JeffM2501/models_mesh_generation.c

## models_mesh_generation.c
/*******************************************************************************************
*
*   raylib example - procedural mesh generation
*
*   This example has been created using raylib 1.8 (www.raylib.com)
*   raylib is licensed under an unmodified zlib/libpng license (View raylib.h for details)
*
*   Copyright (c) 2017 Ramon Santamaria (Ray San)
*
********************************************************************************************/

#include "raylib.h"

#define NUM_MODELS  9      // Parametric 3d shapes to generate

void AllocateMeshData(Mesh* mesh, int triangleCount)
{
    mesh->vertexCount = triangleCount * 3;
    mesh->triangleCount = triangleCount;

    mesh->vertices = (float*)MemAlloc(mesh->vertexCount * 3 * sizeof(float));
    mesh->texcoords = (float*)MemAlloc(mesh->vertexCount * 2 * sizeof(float));
    mesh->normals = (float*)MemAlloc(mesh->vertexCount * 3 * sizeof(float));
}

// generate a simple triangle mesh from code
Mesh MakeMesh()
{
    Mesh mesh = { 0 };
    AllocateMeshData(&mesh, 2);

    float width = 4;
    float height = 2;

    float textureSize = 0.25f; // how big is the texture in world units

    // vertex at the origin
    mesh.vertices[0] = 0;
    mesh.vertices[1] = 0;
    mesh.vertices[2] = 0;
    mesh.normals[0] = 0;
    mesh.normals[1] = 1;
    mesh.normals[2] = 0;
    mesh.texcoords[0] = 0;
    mesh.texcoords[1] = 0;

    // vertex at 2,0,2
    mesh.vertices[3] = width;
    mesh.vertices[4] = 0;
    mesh.vertices[5] = height;
    mesh.normals[3] = 0;
    mesh.normals[4] = 1;
    mesh.normals[5] = 0;
    mesh.texcoords[2] = width/textureSize;
    mesh.texcoords[3] = height / textureSize;

    // vertex at 2,0,0
    mesh.vertices[6] = width;
    mesh.vertices[7] = 0;
    mesh.vertices[8] = 0;
    mesh.normals[6] = 0;
    mesh.normals[7] = 1;
    mesh.normals[8] = 0;
    mesh.texcoords[4] = width / textureSize;
    mesh.texcoords[5] = 0;

    // vertex at the origin
    mesh.vertices[9] = 0;
    mesh.vertices[10] = 0;
    mesh.vertices[11] = 0;
    mesh.normals[9] = 0;
    mesh.normals[10] = 1;
    mesh.normals[11] = 0;
    mesh.texcoords[6] = 0;
    mesh.texcoords[7] = 0;

    // vertex at 0,0,2
    mesh.vertices[12] = 0;
    mesh.vertices[13] = 0;
    mesh.vertices[14] = height;
    mesh.normals[12] = 0;
    mesh.normals[13] = 1;
    mesh.normals[14] = 0;
    mesh.texcoords[8] = 0;
    mesh.texcoords[9] = height / textureSize;

    // vertex at 2,0,2
    mesh.vertices[15] = width;
    mesh.vertices[16] = 0;
    mesh.vertices[17] = height;
    mesh.normals[15] = 0;
    mesh.normals[16] = 1;
    mesh.normals[17] = 0;
    mesh.texcoords[10] = width / textureSize;
    mesh.texcoords[11] = height / textureSize;

    UploadMesh(&mesh, false);

    return mesh;
}

int main(void)
{
    // Initialization
    //--------------------------------------------------------------------------------------
    const int screenWidth = 800;
    const int screenHeight = 450;

    InitWindow(screenWidth, screenHeight, "raylib [models] example - mesh generation");

    // We generate a checked image for texturing
    Image checked = GenImageChecked(2, 2, 1, 1, RED, GREEN);
    Texture2D texture = LoadTextureFromImage(checked);
    UnloadImage(checked);

    Model models[NUM_MODELS] = { 0 };

    models[0] = LoadModelFromMesh(GenMeshPlane(2, 2, 5, 5));
    models[1] = LoadModelFromMesh(GenMeshCube(2.0f, 1.0f, 2.0f));
    models[2] = LoadModelFromMesh(GenMeshSphere(2, 32, 32));
    models[3] = LoadModelFromMesh(GenMeshHemiSphere(2, 16, 16));
    models[4] = LoadModelFromMesh(GenMeshCylinder(1, 2, 16));
    models[5] = LoadModelFromMesh(GenMeshTorus(0.25f, 4.0f, 16, 32));
    models[6] = LoadModelFromMesh(GenMeshKnot(1.0f, 2.0f, 16, 128));
    models[7] = LoadModelFromMesh(GenMeshPoly(5, 2.0f));
    models[8] = LoadModelFromMesh(MakeMesh());

    // Set checked texture as default diffuse component for all models material
    for (int i = 0; i < NUM_MODELS; i++) models[i].materials[0].maps[MATERIAL_MAP_DIFFUSE].texture = texture;

    // Define the camera to look into our 3d world
    Camera camera = { { 5.0f, 5.0f, 5.0f }, { 0.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f }, 45.0f, 0 };

    // Model drawing position
    Vector3 position = { 0.0f, 0.0f, 0.0f };

    int currentModel = 8;

    SetCameraMode(camera, CAMERA_ORBITAL);  // Set a orbital camera mode

    SetTargetFPS(60);               // Set our game to run at 60 frames-per-second
    //--------------------------------------------------------------------------------------

    // Main game loop
    while (!WindowShouldClose())    // Detect window close button or ESC key
    {
        // Update
        //----------------------------------------------------------------------------------
        UpdateCamera(&camera);      // Update internal camera and our camera

        if (IsMouseButtonPressed(MOUSE_LEFT_BUTTON))
        {
            currentModel = (currentModel + 1)%NUM_MODELS; // Cycle between the textures
        }

        if (IsKeyPressed(KEY_RIGHT))
        {
            currentModel++;
            if (currentModel >= NUM_MODELS) currentModel = 0;
        }
        else if (IsKeyPressed(KEY_LEFT))
        {
            currentModel--;
            if (currentModel < 0) currentModel = NUM_MODELS - 1;
        }
        //----------------------------------------------------------------------------------

        // Draw
        //----------------------------------------------------------------------------------
        BeginDrawing();

            ClearBackground(RAYWHITE);

            BeginMode3D(camera);

               DrawModel(models[currentModel], position, 1.0f, WHITE);
               DrawGrid(10, 1.0);

            EndMode3D();

            DrawRectangle(30, 400, 310, 30, Fade(SKYBLUE, 0.5f));
            DrawRectangleLines(30, 400, 310, 30, Fade(DARKBLUE, 0.5f));
            DrawText("MOUSE LEFT BUTTON to CYCLE PROCEDURAL MODELS", 40, 410, 10, BLUE);

            switch(currentModel)
            {
                case 0: DrawText("PLANE", 680, 10, 20, DARKBLUE); break;
                case 1: DrawText("CUBE", 680, 10, 20, DARKBLUE); break;
                case 2: DrawText("SPHERE", 680, 10, 20, DARKBLUE); break;
                case 3: DrawText("HEMISPHERE", 640, 10, 20, DARKBLUE); break;
                case 4: DrawText("CYLINDER", 680, 10, 20, DARKBLUE); break;
                case 5: DrawText("TORUS", 680, 10, 20, DARKBLUE); break;
                case 6: DrawText("KNOT", 680, 10, 20, DARKBLUE); break;
                case 7: DrawText("POLY", 680, 10, 20, DARKBLUE); break;
                case 8: DrawText("Parametric(custom)", 580, 10, 20, DARKBLUE); break;
                default: break;
            }

        EndDrawing();
        //----------------------------------------------------------------------------------
    }

    // De-Initialization
    //--------------------------------------------------------------------------------------
    UnloadTexture(texture); // Unload texture

    // Unload models data (GPU VRAM)
    for (int i = 0; i < NUM_MODELS; i++) UnloadModel(models[i]);

    CloseWindow();          // Close window and OpenGL context
    //--------------------------------------------------------------------------------------

    return 0;
}
	/*******************************************************************************************
	*
	* raylib example - procedural mesh generation
	*
	* This example has been created using raylib 1.8 (www.raylib.com)
	* raylib is licensed under an unmodified zlib/libpng license (View raylib.h for details)
	*
	* Copyright (c) 2017 Ramon Santamaria (Ray San)
	*
	********************************************************************************************/

	#include "raylib.h"

	#define NUM_MODELS 9 // Parametric 3d shapes to generate

	void AllocateMeshData(Mesh* mesh, int triangleCount)
	{
	mesh->vertexCount = triangleCount * 3;
	mesh->triangleCount = triangleCount;

	mesh->vertices = (float)MemAlloc(mesh->vertexCount 3 * sizeof(float));
	mesh->texcoords = (float)MemAlloc(mesh->vertexCount 2 * sizeof(float));
	mesh->normals = (float)MemAlloc(mesh->vertexCount 3 * sizeof(float));
	}

	// generate a simple triangle mesh from code
	Mesh MakeMesh()
	{
	Mesh mesh = { 0 };
	AllocateMeshData(&mesh, 2);

	float width = 4;
	float height = 2;

	float textureSize = 0.25f; // how big is the texture in world units

	// vertex at the origin
	mesh.vertices[0] = 0;
	mesh.vertices[1] = 0;
	mesh.vertices[2] = 0;
	mesh.normals[0] = 0;
	mesh.normals[1] = 1;
	mesh.normals[2] = 0;
	mesh.texcoords[0] = 0;
	mesh.texcoords[1] = 0;

	// vertex at 2,0,2
	mesh.vertices[3] = width;
	mesh.vertices[4] = 0;
	mesh.vertices[5] = height;
	mesh.normals[3] = 0;
	mesh.normals[4] = 1;
	mesh.normals[5] = 0;
	mesh.texcoords[2] = width/textureSize;
	mesh.texcoords[3] = height / textureSize;

	// vertex at 2,0,0
	mesh.vertices[6] = width;
	mesh.vertices[7] = 0;
	mesh.vertices[8] = 0;
	mesh.normals[6] = 0;
	mesh.normals[7] = 1;
	mesh.normals[8] = 0;
	mesh.texcoords[4] = width / textureSize;
	mesh.texcoords[5] = 0;

	// vertex at the origin
	mesh.vertices[9] = 0;
	mesh.vertices[10] = 0;
	mesh.vertices[11] = 0;
	mesh.normals[9] = 0;
	mesh.normals[10] = 1;
	mesh.normals[11] = 0;
	mesh.texcoords[6] = 0;
	mesh.texcoords[7] = 0;

	// vertex at 0,0,2
	mesh.vertices[12] = 0;
	mesh.vertices[13] = 0;
	mesh.vertices[14] = height;
	mesh.normals[12] = 0;
	mesh.normals[13] = 1;
	mesh.normals[14] = 0;
	mesh.texcoords[8] = 0;
	mesh.texcoords[9] = height / textureSize;

	// vertex at 2,0,2
	mesh.vertices[15] = width;
	mesh.vertices[16] = 0;
	mesh.vertices[17] = height;
	mesh.normals[15] = 0;
	mesh.normals[16] = 1;
	mesh.normals[17] = 0;
	mesh.texcoords[10] = width / textureSize;
	mesh.texcoords[11] = height / textureSize;

	UploadMesh(&mesh, false);

	return mesh;
	}

	int main(void)
	{
	// Initialization
	//--------------------------------------------------------------------------------------
	const int screenWidth = 800;
	const int screenHeight = 450;

	InitWindow(screenWidth, screenHeight, "raylib [models] example - mesh generation");

	// We generate a checked image for texturing
	Image checked = GenImageChecked(2, 2, 1, 1, RED, GREEN);
	Texture2D texture = LoadTextureFromImage(checked);
	UnloadImage(checked);

	Model models[NUM_MODELS] = { 0 };

	models[0] = LoadModelFromMesh(GenMeshPlane(2, 2, 5, 5));
	models[1] = LoadModelFromMesh(GenMeshCube(2.0f, 1.0f, 2.0f));
	models[2] = LoadModelFromMesh(GenMeshSphere(2, 32, 32));
	models[3] = LoadModelFromMesh(GenMeshHemiSphere(2, 16, 16));
	models[4] = LoadModelFromMesh(GenMeshCylinder(1, 2, 16));
	models[5] = LoadModelFromMesh(GenMeshTorus(0.25f, 4.0f, 16, 32));
	models[6] = LoadModelFromMesh(GenMeshKnot(1.0f, 2.0f, 16, 128));
	models[7] = LoadModelFromMesh(GenMeshPoly(5, 2.0f));
	models[8] = LoadModelFromMesh(MakeMesh());

	// Set checked texture as default diffuse component for all models material
	for (int i = 0; i < NUM_MODELS; i++) models[i].materials[0].maps[MATERIAL_MAP_DIFFUSE].texture = texture;

	// Define the camera to look into our 3d world
	Camera camera = { { 5.0f, 5.0f, 5.0f }, { 0.0f, 0.0f, 0.0f }, { 0.0f, 1.0f, 0.0f }, 45.0f, 0 };

	// Model drawing position
	Vector3 position = { 0.0f, 0.0f, 0.0f };

	int currentModel = 8;

	SetCameraMode(camera, CAMERA_ORBITAL); // Set a orbital camera mode

	SetTargetFPS(60); // Set our game to run at 60 frames-per-second
	//--------------------------------------------------------------------------------------

	// Main game loop
	while (!WindowShouldClose()) // Detect window close button or ESC key
	{
	// Update
	//----------------------------------------------------------------------------------
	UpdateCamera(&camera); // Update internal camera and our camera

	if (IsMouseButtonPressed(MOUSE_LEFT_BUTTON))
	{
	currentModel = (currentModel + 1)%NUM_MODELS; // Cycle between the textures
	}

	if (IsKeyPressed(KEY_RIGHT))
	{
	currentModel++;
	if (currentModel >= NUM_MODELS) currentModel = 0;
	}
	else if (IsKeyPressed(KEY_LEFT))
	{
	currentModel--;
	if (currentModel < 0) currentModel = NUM_MODELS - 1;
	}
	//----------------------------------------------------------------------------------

	// Draw
	//----------------------------------------------------------------------------------
	BeginDrawing();

	ClearBackground(RAYWHITE);

	BeginMode3D(camera);

	DrawModel(models[currentModel], position, 1.0f, WHITE);
	DrawGrid(10, 1.0);

	EndMode3D();

	DrawRectangle(30, 400, 310, 30, Fade(SKYBLUE, 0.5f));
	DrawRectangleLines(30, 400, 310, 30, Fade(DARKBLUE, 0.5f));
	DrawText("MOUSE LEFT BUTTON to CYCLE PROCEDURAL MODELS", 40, 410, 10, BLUE);

	switch(currentModel)
	{
	case 0: DrawText("PLANE", 680, 10, 20, DARKBLUE); break;
	case 1: DrawText("CUBE", 680, 10, 20, DARKBLUE); break;
	case 2: DrawText("SPHERE", 680, 10, 20, DARKBLUE); break;
	case 3: DrawText("HEMISPHERE", 640, 10, 20, DARKBLUE); break;
	case 4: DrawText("CYLINDER", 680, 10, 20, DARKBLUE); break;
	case 5: DrawText("TORUS", 680, 10, 20, DARKBLUE); break;
	case 6: DrawText("KNOT", 680, 10, 20, DARKBLUE); break;
	case 7: DrawText("POLY", 680, 10, 20, DARKBLUE); break;
	case 8: DrawText("Parametric(custom)", 580, 10, 20, DARKBLUE); break;
	default: break;
	}

	EndDrawing();
	//----------------------------------------------------------------------------------
	}

	// De-Initialization
	//--------------------------------------------------------------------------------------
	UnloadTexture(texture); // Unload texture

	// Unload models data (GPU VRAM)
	for (int i = 0; i < NUM_MODELS; i++) UnloadModel(models[i]);

	CloseWindow(); // Close window and OpenGL context
	//--------------------------------------------------------------------------------------

	return 0;
	}