partIndex, GL_ControlBase control)
{
Selected = false;
return REDRAW;
}
public override uint DeselectAll(GL_ControlBase control)
{
Selected = false;
return REDRAW;
}
public override Vector3 Position
{
get
{
return position;
}
set
{
position = value;
}
}*/
}
}