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mirror of synced 2024-12-12 07:41:11 +01:00
Switch-Toolbox/File_Format_Library/GL/BFRES_Render.cs
KillzXGaming 32fb5444e7 Add all the newest changes.
Add support for bayonetta/astral chain dat.
Add support for darc archives.
Support previewing window panes for bflyt (1 frame atm with around kind)
Add bflan reading. Saving needs more testing and will be enabled soon.
Bflyt editor will keep the editor open within an archive when saved.
A custom dialog will be added soon to customize saving parameters.
Bflims will be loaded if in the same folder as the bflyt when opened.
2019-09-10 18:42:48 -04:00

1392 lines
56 KiB
C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Drawing;
using Syroot.NintenTools.NSW.Bfres;
using Syroot.NintenTools.NSW.Bfres.Helpers;
using OpenTK;
using OpenTK.Graphics.OpenGL;
using System.Windows.Forms;
using GL_EditorFramework.GL_Core;
using GL_EditorFramework.Interfaces;
using Toolbox.Library;
using Toolbox.Library.Rendering;
using Toolbox.Library.IO;
using Toolbox.Library.Forms;
using ResU = Syroot.NintenTools.Bfres;
using Bfres.Structs;
using SF = SFGraphics.GLObjects.Shaders;
namespace FirstPlugin
{
public class BFRESRender : AbstractGlDrawable, IMeshContainer
{
private bool Disposing = false;
public Matrix4 ModelTransform = Matrix4.Identity;
Vector3 position = new Vector3(0);
public static Vector4 hoverColor = new Vector4(1);
public static Vector4 selectColor = new Vector4(1);
protected bool Selected = false;
public bool Hovered = false;
public bool IsSelected() => Selected;
// gl buffer objects
int vbo_position;
int ibo_elements;
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;
}
}
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);
}
}
}
public BFRES ResFileNode;
public BFRESRender()
{
}
private 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;
}
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;
}
}
}
#region Rendering
// public ShaderProgram BotwShaderProgram;
// public ShaderProgram normalsShaderProgram;
// public ShaderProgram debugShaderProgram;
// public ShaderProgram pbrShaderProgram;
// public ShaderProgram defaultShaderProgram;
// public ShaderProgram solidColorShaderProgram;
public override void Prepare(GL_ControlModern control)
{
/* string pathFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\BFRES.frag";
string pathVert = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\BFRES.vert";
string pathBotwFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\BFRES_Botw.frag";
string pathPbrFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\BFRES_PBR.frag";
string pathBfresUtiltyFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\BFRES_utility.frag";
string pathBfresTurboShadow = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\BFRESTurboShadow.frag";
string pathUtiltyFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Utility") + "\\Utility.frag";
string pathDebugFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\BFRES_Debug.frag";
string pathNormalsFrag = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\Normals.frag";
string pathNormalsVert = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\Normals.vert";
string pathNormalGeom = System.IO.Path.Combine(Runtime.ExecutableDir, "Shader", "Bfres") + "\\Normals.geom";
var defaultFrag = new FragmentShader(System.IO.File.ReadAllText(pathFrag));
var defaultVert = new VertexShader(System.IO.File.ReadAllText(pathVert));
var BotwtFrag = new FragmentShader(System.IO.File.ReadAllText(pathBotwFrag));
var shadowMapAGL = new FragmentShader(System.IO.File.ReadAllText(pathBfresTurboShadow));
var PbrFrag = new FragmentShader(System.IO.File.ReadAllText(pathPbrFrag));
var debugFrag = new FragmentShader(System.IO.File.ReadAllText(pathDebugFrag));
var normalsVert = new VertexShader(System.IO.File.ReadAllText(pathNormalsVert));
var normalsFrag = new FragmentShader(System.IO.File.ReadAllText(pathNormalsFrag));
var normalsGeom = new GeomertyShader(System.IO.File.ReadAllText(pathNormalGeom));
var bfresUtiltyFrag = new FragmentShader(System.IO.File.ReadAllText(pathBfresUtiltyFrag));
var utiltyFrag = new FragmentShader(System.IO.File.ReadAllText(pathUtiltyFrag));
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;
uniform mat4 mtxMdl;
uniform mat4 mtxCam;
out vec3 normal;
out vec3 color;
out vec3 position;
void main(){
normal = vNormal;
color = vColor;
position = vPosition;
gl_Position = mtxMdl * mtxCam * vec4(vPosition.xyz, 1.0);
}");
defaultShaderProgram = new ShaderProgram(new Shader[] { bfresUtiltyFrag, utiltyFrag, defaultFrag, defaultVert, utiltyFrag, shadowMapAGL });
BotwShaderProgram = new ShaderProgram(new Shader[] { bfresUtiltyFrag, utiltyFrag, BotwtFrag, defaultVert, utiltyFrag, shadowMapAGL });
normalsShaderProgram = new ShaderProgram(new Shader[] { normalsFrag, normalsVert, normalsGeom });
debugShaderProgram = new ShaderProgram(new Shader[] { bfresUtiltyFrag, utiltyFrag, debugFrag, defaultVert, utiltyFrag, shadowMapAGL });
pbrShaderProgram = new ShaderProgram(new Shader[] { bfresUtiltyFrag, utiltyFrag, PbrFrag, defaultVert, shadowMapAGL });
solidColorShaderProgram = new ShaderProgram(solidColorFrag, solidColorVert);*/
}
public override void Prepare(GL_ControlLegacy control)
{
}
public override void Draw(GL_ControlLegacy control, Pass pass)
{
if (Disposing) 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_ControlModern 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) {
DrawBfres(control, pass);
}
/* public override void Draw(GL_ControlModern control, Pass pass, EditorSceneBase editorScene) {
DrawBfres(control, pass);
}*/
private void DrawBfres(GL_ControlModern control, Pass pass)
{
if (!Runtime.OpenTKInitialized || pass == Pass.TRANSPARENT || Disposing)
return;
bool buffersWereInitialized = ibo_elements != 0 && vbo_position != 0;
if (!buffersWereInitialized)
GenerateBuffers();
if (Hovered == true)
throw new Exception("model selected");
//Temporarily revert to using this shader system as it is easy to port back
//This is much quicker. Will change after shaders are handled faster
SF.Shader shader = OpenTKSharedResources.shaders["BFRES"];
if (Runtime.EnablePBR)
shader = OpenTKSharedResources.shaders["BFRES_PBR"];
if (models.Count > 0)
{
if (models[0].shapes.Count > 0)
{
if (models[0].shapes[0].GetFMAT().shaderassign.ShaderModel == "uking_mat")
{
shader = OpenTKSharedResources.shaders["BFRES_Botw"];
//Botw uses small models so lower the bone size
Runtime.bonePointSize = 0.040f;
}
}
}
if (Runtime.viewportShading != Runtime.ViewportShading.Default)
shader = OpenTKSharedResources.shaders["BFRES_Debug"];
if (Runtime.viewportShading == Runtime.ViewportShading.Lighting && Runtime.EnablePBR)
shader = OpenTKSharedResources.shaders["BFRES_PBR"];
shader.UseProgram();
control.UpdateModelMatrix(Matrix4.CreateScale(Runtime.previewScale) * ModelTransform);
Matrix4 camMat = control.CameraMatrix;
Matrix4 mdlMat = control.ModelMatrix;
Matrix4 projMat = control.ProjectionMatrix;
Matrix4 computedCamMtx = camMat * projMat;
Matrix4 mvpMat = control.ModelMatrix * control.CameraMatrix * control.ProjectionMatrix;
Matrix4 sphereMatrix = mvpMat;
Matrix4 invertedCamera = Matrix4.Identity;
// invertedCamera = mvpMat.Inverted();
// if (invertedCamera.Determinant == 0)
// invertedCamera = Matrix4.Identity;
sphereMatrix = invertedCamera;
sphereMatrix.Transpose();
shader.SetMatrix4x4("sphereMatrix", ref sphereMatrix);
shader.SetMatrix4x4("mtxCam", ref computedCamMtx);
shader.SetMatrix4x4("mtxMdl", ref mdlMat);
shader.SetVector3("cameraPosition", control.CameraPosition);
SetRenderSettings(shader);
Vector4 pickingColor = control.NextPickingColor();
shader.SetVector3("difLightColor", new Vector3(1));
shader.SetVector3("ambLightColor", new Vector3(1));
Vector3 lightDirection = new Vector3(0f, 0f, -1f);
GL.Enable(EnableCap.AlphaTest);
GL.AlphaFunc(AlphaFunction.Gequal, 0.1f);
DrawModels(shader, control);
if (Runtime.renderNormalsPoints)
{
shader = OpenTKSharedResources.shaders["BFRES_Normals"];
shader.UseProgram();
shader.SetMatrix4x4("camMtx", ref camMat);
shader.SetMatrix4x4("mtxProj", ref projMat);
shader.SetMatrix4x4("mtxCam", ref computedCamMtx);
shader.SetMatrix4x4("mtxMdl", ref mdlMat);
shader.SetFloat("normalsLength", Runtime.normalsLineLength);
DrawModels(shader, control);
}
GL.UseProgram(0);
GL.Disable(EnableCap.DepthTest);
GL.Enable(EnableCap.DepthTest);
GL.Enable(EnableCap.CullFace);
}
private void DrawModels(SF.Shader shader, GL_ControlModern control)
{
shader.EnableVertexAttributes();
for (int m = 0; m < models.Count; m++)
{
if (models[m].Checked)
{
List<FSHP> opaque = new List<FSHP>();
List<FSHP> transparent = new List<FSHP>();
for (int shp = 0; shp < models[m].shapes.Count; shp++)
{
if (models[m].shapes[shp].GetFMAT().isTransparent)
transparent.Add(models[m].shapes[shp]);
else
opaque.Add(models[m].shapes[shp]);
}
for (int shp = 0; shp < transparent.Count; shp++)
{
DrawModel(transparent[shp], models[m], shader, models[m].IsSelected);
}
for (int shp = 0; shp < opaque.Count; shp++)
{
DrawModel(opaque[shp], models[m], shader, models[m].IsSelected);
}
}
}
shader.DisableVertexAttributes();
}
public void DepthSortMeshes(Vector3 cameraPosition)
{
foreach (FMDL fmdl in models)
{
List<FSHP> unsortedMeshes = new List<FSHP>();
foreach (FSHP m in fmdl.shapes)
{
m.sortingDistance = m.CalculateSortingDistance(cameraPosition);
unsortedMeshes.Add(m);
}
fmdl.depthSortedMeshes = unsortedMeshes.OrderBy(o => (o.sortingDistance)).ToList();
}
// Order by the distance from the camera to the closest point on the bounding sphere.
// Positive values are usually closer to camera. Negative values are usually farther away.
}
private void SetRenderSettings(SF.Shader shader)
{
shader.SetBoolToInt("renderVertColor", Runtime.renderVertColor);
shader.SetBoolToInt("useNormalMap", Runtime.useNormalMap);
shader.SetBoolToInt("renderR", Runtime.renderR);
shader.SetBoolToInt("renderG", Runtime.renderG);
shader.SetBoolToInt("renderB", Runtime.renderB);
shader.SetBoolToInt("renderAlpha", Runtime.renderAlpha);
shader.SetInt("renderType", (int)Runtime.viewportShading);
shader.SetInt("uvChannel", (int)Runtime.uvChannel);
shader.SetBoolToInt("renderFog", Runtime.renderFog);
shader.SetBoolToInt("renderDiffuse", Runtime.renderDiffuse);
shader.SetBoolToInt("renderSpecular", Runtime.renderSpecular);
shader.SetBoolToInt("renderFresnel", Runtime.renderFresnel);
}
private static void SetDefaultTextureAttributes(FMAT mat, SF.Shader shader)
{
shader.SetBoolToInt("HasDiffuse", mat.HasDiffuseMap);
shader.SetBoolToInt("HasDiffuseLayer", mat.HasDiffuseLayer);
shader.SetBoolToInt("HasNormalMap", mat.HasNormalMap);
shader.SetBoolToInt("HasEmissionMap", mat.HasEmissionMap);
shader.SetBoolToInt("HasLightMap", mat.HasLightMap);
shader.SetBoolToInt("HasShadowMap", mat.HasShadowMap);
shader.SetBoolToInt("HasSpecularMap", mat.HasSpecularMap);
shader.SetBoolToInt("HasTeamColorMap", mat.HasTeamColorMap);
shader.SetBoolToInt("HasSphereMap", mat.HasSphereMap);
shader.SetBoolToInt("HasSubSurfaceScatteringMap", mat.HasSubSurfaceScatteringMap);
//Unused atm untill I do PBR shader
shader.SetBoolToInt("HasMetalnessMap", mat.HasMetalnessMap);
shader.SetBoolToInt("HasRoughnessMap", mat.HasRoughnessMap);
shader.SetBoolToInt("HasMRA", mat.HasMRA);
}
private static void SetBoneUniforms(SF.Shader shader, FMDL fmdl, FSHP fshp)
{
for (int i = 0; i < fmdl.Skeleton.Node_Array.Length; i++)
{
GL.Uniform1(GL.GetUniformLocation(shader.Id, String.Format("boneIds[{0}]", i)), fmdl.Skeleton.Node_Array[i]);
Matrix4 transform = fmdl.Skeleton.bones[fmdl.Skeleton.Node_Array[i]].invert * fmdl.Skeleton.bones[fmdl.Skeleton.Node_Array[i]].Transform;
GL.UniformMatrix4(GL.GetUniformLocation(shader.Id, String.Format("bones[{0}]", i)), false, ref transform);
}
}
private static void SetTextureUniforms(FMAT mat, FSHP m, SF.Shader shader)
{
GL.ActiveTexture(TextureUnit.Texture0 + 1);
GL.BindTexture(TextureTarget.Texture2D, RenderTools.defaultTex.RenderableTex.TexID);
GL.ActiveTexture(TextureUnit.Texture11);
GL.Uniform1(shader.GetUniformLocation("weightRamp1"), 11);
GL.BindTexture(TextureTarget.Texture2D, RenderTools.BoneWeightGradient.Id);
GL.ActiveTexture(TextureUnit.Texture12);
GL.Uniform1(shader.GetUniformLocation("weightRamp2"), 12);
GL.BindTexture(TextureTarget.Texture2D, RenderTools.BoneWeightGradient2.Id);
GL.Uniform1(shader.GetUniformLocation("debugOption"), 2);
GL.ActiveTexture(TextureUnit.Texture10);
GL.Uniform1(shader.GetUniformLocation("UVTestPattern"), 10);
GL.BindTexture(TextureTarget.Texture2D, RenderTools.uvTestPattern.RenderableTex.TexID);
GL.Uniform1(shader.GetUniformLocation("normalMap"), 0);
GL.Uniform1(shader.GetUniformLocation("BakeShadowMap"), 0);
shader.SetInt("RedChannel", 0);
shader.SetInt("GreenChannel", 1);
shader.SetInt("BlueChannel", 2);
shader.SetInt("AlphaChannel", 3);
LoadPBRMaps(shader);
for (int t = 0; t < mat.TextureMaps.Count; t++)
{
MatTexture matex = (MatTexture)mat.TextureMaps[t];
if (matex.Type == MatTexture.TextureType.Diffuse)
mat.HasDiffuseMap = TextureUniform(shader, mat, "DiffuseMap", matex);
else if (matex.Type == MatTexture.TextureType.Normal)
mat.HasNormalMap = TextureUniform(shader, mat, "NormalMap", matex);
else if (matex.Type == MatTexture.TextureType.Emission)
mat.HasEmissionMap = TextureUniform(shader, mat, "EmissionMap", matex);
else if (matex.Type == MatTexture.TextureType.Specular)
mat.HasSpecularMap = TextureUniform(shader, mat, "SpecularMap", matex);
else if (matex.Type == MatTexture.TextureType.Shadow)
mat.HasShadowMap = TextureUniform(shader, mat, "BakeShadowMap", matex);
else if (matex.Type == MatTexture.TextureType.Light)
mat.HasLightMap = TextureUniform(shader, mat, "BakeLightMap", matex);
else if (matex.Type == MatTexture.TextureType.Metalness)
mat.HasMetalnessMap = TextureUniform(shader, mat, "MetalnessMap", matex);
else if (matex.Type == MatTexture.TextureType.Roughness)
mat.HasRoughnessMap = TextureUniform(shader, mat, "RoughnessMap", matex);
else if (matex.Type == MatTexture.TextureType.TeamColor)
mat.HasTeamColorMap = TextureUniform(shader, mat, "TeamColorMap", matex);
else if (matex.Type == MatTexture.TextureType.Transparency)
mat.HasTransparencyMap = TextureUniform(shader, mat, "TransparencyMap", matex);
else if (matex.Type == MatTexture.TextureType.DiffuseLayer2)
mat.HasDiffuseLayer = TextureUniform(shader, mat, "DiffuseLayer", matex);
else if (matex.Type == MatTexture.TextureType.SphereMap)
mat.HasSphereMap = mat.HasSphereMap = TextureUniform(shader, mat, "SphereMap", matex);
else if (matex.Type == MatTexture.TextureType.SubSurfaceScattering)
mat.HasSubSurfaceScatteringMap = TextureUniform(shader, mat, "SubSurfaceScatteringMap", matex);
else if (matex.Type == MatTexture.TextureType.MRA)
mat.HasMRA = TextureUniform(shader, mat, "MRA", matex);
}
SetDefaultTextureAttributes(mat, shader);
}
private static void LoadPBRMaps(SF.Shader shader)
{
GL.ActiveTexture(TextureUnit.Texture0 + 26);
RenderTools.specularPbr.Bind();
GL.Uniform1(shader.GetUniformLocation("specularIbl"), 26);
// GL.GenerateMipmap(GenerateMipmapTarget.TextureCubeMap);
// PBR IBL
GL.ActiveTexture(TextureUnit.Texture0 + 25);
RenderTools.diffusePbr.Bind();
GL.Uniform1(shader.GetUniformLocation("irradianceMap"), 25);
GL.ActiveTexture(TextureUnit.Texture0 + 27);
RenderTools.brdfPbr.Bind();
GL.Uniform1(shader.GetUniformLocation("brdfLUT"), 27);
}
private static bool TextureUniform(SF.Shader shader, FMAT mat, string name, MatTexture mattex)
{
if (mattex.textureState == STGenericMatTexture.TextureState.Binded)
return true;
// Bind the texture and create the uniform if the material has the right textures.
bool IsBound = BindTexture(mattex, mat, shader, mat.GetResFileU() != null);
int texId = mattex.textureUnit + 1;
if (IsBound)
GL.Uniform1(shader.GetUniformLocation(name), texId);
else
return false;
return true;
}
public static bool BindTexture(MatTexture tex, FMAT material, SF.Shader shader, bool IsWiiU)
{
BFRES bfres = (BFRES)material.Parent.Parent.Parent.Parent;
GL.ActiveTexture(TextureUnit.Texture0 + tex.textureUnit + 1);
GL.BindTexture(TextureTarget.Texture2D, RenderTools.defaultTex.RenderableTex.TexID);
string activeTex = tex.Name;
if (tex.animatedTexName != "")
activeTex = tex.animatedTexName;
if (IsWiiU)
{
if (bfres.HasTextures)
{
var ftexCont = bfres.GetFTEXContainer;
if (ftexCont != null)
{
if (ftexCont.ResourceNodes.ContainsKey(activeTex))
{
return BindFTEX(ftexCont, tex, shader, activeTex);
}
}
}
foreach (var ftexContainer in PluginRuntime.ftexContainers)
{
if (ftexContainer.ResourceNodes.ContainsKey(activeTex))
{
return BindFTEX(ftexContainer, tex, shader, activeTex);
}
}
}
else
{
if (bfres.HasTextures)
{
var bntx = bfres.GetBNTX;
if (bntx != null)
{
if (bntx.Textures.ContainsKey(activeTex))
{
return BindBNTX(bntx, tex, shader, activeTex);
}
}
}
foreach (var bntx in PluginRuntime.bntxContainers)
{
if (bntx.Textures.ContainsKey(activeTex))
{
return BindBNTX(bntx, tex, shader, activeTex);
}
}
}
return true;
}
private static bool BindFTEX(BFRESGroupNode ftexContainer, MatTexture tex, SF.Shader shader, string activeTex)
{
FTEX ftex = (FTEX)ftexContainer.ResourceNodes[activeTex];
if (ftex.RenderableTex == null || !ftex.RenderableTex.GLInitialized)
ftex.LoadOpenGLTexture();
BindGLTexture(tex, shader, ftex);
return ftex.RenderableTex.GLInitialized;
}
private static bool BindBNTX(BNTX bntx, MatTexture tex, SF.Shader shader, string activeTex)
{
if (bntx.Textures[activeTex].RenderableTex == null ||
!bntx.Textures[activeTex].RenderableTex.GLInitialized)
{
bntx.Textures[activeTex].LoadOpenGLTexture();
}
BindGLTexture(tex, shader, bntx.Textures[activeTex]);
return bntx.Textures[activeTex].RenderableTex.GLInitialized;
}
private static void BindGLTexture(MatTexture tex, SF.Shader shader, STGenericTexture texture)
{
//If the texture is still not initialized then return
if (!texture.RenderableTex.GLInitialized)
return;
if (tex.Type == STGenericMatTexture.TextureType.Diffuse)
{
shader.SetInt("RedChannel", (int)texture.RedChannel);
shader.SetInt("GreenChannel", (int)texture.GreenChannel);
shader.SetInt("BlueChannel", (int)texture.BlueChannel);
shader.SetInt("AlphaChannel", (int)texture.AlphaChannel);
}
// GL.ActiveTexture(TextureUnit.Texture0 + texid);
GL.BindTexture(TextureTarget.Texture2D, texture.RenderableTex.TexID);
GL.TexParameter(TextureTarget.Texture2D, TextureParameterName.TextureWrapS, (int)MatTexture.wrapmode[tex.WrapModeS]);
GL.TexParameter(TextureTarget.Texture2D, TextureParameterName.TextureWrapT, (int)MatTexture.wrapmode[tex.WrapModeT]);
GL.TexParameter(TextureTarget.Texture2D, TextureParameterName.TextureMinFilter, (int)MatTexture.minfilter[tex.MinFilter]);
GL.TexParameter(TextureTarget.Texture2D, TextureParameterName.TextureMagFilter, (int)MatTexture.magfilter[tex.MagFilter]);
GL.TexParameter(TextureTarget.Texture2D, (TextureParameterName)ExtTextureFilterAnisotropic.TextureMaxAnisotropyExt, 0.0f);
}
private void DrawModel(FSHP m, FMDL mdl, SF.Shader shader, bool ModelSelected)
{
if (m.lodMeshes[m.DisplayLODIndex].faces.Count <= 3)
return;
var mat = m.GetFMAT();
if (shader != OpenTKSharedResources.shaders["BFRES_Normals"])
{
SetRenderPass(mat);
SetUniforms(mat, shader, m, m.DisplayId);
SetTextureUniforms(mat, m, shader);
}
SetBoneUniforms(shader, mdl, m);
ApplyTransformFix(mdl, m, shader);
SetVertexAttributes(m, shader);
//Check the binded bone if it's visible from bone visual anims
// if (!mdl.Skeleton.bones[m.boneIndx].Visible)
// m.Checked = false;
if (m.Checked && mdl.Skeleton.bones.Count > 0 && mdl.Skeleton.bones[m.BoneIndex].Visible && mat.Enabled)
{
shader.SetVector3("materialSelectColor", new Vector3(0));
if (m.GetMaterial().IsSelected)
{
shader.SetVector3("materialSelectColor", ColorUtility.ToVector3(Color.FromArgb(0,163,204)));
DrawModelSelection(m, shader);
}
else if (m.IsSelected || ModelSelected)
{
DrawModelSelection(m, shader);
}
else
{
if (Runtime.RenderModelWireframe)
{
DrawModelWireframe(m, shader);
}
if (Runtime.RenderModels)
{
DrawMdoelHoverSelection(m, shader, IsSelected(), Hovered);
PrimitiveType primitiveType = PrimitiveType.Triangles;
switch (m.lodMeshes[m.DisplayLODIndex].PrimitiveType)
{
case STPolygonType.Line:
primitiveType = PrimitiveType.Lines;
break;
case STPolygonType.LineStrip:
primitiveType = PrimitiveType.LineStrip;
break;
case STPolygonType.Point:
primitiveType = PrimitiveType.Points;
break;
case STPolygonType.Triangle:
primitiveType = PrimitiveType.Triangles;
break;
}
GL.DrawElements(primitiveType, m.lodMeshes[m.DisplayLODIndex].displayFaceSize, DrawElementsType.UnsignedInt, m.Offset);
}
}
}
}
private static void ApplyTransformFix(FMDL fmdl, FSHP m, SF.Shader shader)
{
Matrix4 idenity = Matrix4.Identity;
shader.SetInt("NoSkinning", 0);
shader.SetInt("RigidSkinning", 0);
shader.SetInt("SingleBoneIndex", m.BoneIndex);
shader.SetMatrix4x4("SingleBoneBindTransform", ref idenity);
//Some objects will have no weights or indices. These will weigh to the bone index in the shape section.
if (m.VertexSkinCount == 1)
{
shader.SetInt("RigidSkinning", 1);
}
if (m.VertexSkinCount == 0)
{
if (fmdl.Skeleton.bones.Count > 0)
{
Matrix4 transform = fmdl.Skeleton.bones[m.BoneIndex].invert * fmdl.Skeleton.bones[m.BoneIndex].Transform;
shader.SetMatrix4x4("SingleBoneBindTransform", ref transform);
shader.SetInt("NoSkinning", 1);
}
}
}
static bool Loaded = false;
public void UpdateVertexData()
{
if (!Runtime.OpenTKInitialized)
return;
UpdateModelList();
Loaded = false;
DisplayVertex[] Vertices;
int[] Faces;
int poffset = 0;
int voffset = 0;
List<DisplayVertex> Vs = new List<DisplayVertex>();
List<int> Ds = new List<int>();
int TotalShapeCount = models.Sum(b => b.shapes.Count);
int value = 0;
for (int m = 0; m < models.Count; m++)
{
//Reset min/max
models[m].MaxPosition = new Vector3(0);
models[m].MinPosition = new Vector3(0);
for (int shp = 0; shp < models[m].shapes.Count; shp++)
{
//Update render pass aswell
CheckRenderPass(models[m].shapes[shp].GetFMAT());
models[m].shapes[shp].Offset = poffset * 4;
List<DisplayVertex> pv = models[m].shapes[shp].CreateDisplayVertices(models[m]);
Vs.AddRange(pv);
for (int i = 0; i < models[m].shapes[shp].lodMeshes[models[m].shapes[shp].DisplayLODIndex].displayFaceSize; i++)
{
Ds.Add(models[m].shapes[shp].display[i] + voffset);
}
poffset += models[m].shapes[shp].lodMeshes[models[m].shapes[shp].DisplayLODIndex].displayFaceSize;
voffset += pv.Count;
}
}
// Binds
Vertices = Vs.ToArray();
Faces = Ds.ToArray();
// Bind only once!
GL.BindBuffer(BufferTarget.ArrayBuffer, vbo_position);
GL.BufferData<DisplayVertex>(BufferTarget.ArrayBuffer, (IntPtr)(Vertices.Length * 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();
Loaded = true;
}
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 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();
}
}
}
private static void SetRenderPass(FMAT mat)
{
bool NoCull = false;
bool CullBack = false;
bool CullFront = false;
for (int i = 0; i < mat.renderinfo.Count; i++)
{
if (mat.renderinfo[i].Name == "display_face")
{
NoCull = mat.renderinfo[i].ValueString.Contains("both");
CullFront = mat.renderinfo[i].ValueString.Contains("back");
CullBack = mat.renderinfo[i].ValueString.Contains("front");
}
if (mat.shaderassign.ShaderArchive == "Turbo_UBER")
{
AglShaderTurbo aglShader = new AglShaderTurbo();
aglShader.LoadRenderInfo(mat.renderinfo[i]);
}
}
if (NoCull)
{
GL.Disable(EnableCap.CullFace);
}
else if (CullFront)
{
GL.Enable(EnableCap.CullFace);
GL.CullFace(CullFaceMode.Front);
}
else if (CullBack)
{
GL.Enable(EnableCap.CullFace);
GL.CullFace(CullFaceMode.Back);
}
}
private static void CheckRenderPass(FMAT mat)
{
if (mat.ImageKey != "material")
{
mat.ImageKey = "material";
mat.SelectedImageKey = "material";
}
bool IsTranslucent = false;
bool IsTransparentMask = false;
for (int i = 0; i < mat.renderinfo.Count; i++)
{
if (mat.renderinfo[i].Name == "gsys_render_state_mode")
{
IsTranslucent = mat.renderinfo[i].ValueString.Contains("translucent");
IsTransparentMask = mat.renderinfo[i].ValueString.Contains("mask");
}
if (mat.renderinfo[i].Name == "renderPass")
{
IsTransparentMask = mat.renderinfo[i].ValueString.Contains("xlu");
}
}
if (mat.shaderassign.options.ContainsKey("enable_translucent"))
IsTranslucent = mat.shaderassign.options["enable_translucent"] == "1";
if (mat.shaderassign.options.ContainsKey("enable_translucent"))
IsTransparentMask = mat.shaderassign.options["enable_transparent"] == "1";
if (mat.MaterialU != null)
{
IsTranslucent = mat.MaterialU.RenderState.FlagsMode == ResU.RenderStateFlagsMode.Translucent;
IsTransparentMask = mat.MaterialU.RenderState.FlagsMode == ResU.RenderStateFlagsMode.AlphaMask;
}
mat.isTransparent = IsTransparentMask || IsTranslucent;
SetMaterialIcon(mat, IsTranslucent, "MaterialTranslucent");
SetMaterialIcon(mat, IsTransparentMask, "MaterialTransparent");
}
private static void SetMaterialIcon(FMAT mat, bool IsEffect, string Key)
{
if (IsEffect)
{
mat.ImageKey = Key;
mat.SelectedImageKey = Key;
}
}
private static void SetUniforms(FMAT mat, SF.Shader shader, FSHP m, int id)
{
shader.SetBoolToInt("isTransparent", mat.isTransparent);
shader.SetFloat("ao_density", 1);
shader.SetFloat("shadow_density", 1);
shader.SetFloat("normal_map_weight", 1);
//Bake map UV coordinate ST
shader.SetVector4("gsys_bake_st0", new Vector4(1, 1, 0, 0));
shader.SetVector4("gsys_bake_st1", new Vector4(1, 1, 0, 0));
shader.SetBoolToInt("UseSpecularColor",
(mat.GetOptionValue("specular_mask_is_color") == 1) ||
mat.GetOptionValue("enable_specular_color") == 1);
shader.SetBoolToInt("UseMultiTexture", mat.GetOptionValue("enable_multi_texture") == 1);
//Colors
shader.SetVector4("const_color0", new Vector4(1, 1, 1, 1));
shader.SetVector4("base_color_mul_color", new Vector4(1, 1, 1, 1));
shader.SetVector3("albedo_tex_color", new Vector3(1, 1, 1));
shader.SetVector3("emission_color", new Vector3(1, 1, 1));
shader.SetVector3("specular_color", new Vector3(1, 1, 1));
shader.SetFloat("fuv1_mtx", 0);
//SRT
shader.SetVector4("tex_mtx0", new Vector4(1, 1, 1, 1));
shader.SetVector2("SRT_Scale", new Vector2(1, 1));
shader.SetFloat("SRT_Rotate", 0);
shader.SetVector2("SRT_Translate", new Vector2(0, 0));
shader.SetInt("selectedBoneIndex", Runtime.SelectedBoneIndex);
SetUniformData(mat, shader, "base_color_mul_color");
shader.SetInt("enableCellShading", 0);
bool HasTans = m.vertexAttributes.Any(x => x.Name == "_t0");
shader.SetBoolToInt("hasTangents", HasTans);
SetUniformData(mat, shader, "fuv1_mtx");
SetUniformData(mat, shader, "gsys_bake_st0");
SetUniformData(mat, shader, "gsys_bake_st1");
SetUniformData(mat, shader, "ao_density");
SetUniformData(mat, shader, "shadow_density");
SetUniformData(mat, shader, "normal_map_weight");
SetUniformData(mat, shader, "const_color0");
SetUniformData(mat, shader, "base_color_mul_color");
SetUniformData(mat, shader, "albedo_tex_color");
SetUniformData(mat, shader, "emission_color");
SetUniformData(mat, shader, "specular_color");
//This uniform sets various maps for BOTW to use second UV channel
SetUniformData(mat, shader, "uking_texture2_texcoord");
SetUniformData(mat, shader, "cIsEnableNormalMap");
SetUniformData(mat, shader, "tex_mtx0");
//Sets shadow type
//0 = Ambient occusion bake map
//1 = Shadow
//2 = Shadow + Ambient occusion map
SetUniformData(mat, shader, "bake_shadow_type");
SetUniformData(mat, shader, "bake_light_type");
SetUniformData(mat, shader, "gsys_bake_light_scale");
SetUniformData(mat, shader, "enable_projection_light");
SetUniformData(mat, shader, "enable_actor_light");
SetUniformData(mat, shader, "bake_calc_type");
}
private static void SetUniformData(FMAT mat, SF.Shader shader, string propertyName)
{
if (mat.shaderassign.options.ContainsKey(propertyName))
{
float value = float.Parse(mat.shaderassign.options[propertyName]);
shader.SetFloat(propertyName, value);
}
if (mat.matparam.ContainsKey(propertyName))
{
if (mat.matparam[propertyName].Type == ShaderParamType.Float)
{
if (mat.anims.ContainsKey(propertyName))
mat.matparam[propertyName].ValueFloat[0] = mat.anims[propertyName][0];
shader.SetFloat(propertyName, mat.matparam[propertyName].ValueFloat[0]);
}
if (mat.matparam[propertyName].Type == ShaderParamType.Float2)
{
if (mat.anims.ContainsKey(propertyName))
{
mat.matparam[propertyName].ValueFloat = new float[2] {
mat.anims[propertyName][0], mat.anims[propertyName][1]};
}
shader.SetVector2(propertyName, Utils.ToVec2(mat.matparam[propertyName].ValueFloat));
}
if (mat.matparam[propertyName].Type == ShaderParamType.Float3)
{
if (mat.anims.ContainsKey(propertyName))
{
mat.matparam[propertyName].ValueFloat = new float[3] {
mat.anims[propertyName][0],
mat.anims[propertyName][1],
mat.anims[propertyName][2]};
}
shader.SetVector3(propertyName, Utils.ToVec3(mat.matparam[propertyName].ValueFloat));
}
if (mat.matparam[propertyName].Type == ShaderParamType.Float4)
{
if (mat.anims.ContainsKey(propertyName))
{
mat.matparam[propertyName].ValueFloat = new float[4] {
mat.anims[propertyName][0], mat.anims[propertyName][1],
mat.anims[propertyName][2], mat.anims[propertyName][3]};
}
shader.SetVector4(propertyName, Utils.ToVec4(mat.matparam[propertyName].ValueFloat));
}
if (mat.matparam[propertyName].Type == ShaderParamType.TexSrt)
{
// Vector 2 Scale
// 1 roation float
// Vector2 translate
TexSrt texSRT = mat.matparam[propertyName].ValueTexSrt;
shader.SetVector2("SRT_Scale", Utils.ToVec2(texSRT.Scaling));
shader.SetFloat("SRT_Rotate", texSRT.Rotation);
shader.SetVector2("SRT_Translate", Utils.ToVec2(texSRT.Translation));
}
}
if (mat.animatedMatParams.ContainsKey(propertyName))
{
if (mat.animatedMatParams[propertyName].Type == ShaderParamType.Float)
{
if (mat.anims.ContainsKey(propertyName))
mat.animatedMatParams[propertyName].ValueFloat[0] = mat.anims[propertyName][0];
shader.SetFloat(propertyName, mat.animatedMatParams[propertyName].ValueFloat[0]);
}
if (mat.animatedMatParams[propertyName].Type == ShaderParamType.Float2)
{
if (mat.anims.ContainsKey(propertyName))
{
mat.animatedMatParams[propertyName].ValueFloat = new float[2] {
mat.anims[propertyName][0], mat.anims[propertyName][1]};
}
shader.SetVector2(propertyName, Utils.ToVec2(mat.animatedMatParams[propertyName].ValueFloat));
}
if (mat.animatedMatParams[propertyName].Type == ShaderParamType.Float3)
{
Console.WriteLine(propertyName + " " + mat.animatedMatParams[propertyName].ValueFloat);
if (mat.anims.ContainsKey(propertyName))
{
mat.animatedMatParams[propertyName].ValueFloat = new float[3] {
mat.anims[propertyName][0],
mat.anims[propertyName][1],
mat.anims[propertyName][2]};
}
shader.SetVector3(propertyName, Utils.ToVec3(mat.animatedMatParams[propertyName].ValueFloat));
}
if (mat.animatedMatParams[propertyName].Type == ShaderParamType.Float4)
{
if (mat.anims.ContainsKey(propertyName))
{
mat.animatedMatParams[propertyName].ValueFloat = new float[4] {
mat.anims[propertyName][0], mat.anims[propertyName][1],
mat.anims[propertyName][2], mat.anims[propertyName][3]};
}
shader.SetVector4(propertyName, Utils.ToVec4(mat.animatedMatParams[propertyName].ValueFloat));
}
if (mat.animatedMatParams[propertyName].Type == ShaderParamType.TexSrt)
{
// Vector 2 Scale
// 1 roation float
// Vector2 translate
TexSrt texSRT = mat.animatedMatParams[propertyName].ValueTexSrt;
shader.SetVector2("SRT_Scale", Utils.ToVec2(texSRT.Scaling));
shader.SetFloat("SRT_Rotate", texSRT.Rotation);
shader.SetVector2("SRT_Translate", Utils.ToVec2(texSRT.Translation));
}
}
}
private void SetVertexAttributes(FSHP m, SF.Shader shader)
{
GL.BindBuffer(BufferTarget.ArrayBuffer, vbo_position);
GL.VertexAttribPointer(shader.GetAttribLocation("vPosition"), 3, VertexAttribPointerType.Float, false, DisplayVertex.Size, 0);
GL.VertexAttribPointer(shader.GetAttribLocation("vNormal"), 3, VertexAttribPointerType.Float, false, DisplayVertex.Size, 12);
GL.VertexAttribPointer(shader.GetAttribLocation("vTangent"), 3, VertexAttribPointerType.Float, false, DisplayVertex.Size, 24);
GL.VertexAttribPointer(shader.GetAttribLocation("vBitangent"), 3, VertexAttribPointerType.Float, false, DisplayVertex.Size, 36);
GL.VertexAttribPointer(shader.GetAttribLocation("vUV0"), 2, VertexAttribPointerType.Float, false, DisplayVertex.Size, 48);
GL.VertexAttribPointer(shader.GetAttribLocation("vColor"), 4, VertexAttribPointerType.Float, false, DisplayVertex.Size, 56);
GL.VertexAttribIPointer(shader.GetAttribLocation("vBone"), 4, VertexAttribIntegerType.Int, DisplayVertex.Size, new IntPtr(72));
GL.VertexAttribPointer(shader.GetAttribLocation("vWeight"), 4, VertexAttribPointerType.Float, false, DisplayVertex.Size, 88);
GL.VertexAttribPointer(shader.GetAttribLocation("vUV1"), 2, VertexAttribPointerType.Float, false, DisplayVertex.Size, 104);
GL.VertexAttribPointer(shader.GetAttribLocation("vUV2"), 2, VertexAttribPointerType.Float, false, DisplayVertex.Size, 112);
GL.VertexAttribPointer(shader.GetAttribLocation("vPosition2"), 3, VertexAttribPointerType.Float, false, DisplayVertex.Size, 124);
GL.VertexAttribPointer(shader.GetAttribLocation("vPosition3"), 3, VertexAttribPointerType.Float, false, DisplayVertex.Size, 136);
GL.BindBuffer(BufferTarget.ElementArrayBuffer, ibo_elements);
}
private static void DrawMdoelHoverSelection(STGenericObject p, SF.Shader shader,
bool IsSelected, bool IsHovered)
{
if (IsHovered && IsSelected)
shader.SetVector4("pickingColor", hoverColor);
else if (IsHovered || IsSelected)
shader.SetVector4("pickingColor", selectColor);
else
shader.SetVector4("pickingColor", new Vector4(1));
}
private static void DrawModelWireframe(STGenericObject p, SF.Shader shader)
{
// use vertex color for wireframe color
shader.SetInt("colorOverride", 1);
GL.PolygonMode(MaterialFace.Front, PolygonMode.Line);
GL.Enable(EnableCap.LineSmooth);
GL.LineWidth(1.5f);
GL.DrawElements(PrimitiveType.Triangles, p.lodMeshes[p.DisplayLODIndex].displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
GL.PolygonMode(MaterialFace.FrontAndBack, PolygonMode.Fill);
shader.SetInt("colorOverride", 0);
}
private static void DrawModelSelection(STGenericObject p, SF.Shader shader)
{
//This part needs to be reworked for proper outline. Currently would make model disappear
/* GL.Enable(EnableCap.DepthTest);
GL.StencilOp(StencilOp.Keep, StencilOp.Keep, StencilOp.Replace);
GL.Clear(ClearBufferMask.ColorBufferBit | ClearBufferMask.DepthBufferBit | ClearBufferMask.StencilBufferBit);
GL.StencilMask(0x00);
GL.StencilFunc(StencilFunction.Always, 1, 0xFF); // all fragments should update the stencil buffer
GL.StencilMask(0xFF); // enable writing to the stencil buffer
GL.DrawElements(PrimitiveType.Triangles, p.lodMeshes[p.DisplayLODIndex].displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
GL.StencilFunc(StencilFunction.Notequal, 1, 0xFF);
GL.StencilMask(0x00); // enable writing to the stencil buffer
GL.Disable(EnableCap.DepthTest);
shader.SetInt("colorOverride", 1);
GL.PolygonMode(MaterialFace.Front, PolygonMode.Line);
GL.LineWidth(2.0f);
GL.DrawElements(PrimitiveType.Triangles, p.lodMeshes[p.DisplayLODIndex].displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
GL.PolygonMode(MaterialFace.FrontAndBack, PolygonMode.Fill);
shader.SetInt("colorOverride", 0);
GL.StencilMask(0xFF);
GL.Enable(EnableCap.DepthTest);*/
// Override the model color with white in the shader.
shader.SetInt("colorOverride", 1);
GL.PolygonMode(MaterialFace.Front, PolygonMode.Line);
GL.Enable(EnableCap.LineSmooth);
GL.LineWidth(1.3f);
GL.DrawElements(PrimitiveType.Triangles, p.lodMeshes[p.DisplayLODIndex].displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
GL.PolygonMode(MaterialFace.FrontAndBack, PolygonMode.Fill);
shader.SetInt("colorOverride", 0);
GL.DrawElements(PrimitiveType.Triangles, p.lodMeshes[p.DisplayLODIndex].displayFaceSize, DrawElementsType.UnsignedInt, p.Offset);
}
/* public override BoundingBox GetSelectionBox()
{
Vector3 Min = new Vector3(0);
Vector3 Max = new Vector3(0);
foreach (var model in models)
{
foreach (var shape in model.shapes)
{
foreach (var vertex in shape.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 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 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 DeselectAll(GL_ControlBase control)
{
Selected = false;
return REDRAW;
}
public override Vector3 Position
{
get
{
return position;
}
set
{
position = value;
}
}*/
#endregion
}
}