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rlgl rewrite, meshes not showing up correctly yet

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Jip 2024-05-06 07:24:32 +02:00
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library/rlgldemo/main.cpp Normal file
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/*
libvitaboy - Open source Openrl TSO character animation library
Renderer.cpp - Copyright (c) 2012 Niotso Project <http://niotso.org/>
Author(s): Fatbag <X-Fi6@phppoll.org>
Permission to use, copy, modify, and/or distribute this software for any
purpose with or without fee is hereby granted, provided that the above
copyright notice and this permission notice appear in all copies.
THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
ACTION OF CONTRACT, NErlIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include "raylib.h"
#include "raymath.h" // Required for: Vector3, Quaternion and Matrix functionality
#include "utils.h" // Required for: TRACELOG(), LoadFileData(), LoadFileText(), SaveFileText()
#include "rlgl.h"
#include <cassert>
#include <FileHandler.h>
#include "../libvitaboy/libvitaboy.hpp"
#define SCREEN_WIDTH (800)
#define SCREEN_HEIGHT (600)
#define WINDOW_TITLE "libvitaboy - Renderer - Ray"
struct BasicVertex_t {
float x, y, z;
};
struct CharacterPlacement_t {
BasicVertex_t Translation;
BasicVertex_t Rotation;
};
static CharacterPlacement_t Character = {{0,-3,0}, {0,0,0}};
static Skeleton_t Skeleton;
static Animation_t Animation;
static float AnimationTime = 0;
static void DisplayFileError(const char * Filename){
const char * Message;
switch(File::Error){
case FERR_NOT_FOUND:
Message = "%s does not exist.";
break;
case FERR_OPEN:
Message = "%s could not be opened for reading.";
break;
case FERR_BLANK:
case FERR_UNRECOGNIZED:
case FERR_INVALIDDATA:
Message = "%s is corrupt or invalid.";
break;
case FERR_MEMORY:
Message = "Memory for %s could not be allocated.";
break;
default:
Message = "%s could not be read.";
break;
}
char Buffer[1024];
sprintf(Buffer, Message, Filename);
}
static bool Read(const char* Filename, uint8_t** InData) {
*InData = File::ReadFile(Filename);
if (*InData != NULL) {
VBFile.set(*InData, File::FileSize);
return true;
}
DisplayFileError(Filename);
return false;
}
//textures
static Texture2D textures[3];
enum { Texture_Body, Texture_Head, Texture_Hand };
static const char* const TexturePaths[] = { "body.jpg", "head.jpg", "hand.jpg" };
static bool LoadTextures()
{
for (int i = 0; i < 3; i++)
{
textures[i] = LoadTexture(TexturePaths[i]);
}
return true;
}
static bool UnloadTextures()
{
for (int i = 0; i < 3; i++)
{
UnloadTexture(textures[i]);
}
return true;
}
//meshes
static const unsigned MeshCount = 4;
static Mesh_t Meshes[4];
enum { Mesh_Body, Mesh_Head, Mesh_LHand, Mesh_RHand };
static const char* const MeshPaths[] = { "body.mesh", "head.mesh", "lhand.mesh", "rhand.mesh" };
static const unsigned Mesh_UseTexture[] = { Texture_Body, Texture_Head, Texture_Hand, Texture_Hand };
static const char* const MeshActivate[] = { NULL, "HEAD", "L_HAND", "R_HAND" };
// Generate a simple triangle mesh from code
static Mesh CreateMesh(const Mesh_t& tso_mesh)
{
Mesh ray_mesh = { 0 };
ray_mesh.vertexCount = tso_mesh.RealVertexCount;
ray_mesh.triangleCount = tso_mesh.FaceCount; // Face count (triangulated)
ray_mesh.vertices = (float*)RL_CALLOC(ray_mesh.vertexCount * 3, sizeof(float));
ray_mesh.texcoords = (float*)RL_CALLOC(ray_mesh.vertexCount * 2, sizeof(float));
ray_mesh.normals = (float*)RL_CALLOC(ray_mesh.vertexCount * 3, sizeof(float));
ray_mesh.indices = (unsigned short*)RL_CALLOC(ray_mesh.triangleCount * 3, sizeof(unsigned short));
// Process all mesh faces
//vertex data
for (unsigned j = 0; j < ray_mesh.vertexCount; j++)
{
//vertices?
ray_mesh.vertices[j * 3 + 0] = tso_mesh.TransformedVertexData[j].Coord.x;
ray_mesh.vertices[j * 3 + 1] = tso_mesh.TransformedVertexData[j].Coord.y;
ray_mesh.vertices[j * 3 + 2] = tso_mesh.TransformedVertexData[j].Coord.z;
//coords
ray_mesh.texcoords[j * 2 + 0] = tso_mesh.TransformedVertexData[j].TextureCoord.u;
ray_mesh.texcoords[j * 2 + 1] = -tso_mesh.TransformedVertexData[j].TextureCoord.v;
//normals
ray_mesh.normals[j * 3 + 0] = tso_mesh.TransformedVertexData[j].NormalCoord.x;
ray_mesh.normals[j * 3 + 0] = tso_mesh.TransformedVertexData[j].NormalCoord.y;
ray_mesh.normals[j * 3 + 0] = tso_mesh.TransformedVertexData[j].NormalCoord.z;
}
//indices
for (unsigned j = 0; j < ray_mesh.triangleCount; j++)
{
ray_mesh.indices[j * 3 + 0] = (unsigned short)tso_mesh.FaceData[j].VertexA;
//counter clock wise
ray_mesh.indices[j * 3 + 1] = (unsigned short)tso_mesh.FaceData[j].VertexC;
ray_mesh.indices[j * 3 + 2] = (unsigned short)tso_mesh.FaceData[j].VertexB;
//Clock wise
//ray_mesh.indices[j * 3 + 1] = (unsigned short)tso_mesh.FaceData[j].VertexB;
//ray_mesh.indices[j * 3 + 2] = (unsigned short)tso_mesh.FaceData[j].VertexC;
}
// Upload mesh data from CPU (RAM) to GPU (VRAM) memory
UploadMesh(&ray_mesh, true); //check the dynamic flag if we have to keep creating the mesh
return ray_mesh;
}
static bool LoadMeshes()
{
uint8_t* InData;
for (unsigned i = 0; i < MeshCount; i++)
{
if (!Read(MeshPaths[i], &InData))
{
return false;
}
ReadMesh(Meshes[i]);
free(InData);
}
return true;
}
static int ResizeScene(uint16_t width, uint16_t height)
{
rlViewport(0, 0, width, height);
rlMatrixMode(RL_PROJECTION);
rlLoadIdentity();
// Calculate The Aspect Ratio Of The Window
//rluPerspective(45.0f, (rlfloat)width/(rlfloat)height, 0.1f, 100.0f);
// rlScalef(-1.0f, 1.0f, 1.0f);
rlMatrixMode(RL_MODELVIEW);
rlLoadIdentity();
return 1;
}
static bool InitRLGL()
{
rlglInit(SCREEN_WIDTH, SCREEN_HEIGHT);
//rlSetCullFace();
//rlEnable(rl_CULL_FACE);
rlDisableBackfaceCulling();
//rlDisable(rl_BLEND);
rlEnableColorBlend();
//rlDepthFunc(rl_LEQUAL); //default
//rlHint(rl_PERSPECTIVE_CORRECTION_HINT, rl_NICEST); //default
//cant change this
//rlFrontFace(rl_CW);
ResizeScene(SCREEN_WIDTH, SCREEN_HEIGHT);
return true;
}
static void TransformVertices(Bone_t& Bone)
{
rlTranslatef(Bone.Translation.x, Bone.Translation.y, Bone.Translation.z);
float matRotation[16];
FindQuaternionMatrix(matRotation, &Bone.Rotation);
rlMultMatrixf(matRotation);
unsigned MeshIndex = 0;
unsigned BoneIndex;
for(unsigned i=1; i<MeshCount; i++){
if(!strcmp(Bone.Name, MeshActivate[i])){
MeshIndex = i;
break;
}
}
Mesh_t& Mesh = Meshes[MeshIndex];
for(BoneIndex=0; BoneIndex<Mesh.BindingCount; BoneIndex++){
if(!strcmp(Bone.Name, Mesh.BoneNames[Mesh.BoneBindings[BoneIndex].BoneIndex]))
break;
}
if(BoneIndex < Mesh.BindingCount){
for(unsigned i=0; i<Mesh.BoneBindings[BoneIndex].RealVertexCount; i++){
unsigned VertexIndex = Mesh.BoneBindings[BoneIndex].FirstRealVertex + i;
Vertex_t& RelativeVertex = Mesh.VertexData[VertexIndex];
Vertex_t& AbsoluteVertex = Mesh.TransformedVertexData[VertexIndex];
rlTranslatef(RelativeVertex.Coord.x, RelativeVertex.Coord.y, RelativeVertex.Coord.z);
const Matrix matModelView = rlGetMatrixModelview();
const Vector3 vertex = Vector3Transform(Vector3{ 0.f, 0.f, 0.f }, matModelView);
AbsoluteVertex.Coord.x = vertex.x;
AbsoluteVertex.Coord.y = vertex.y;
AbsoluteVertex.Coord.z = vertex.z;
rlTranslatef(-RelativeVertex.Coord.x, -RelativeVertex.Coord.y, -RelativeVertex.Coord.z);
}
for(unsigned i=0; i<Mesh.BoneBindings[BoneIndex].BlendVertexCount; i++){
unsigned VertexIndex = Mesh.RealVertexCount + Mesh.BoneBindings[BoneIndex].FirstBlendVertex + i;
Vertex_t& RelativeVertex = Mesh.VertexData[VertexIndex];
Vertex_t& AbsoluteVertex = Mesh.TransformedVertexData[VertexIndex];
rlTranslatef(RelativeVertex.Coord.x, RelativeVertex.Coord.y, RelativeVertex.Coord.z);
const Matrix matModelView = rlGetMatrixModelview();
const Vector3 vertex = Vector3Transform(Vector3{ 0.f, 0.f, 0.f }, matModelView);
AbsoluteVertex.Coord.x = vertex.x;
AbsoluteVertex.Coord.y = vertex.y;
AbsoluteVertex.Coord.z = vertex.z;
rlTranslatef(-RelativeVertex.Coord.x, -RelativeVertex.Coord.y, -RelativeVertex.Coord.z);
}
}
if(Bone.ChildrenCount == 1){
TransformVertices(*Bone.Children[0]);
}else if(Bone.ChildrenCount > 1){
for(unsigned i=0; i<Bone.ChildrenCount; i++){
rlPushMatrix();
TransformVertices(*Bone.Children[i]);
rlPopMatrix();
}
}
}
static void BlendVertices()
{
for(unsigned i=0; i<MeshCount; i++){
Mesh_t& Mesh = Meshes[i];
for(unsigned i=0; i<Mesh.BlendVertexCount; i++){
Vertex_t& BlendVertex = Mesh.TransformedVertexData[Mesh.RealVertexCount + i];
float Weight = BlendVertex.BlendData.Weight;
Vertex_t& RealVertex = Mesh.TransformedVertexData[BlendVertex.BlendData.OtherVertex];
RealVertex.Coord.x =
Weight * BlendVertex.Coord.x +
(1-Weight) * RealVertex.Coord.x;
RealVertex.Coord.y =
Weight * BlendVertex.Coord.y +
(1-Weight) * RealVertex.Coord.y;
RealVertex.Coord.z =
Weight * BlendVertex.Coord.z +
(1-Weight) * RealVertex.Coord.z;
}
}
}
static Mesh ray_meshes[4];
static void CreateMeshes()
{
for (unsigned i = 0; i < MeshCount; i++)
{
ray_meshes[i] = CreateMesh(Meshes[i]);
}
}
static void DrawMeshes()
{
rlPushMatrix();
rlLoadIdentity();
TransformVertices(Skeleton.Bones[0]);
rlPopMatrix();
BlendVertices();
Material material = LoadMaterialDefault();
for (unsigned i = 0; i < MeshCount; i++)
{
material.maps[MATERIAL_MAP_DIFFUSE].texture = textures[Mesh_UseTexture[i]];
DrawMesh(ray_meshes[i], material, MatrixIdentity());
}
rlPopMatrix();
}
static void AdvanceFrame(Skeleton_t& Skeleton, Animation_t& Animation, float TimeDelta)
{
float Duration = (float)Animation.Motions[0].FrameCount/30;
AnimationTime += TimeDelta;
AnimationTime = fmodf(AnimationTime, Duration); //Loop the animation
for(unsigned i=0; i<Animation.MotionsCount; i++){
unsigned BoneIndex = FindBone(Skeleton, Animation.Motions[i].BoneName, Skeleton.BoneCount);
if(BoneIndex == (unsigned)-1) continue;
Bone_t& Bone = Skeleton.Bones[BoneIndex];
unsigned Frame = AnimationTime*30;
float FractionShown = AnimationTime*30 - Frame;
unsigned NextFrame = (Frame+1 != Animation.Motions[0].FrameCount) ? Frame+1 : 0;
if(Animation.Motions[i].HasTranslation){
Translation_t& Translation = Animation.Motions[i].Translations[Frame];
Translation_t& NextTranslation = Animation.Motions[i].Translations[NextFrame];
Bone.Translation.x = (1-FractionShown)*Translation.x + FractionShown*NextTranslation.x;
Bone.Translation.y = (1-FractionShown)*Translation.y + FractionShown*NextTranslation.y;
Bone.Translation.z = (1-FractionShown)*Translation.z + FractionShown*NextTranslation.z;
}
if(Animation.Motions[i].HasRotation){
Rotation_t& Rotation = Animation.Motions[i].Rotations[Frame];
Rotation_t& NextRotation = Animation.Motions[i].Rotations[NextFrame];
//Use nlerp to interpolate
float w1 = 1.0f - FractionShown, w2 = FractionShown;
if(DotProduct(&Rotation, &NextRotation) < 0)
w1 *= -1;
Bone.Rotation.x = w1*Rotation.x + w2*NextRotation.x;
Bone.Rotation.y = w1*Rotation.y + w2*NextRotation.y;
Bone.Rotation.z = w1*Rotation.z + w2*NextRotation.z;
Bone.Rotation.w = w1*Rotation.w + w2*NextRotation.w;
Normalize(&Bone.Rotation);
}
}
}
static void DrawBonesSkeleton(Bone_t& Bone)
{
rlTranslatef(Bone.Translation.x, Bone.Translation.y, Bone.Translation.z);
float RotationMatrix[16];
FindQuaternionMatrix(RotationMatrix, &Bone.Rotation);
rlMultMatrixf(RotationMatrix);
Color color;
if (!strcmp(Bone.Name, "ROOT"))
{
color = RED;
}
else if (!strcmp(Bone.Name, "HEAD"))
{
color = YELLOW;
}
else
{
color = GREEN;
}
DrawCube(Vector3{ 0.f, 0.f, 0.f }, 0.1f, 0.1f, 0.1f, color);
if(Bone.ChildrenCount == 1){
DrawBonesSkeleton(*Bone.Children[0]);
}else if(Bone.ChildrenCount > 1){
for(unsigned i=0; i<Bone.ChildrenCount; i++){
rlPushMatrix();
{
DrawBonesSkeleton(*Bone.Children[i]);
}
rlPopMatrix();
}
}
}
static void DrawSkeleton()
{
rlPushMatrix();
{
DrawBonesSkeleton(Skeleton.Bones[0]);
}
rlPopMatrix();
}
static bool Startup()
{
uint8_t * InData;
if(!Read("skeleton.skel", &InData))
return false;
ReadSkeleton(Skeleton);
free(InData);
for(unsigned i=0; i<MeshCount; i++){
if(!Read(MeshPaths[i], &InData))
return 0;
ReadMesh(Meshes[i]);
free(InData);
}
if(!Read("animation.anim", &InData))
return false;
ReadAnimation(Animation);
free(InData);
AdvanceFrame(Skeleton, Animation, 0);
return true;
}
static Model LoadModelTSO()
{
Model model;
//meshes
model.meshCount = MeshCount;
model.meshes = (Mesh*)RL_CALLOC(model.meshCount, sizeof(Mesh));
//textures
model.materialCount = 3;
model.meshMaterial = (int*)RL_CALLOC(model.meshCount, sizeof(int)); // Material index assigned to each mesh
model.materials = (Material*)RL_CALLOC(model.materialCount, sizeof(Material));
model.meshMaterial[0] = 0; // By default, assign material 0 to each mesh
///load the textures
for (int i = 0; i < model.materialCount; i++)
{
model.materials[i] = LoadMaterialDefault();
model.materials[i].maps[MATERIAL_MAP_DIFFUSE].texture = textures[i];
}
//load meshes
for (int i = 0; i < model.meshCount; i++)
{
Mesh_t& tso_mesh = Meshes[i];
Mesh& ray_mesh = model.meshes[i];
ray_mesh.vertexCount = tso_mesh.RealVertexCount;
ray_mesh.triangleCount = tso_mesh.FaceCount; // Face count (triangulated)
ray_mesh.vertices = (float*)RL_CALLOC(ray_mesh.vertexCount * 3, sizeof(float));
ray_mesh.texcoords = (float*)RL_CALLOC(ray_mesh.vertexCount * 2, sizeof(float));
ray_mesh.normals = (float*)RL_CALLOC(ray_mesh.vertexCount * 3, sizeof(float));
ray_mesh.indices = (unsigned short*)RL_CALLOC(ray_mesh.triangleCount * 3, sizeof(unsigned short));
// Process all mesh faces
//vertex data
for (unsigned j = 0; j < ray_mesh.vertexCount; j++)
{
//vertices?
//ray_mesh.vertices[j * 3 + 0] = tso_mesh.TransformedVertexData[j].Coord.x;
//ray_mesh.vertices[j * 3 + 1] = tso_mesh.TransformedVertexData[j].Coord.y;
//ray_mesh.vertices[j * 3 + 2] = tso_mesh.TransformedVertexData[j].Coord.z;
ray_mesh.vertices[j * 3 + 0] = tso_mesh.VertexData[j].Coord.x;
ray_mesh.vertices[j * 3 + 1] = tso_mesh.VertexData[j].Coord.y;
ray_mesh.vertices[j * 3 + 2] = tso_mesh.VertexData[j].Coord.z; //offset for now so we can see them
//coords
ray_mesh.texcoords[j * 2 + 0] = tso_mesh.TransformedVertexData[j].TextureCoord.u;
ray_mesh.texcoords[j * 2 + 1] = -tso_mesh.TransformedVertexData[j].TextureCoord.v;
//normals
ray_mesh.normals[j * 3 + 0] = tso_mesh.TransformedVertexData[j].NormalCoord.x;
ray_mesh.normals[j * 3 + 0] = tso_mesh.TransformedVertexData[j].NormalCoord.y;
ray_mesh.normals[j * 3 + 0] = tso_mesh.TransformedVertexData[j].NormalCoord.z;
}
//indices
for (unsigned j = 0; j < ray_mesh.triangleCount; j++)
{
ray_mesh.indices[j * 3 + 0] = (unsigned short)tso_mesh.FaceData[j].VertexA;
//counter clock wise
//ray_mesh.indices[j * 3 + 1] = (unsigned short)tso_mesh.FaceData[j].VertexC;
//ray_mesh.indices[j * 3 + 2] = (unsigned short)tso_mesh.FaceData[j].VertexB;
//Clock wise
ray_mesh.indices[j * 3 + 1] = (unsigned short)tso_mesh.FaceData[j].VertexB;
ray_mesh.indices[j * 3 + 2] = (unsigned short)tso_mesh.FaceData[j].VertexC;
}
//select the textures
model.meshMaterial[i] = Mesh_UseTexture[i];
}
//upload to gpu
// Make sure model transform is set to identity matrix!
model.transform = MatrixIdentity();
if ((model.meshCount != 0) && (model.meshes != NULL))
{
// Upload vertex data to GPU (static meshes)
for (int i = 0; i < model.meshCount; i++)
{
UploadMesh(&model.meshes[i], true);
}
}
else TRACELOG(LOG_WARNING, "MESH: [%s] Failed to load model mesh(es) data", fileName);
if (model.materialCount == 0)
{
TRACELOG(LOG_WARNING, "MATERIAL: [%s] Failed to load model material data, default to white material", fileName);
model.materialCount = 1;
model.materials = (Material*)RL_CALLOC(model.materialCount, sizeof(Material));
model.materials[0] = LoadMaterialDefault();
if (model.meshMaterial == NULL)
{
model.meshMaterial = (int*)RL_CALLOC(model.meshCount, sizeof(int));
}
}
return model;
}
//settings
static bool ShowMesh = true;
static bool ShowSkeleton = true;
int main(void)
{
InitWindow(SCREEN_WIDTH, SCREEN_HEIGHT, WINDOW_TITLE);
SetTargetFPS(60);
InitRLGL();
// Define the camera to look into our 3d world
Camera camera;
camera.position = Vector3{ 0.0f, 5.0f, 5.0f }; // Camera position
camera.target = Vector3{ 0.0f, 0.0f, 0.0f }; // Camera looking at point
camera.up = Vector3{ 0.0f, 1.0f, 0.0f }; // Camera up vector (rotation towards target)
camera.fovy = 70.0f; // Camera field-of-view Y
camera.projection = CAMERA_PERSPECTIVE; // Camera projection type
assert( Startup() );
assert( LoadTextures() );
assert( LoadMeshes() );
CreateMeshes();
TransformVertices(Skeleton.Bones[0]);
BlendVertices();
Model model = LoadModelTSO();
printf("======================================\n");
printf("=================RAY==================\n");
printf("======================================\n");
DisableCursor();
while (!WindowShouldClose())
{
const float dt{ GetFrameTime() };
//Handle user interaction
{
UpdateCamera(&camera, CAMERA_FREE);
//if (IsKeyDown(KEY_A)) /*{if(zoom <=-1.0f) zoom+=0.05f; }*/ zoom += 3 * dt;
//if (IsKeyDown(KEY_S)) /*{if(zoom >=-10.0f) zoom-=0.05f; }*/ zoom -= 3 * dt;
if (IsKeyDown(KEY_UP)) { if ((Character.Rotation.x -= 60 * dt) <= -360) Character.Rotation.x += 360; }
if (IsKeyDown(KEY_DOWN)) { if ((Character.Rotation.x += 60 * dt) >= 360) Character.Rotation.x -= 360; }
if (IsKeyDown(KEY_LEFT)) { if ((Character.Rotation.y -= 60 * dt) <= -360) Character.Rotation.y += 360; }
if (IsKeyDown(KEY_RIGHT)) { if ((Character.Rotation.y += 60 * dt) >= 360) Character.Rotation.y -= 360; }
if (IsKeyDown(KEY_X)) { if ((Character.Rotation.z -= 60 * dt) <= -360) Character.Rotation.z += 360; }
if (IsKeyDown(KEY_Z)) { if ((Character.Rotation.z += 60 * dt) >= 360) Character.Rotation.z -= 360; }
if (IsKeyDown(KEY_K)) { Character.Translation.y -= 3 * dt; }
if (IsKeyDown(KEY_I)) { Character.Translation.y += 3 * dt; }
if (IsKeyDown(KEY_J)) { Character.Translation.x -= 3 * dt; }
if (IsKeyDown(KEY_L)) { Character.Translation.x += 3 * dt; }
if (IsKeyPressed(KEY_ONE)){ ShowSkeleton = !ShowSkeleton; }
if (IsKeyPressed(KEY_TWO)) { ShowMesh = !ShowMesh; }
if (IsKeyDown(KEY_N)) { AdvanceFrame(Skeleton, Animation, dt); }
}
//rlClearScreenBuffers(); //Clear the screen and the depth buffer
BeginDrawing();
{
ClearBackground(BLACK);
BeginMode3D(camera);
{
DrawGrid(10, 5.0f);
//Avatar
{
if (ShowMesh)
{
//rlEnableWireMode();
//rlColor3f(1.0, 1.0, 1.0);
//DrawMeshes();
//rlDisableWireMode();
const Vector3 position{ 0.0f, 0.0f, 0.0f };
const float scale = 1.f;
DrawModel(model, position, scale, WHITE);
}
if (ShowSkeleton)
{
DrawSkeleton();
}
}
}
EndMode3D();
}
EndDrawing();
}
UnloadTextures();
CloseWindow();
return 0;
}