raylib/src/models.c

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/**********************************************************************************************
*
* raylib.models
*
* Basic functions to draw 3d shapes and load/draw 3d models (.OBJ)
*
2015-07-29 22:43:30 +03:00
* Copyright (c) 2014 Ramon Santamaria (@raysan5)
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*
* This software is provided "as-is", without any express or implied warranty. In no event
* will the authors be held liable for any damages arising from the use of this software.
*
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* Permission is granted to anyone to use this software for any purpose, including commercial
* applications, and to alter it and redistribute it freely, subject to the following restrictions:
*
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* 1. The origin of this software must not be misrepresented; you must not claim that you
* wrote the original software. If you use this software in a product, an acknowledgment
* in the product documentation would be appreciated but is not required.
*
* 2. Altered source versions must be plainly marked as such, and must not be misrepresented
* as being the original software.
*
* 3. This notice may not be removed or altered from any source distribution.
*
**********************************************************************************************/
#include "raylib.h"
#if defined(PLATFORM_ANDROID)
#include "utils.h" // Android fopen function map
#endif
#include <stdio.h> // Standard input/output functions, used to read model files data
#include <stdlib.h> // Declares malloc() and free() for memory management
#include <string.h> // Required for strcmp()
#include <math.h> // Used for sin, cos, tan
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#include "raymath.h" // Required for data type Matrix and Matrix functions
#include "rlgl.h" // raylib OpenGL abstraction layer to OpenGL 1.1, 3.3+ or ES2
//----------------------------------------------------------------------------------
// Defines and Macros
//----------------------------------------------------------------------------------
#define CUBIC_MAP_HALF_BLOCK_SIZE 0.5
//----------------------------------------------------------------------------------
// Types and Structures Definition
//----------------------------------------------------------------------------------
// ...
//----------------------------------------------------------------------------------
// Global Variables Definition
//----------------------------------------------------------------------------------
extern unsigned int whiteTexture;
//----------------------------------------------------------------------------------
// Module specific Functions Declaration
//----------------------------------------------------------------------------------
static float GetHeightValue(Color pixel);
static VertexData LoadOBJ(const char *fileName);
//----------------------------------------------------------------------------------
// Module Functions Definition
//----------------------------------------------------------------------------------
// Draw cube
// NOTE: Cube position is the center position
void DrawCube(Vector3 position, float width, float height, float length, Color color)
{
float x = 0.0f;
float y = 0.0f;
float z = 0.0f;
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rlPushMatrix();
// NOTE: Be careful! Function order matters (rotate -> scale -> translate)
rlTranslatef(position.x, position.y, position.z);
//rlScalef(2.0f, 2.0f, 2.0f);
//rlRotatef(45, 0, 1, 0);
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rlBegin(RL_TRIANGLES);
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rlColor4ub(color.r, color.g, color.b, color.a);
// Front Face -----------------------------------------------------
rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Left
rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Right
rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left
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rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Right
rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left
rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Right
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// Back Face ------------------------------------------------------
rlVertex3f(x-width/2, y-height/2, z-length/2); // Bottom Left
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left
rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Right
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rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right
rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Right
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left
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// Top Face -------------------------------------------------------
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left
rlVertex3f(x-width/2, y+height/2, z+length/2); // Bottom Left
rlVertex3f(x+width/2, y+height/2, z+length/2); // Bottom Right
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rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left
rlVertex3f(x+width/2, y+height/2, z+length/2); // Bottom Right
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// Bottom Face ----------------------------------------------------
rlVertex3f(x-width/2, y-height/2, z-length/2); // Top Left
rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Right
rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Left
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rlVertex3f(x+width/2, y-height/2, z-length/2); // Top Right
rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Right
rlVertex3f(x-width/2, y-height/2, z-length/2); // Top Left
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// Right face -----------------------------------------------------
rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Right
rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right
rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Left
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rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Left
rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Right
rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Left
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// Left Face ------------------------------------------------------
rlVertex3f(x-width/2, y-height/2, z-length/2); // Bottom Right
rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Right
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rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Left
rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left
rlVertex3f(x-width/2, y-height/2, z-length/2); // Bottom Right
rlEnd();
rlPopMatrix();
}
// Draw cube (Vector version)
void DrawCubeV(Vector3 position, Vector3 size, Color color)
{
DrawCube(position, size.x, size.y, size.z, color);
}
// Draw cube wires
void DrawCubeWires(Vector3 position, float width, float height, float length, Color color)
{
float x = 0.0f;
float y = 0.0f;
float z = 0.0f;
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rlPushMatrix();
rlTranslatef(position.x, position.y, position.z);
//rlRotatef(45, 0, 1, 0);
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rlBegin(RL_LINES);
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rlColor4ub(color.r, color.g, color.b, color.a);
// Front Face -----------------------------------------------------
// Bottom Line
rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Left
rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Right
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// Left Line
rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Right
rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Right
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// Top Line
rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Right
rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left
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// Right Line
rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left
rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Left
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// Back Face ------------------------------------------------------
// Bottom Line
rlVertex3f(x-width/2, y-height/2, z-length/2); // Bottom Left
rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Right
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// Left Line
rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Right
rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right
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// Top Line
rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left
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// Right Line
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left
rlVertex3f(x-width/2, y-height/2, z-length/2); // Bottom Left
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// Top Face -------------------------------------------------------
// Left Line
rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left Front
rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left Back
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// Right Line
rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Right Front
rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right Back
// Bottom Face ---------------------------------------------------
// Left Line
rlVertex3f(x-width/2, y-height/2, z+length/2); // Top Left Front
rlVertex3f(x-width/2, y-height/2, z-length/2); // Top Left Back
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// Right Line
rlVertex3f(x+width/2, y-height/2, z+length/2); // Top Right Front
rlVertex3f(x+width/2, y-height/2, z-length/2); // Top Right Back
rlEnd();
rlPopMatrix();
}
// Draw cube
// NOTE: Cube position is the center position
void DrawCubeTexture(Texture2D texture, Vector3 position, float width, float height, float length, Color color)
{
float x = position.x;
float y = position.y;
float z = position.z;
rlEnableTexture(texture.id);
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//rlPushMatrix();
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// NOTE: Be careful! Function order matters (scale, translate, rotate)
//rlScalef(2.0f, 2.0f, 2.0f);
//rlTranslatef(2.0f, 0.0f, 0.0f);
//rlRotatef(45, 0, 1, 0);
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rlBegin(RL_QUADS);
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rlColor4ub(color.r, color.g, color.b, color.a);
// Front Face
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rlNormal3f(0.0f, 0.0f, 1.0f); // Normal Pointing Towards Viewer
rlTexCoord2f(0.0f, 0.0f); rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Left Of The Texture and Quad
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Right Of The Texture and Quad
rlTexCoord2f(1.0f, 1.0f); rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Right Of The Texture and Quad
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Left Of The Texture and Quad
// Back Face
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rlNormal3f( 0.0f, 0.0f,-1.0f); // Normal Pointing Away From Viewer
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(x-width/2, y-height/2, z-length/2); // Bottom Right Of The Texture and Quad
rlTexCoord2f(1.0f, 1.0f); rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Right Of The Texture and Quad
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Left Of The Texture and Quad
rlTexCoord2f(0.0f, 0.0f); rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Left Of The Texture and Quad
// Top Face
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rlNormal3f( 0.0f, 1.0f, 0.0f); // Normal Pointing Up
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left Of The Texture and Quad
rlTexCoord2f(0.0f, 0.0f); rlVertex3f(x-width/2, y+height/2, z+length/2); // Bottom Left Of The Texture and Quad
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(x+width/2, y+height/2, z+length/2); // Bottom Right Of The Texture and Quad
rlTexCoord2f(1.0f, 1.0f); rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right Of The Texture and Quad
// Bottom Face
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rlNormal3f( 0.0f,-1.0f, 0.0f); // Normal Pointing Down
rlTexCoord2f(1.0f, 1.0f); rlVertex3f(x-width/2, y-height/2, z-length/2); // Top Right Of The Texture and Quad
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(x+width/2, y-height/2, z-length/2); // Top Left Of The Texture and Quad
rlTexCoord2f(0.0f, 0.0f); rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Left Of The Texture and Quad
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Right Of The Texture and Quad
// Right face
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rlNormal3f( 1.0f, 0.0f, 0.0f); // Normal Pointing Right
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(x+width/2, y-height/2, z-length/2); // Bottom Right Of The Texture and Quad
rlTexCoord2f(1.0f, 1.0f); rlVertex3f(x+width/2, y+height/2, z-length/2); // Top Right Of The Texture and Quad
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(x+width/2, y+height/2, z+length/2); // Top Left Of The Texture and Quad
rlTexCoord2f(0.0f, 0.0f); rlVertex3f(x+width/2, y-height/2, z+length/2); // Bottom Left Of The Texture and Quad
// Left Face
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rlNormal3f(-1.0f, 0.0f, 0.0f); // Normal Pointing Left
rlTexCoord2f(0.0f, 0.0f); rlVertex3f(x-width/2, y-height/2, z-length/2); // Bottom Left Of The Texture and Quad
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(x-width/2, y-height/2, z+length/2); // Bottom Right Of The Texture and Quad
rlTexCoord2f(1.0f, 1.0f); rlVertex3f(x-width/2, y+height/2, z+length/2); // Top Right Of The Texture and Quad
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(x-width/2, y+height/2, z-length/2); // Top Left Of The Texture and Quad
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rlEnd();
//rlPopMatrix();
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rlDisableTexture();
}
// Draw sphere
void DrawSphere(Vector3 centerPos, float radius, Color color)
{
DrawSphereEx(centerPos, radius, 16, 16, color);
}
// Draw sphere with extended parameters
void DrawSphereEx(Vector3 centerPos, float radius, int rings, int slices, Color color)
{
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rlPushMatrix();
rlTranslatef(centerPos.x, centerPos.y, centerPos.z);
rlScalef(radius, radius, radius);
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rlBegin(RL_TRIANGLES);
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rlColor4ub(color.r, color.g, color.b, color.a);
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for(int i = 0; i < (rings + 2); i++)
{
for(int j = 0; j < slices; j++)
{
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*i)) * sin(DEG2RAD*(j*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*i)),
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cos(DEG2RAD*(270+(180/(rings + 1))*i)) * cos(DEG2RAD*(j*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * sin(DEG2RAD*((j+1)*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i+1))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * cos(DEG2RAD*((j+1)*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * sin(DEG2RAD*(j*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i+1))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * cos(DEG2RAD*(j*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*i)) * sin(DEG2RAD*(j*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*i)),
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cos(DEG2RAD*(270+(180/(rings + 1))*i)) * cos(DEG2RAD*(j*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i))) * sin(DEG2RAD*((j+1)*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i))) * cos(DEG2RAD*((j+1)*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * sin(DEG2RAD*((j+1)*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i+1))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * cos(DEG2RAD*((j+1)*360/slices)));
}
}
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rlEnd();
rlPopMatrix();
}
// Draw sphere wires
void DrawSphereWires(Vector3 centerPos, float radius, int rings, int slices, Color color)
{
rlPushMatrix();
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rlTranslatef(centerPos.x, centerPos.y, centerPos.z);
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rlScalef(radius, radius, radius);
rlBegin(RL_LINES);
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rlColor4ub(color.r, color.g, color.b, color.a);
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for(int i = 0; i < (rings + 2); i++)
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{
for(int j = 0; j < slices; j++)
{
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*i)) * sin(DEG2RAD*(j*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*i)),
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cos(DEG2RAD*(270+(180/(rings + 1))*i)) * cos(DEG2RAD*(j*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * sin(DEG2RAD*((j+1)*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i+1))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * cos(DEG2RAD*((j+1)*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * sin(DEG2RAD*((j+1)*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i+1))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * cos(DEG2RAD*((j+1)*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * sin(DEG2RAD*(j*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i+1))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * cos(DEG2RAD*(j*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * sin(DEG2RAD*(j*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*(i+1))),
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cos(DEG2RAD*(270+(180/(rings + 1))*(i+1))) * cos(DEG2RAD*(j*360/slices)));
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rlVertex3f(cos(DEG2RAD*(270+(180/(rings + 1))*i)) * sin(DEG2RAD*(j*360/slices)),
sin(DEG2RAD*(270+(180/(rings + 1))*i)),
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cos(DEG2RAD*(270+(180/(rings + 1))*i)) * cos(DEG2RAD*(j*360/slices)));
}
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}
rlEnd();
rlPopMatrix();
}
// Draw a cylinder
// NOTE: It could be also used for pyramid and cone
void DrawCylinder(Vector3 position, float radiusTop, float radiusBottom, float height, int sides, Color color)
{
if (sides < 3) sides = 3;
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rlPushMatrix();
rlTranslatef(position.x, position.y, position.z);
rlBegin(RL_TRIANGLES);
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rlColor4ub(color.r, color.g, color.b, color.a);
if (radiusTop > 0)
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{
// Draw Body -------------------------------------------------------------------------------------
for(int i = 0; i < 360; i += 360/sides)
{
rlVertex3f(sin(DEG2RAD*i) * radiusBottom, 0, cos(DEG2RAD*i) * radiusBottom); //Bottom Left
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusBottom, 0, cos(DEG2RAD*(i+360/sides)) * radiusBottom); //Bottom Right
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusTop, height, cos(DEG2RAD*(i+360/sides)) * radiusTop); //Top Right
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rlVertex3f(sin(DEG2RAD*i) * radiusTop, height, cos(DEG2RAD*i) * radiusTop); //Top Left
rlVertex3f(sin(DEG2RAD*i) * radiusBottom, 0, cos(DEG2RAD*i) * radiusBottom); //Bottom Left
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusTop, height, cos(DEG2RAD*(i+360/sides)) * radiusTop); //Top Right
}
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// Draw Cap --------------------------------------------------------------------------------------
for(int i = 0; i < 360; i += 360/sides)
{
rlVertex3f(0, height, 0);
rlVertex3f(sin(DEG2RAD*i) * radiusTop, height, cos(DEG2RAD*i) * radiusTop);
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusTop, height, cos(DEG2RAD*(i+360/sides)) * radiusTop);
}
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}
else
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{
// Draw Cone -------------------------------------------------------------------------------------
for(int i = 0; i < 360; i += 360/sides)
{
rlVertex3f(0, height, 0);
rlVertex3f(sin(DEG2RAD*i) * radiusBottom, 0, cos(DEG2RAD*i) * radiusBottom);
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusBottom, 0, cos(DEG2RAD*(i+360/sides)) * radiusBottom);
}
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}
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// Draw Base -----------------------------------------------------------------------------------------
for(int i = 0; i < 360; i += 360/sides)
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{
rlVertex3f(0, 0, 0);
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusBottom, 0, cos(DEG2RAD*(i+360/sides)) * radiusBottom);
rlVertex3f(sin(DEG2RAD*i) * radiusBottom, 0, cos(DEG2RAD*i) * radiusBottom);
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}
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rlEnd();
rlPopMatrix();
}
// Draw a wired cylinder
// NOTE: It could be also used for pyramid and cone
void DrawCylinderWires(Vector3 position, float radiusTop, float radiusBottom, float height, int sides, Color color)
{
if(sides < 3) sides = 3;
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rlPushMatrix();
rlTranslatef(position.x, position.y, position.z);
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rlBegin(RL_LINES);
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rlColor4ub(color.r, color.g, color.b, color.a);
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for(int i = 0; i < 360; i += 360/sides)
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{
rlVertex3f(sin(DEG2RAD*i) * radiusBottom, 0, cos(DEG2RAD*i) * radiusBottom);
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusBottom, 0, cos(DEG2RAD*(i+360/sides)) * radiusBottom);
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rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusBottom, 0, cos(DEG2RAD*(i+360/sides)) * radiusBottom);
rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusTop, height, cos(DEG2RAD*(i+360/sides)) * radiusTop);
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rlVertex3f(sin(DEG2RAD*(i+360/sides)) * radiusTop, height, cos(DEG2RAD*(i+360/sides)) * radiusTop);
rlVertex3f(sin(DEG2RAD*i) * radiusTop, height, cos(DEG2RAD*i) * radiusTop);
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rlVertex3f(sin(DEG2RAD*i) * radiusTop, height, cos(DEG2RAD*i) * radiusTop);
rlVertex3f(sin(DEG2RAD*i) * radiusBottom, 0, cos(DEG2RAD*i) * radiusBottom);
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}
rlEnd();
rlPopMatrix();
}
// Draw a plane
void DrawPlane(Vector3 centerPos, Vector2 size, Color color)
{
// NOTE: QUADS usage require defining a texture on OpenGL 3.3+
if (rlGetVersion() != OPENGL_11) rlEnableTexture(whiteTexture); // Default white texture
// NOTE: Plane is always created on XZ ground
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rlPushMatrix();
rlTranslatef(centerPos.x, centerPos.y, centerPos.z);
rlScalef(size.x, 1.0f, size.y);
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rlBegin(RL_QUADS);
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rlColor4ub(color.r, color.g, color.b, color.a);
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rlNormal3f(0.0f, 1.0f, 0.0f);
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rlTexCoord2f(0.0f, 0.0f); rlVertex3f(-0.5f, 0.0f, -0.5f);
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(-0.5f, 0.0f, 0.5f);
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rlTexCoord2f(1.0f, 1.0f); rlVertex3f(0.5f, 0.0f, 0.5f);
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(0.5f, 0.0f, -0.5f);
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rlEnd();
rlPopMatrix();
if (rlGetVersion() != OPENGL_11) rlDisableTexture();
}
// Draw a quad
void DrawQuad(Vector3 v1, Vector3 v2, Vector3 v3, Vector3 v4, Color color)
{
// TODO: Calculate normals from vertex position
rlBegin(RL_QUADS);
rlColor4ub(color.r, color.g, color.b, color.a);
//rlNormal3f(0.0f, 0.0f, 0.0f);
rlVertex3f(v1.x, v1.y, v1.z);
rlVertex3f(v2.x, v2.y, v2.z);
rlVertex3f(v3.x, v3.y, v3.z);
rlVertex3f(v4.x, v4.y, v4.z);
rlEnd();
}
// Draw a ray line
void DrawRay(Ray ray, Color color)
{
float scale = 10000;
rlBegin(RL_LINES);
rlColor4ub(color.r, color.g, color.b, color.a);
rlColor4ub(color.r, color.g, color.b, color.a);
rlVertex3f(ray.position.x, ray.position.y, ray.position.z);
rlVertex3f(ray.position.x + ray.direction.x*scale, ray.position.y + ray.direction.y*scale, ray.position.z + ray.direction.z*scale);
rlEnd();
}
// Draw a grid centered at (0, 0, 0)
void DrawGrid(int slices, float spacing)
{
int halfSlices = slices / 2;
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rlBegin(RL_LINES);
for(int i = -halfSlices; i <= halfSlices; i++)
{
if (i == 0)
{
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rlColor3f(0.5f, 0.5f, 0.5f);
rlColor3f(0.5f, 0.5f, 0.5f);
rlColor3f(0.5f, 0.5f, 0.5f);
rlColor3f(0.5f, 0.5f, 0.5f);
}
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else
{
rlColor3f(0.75f, 0.75f, 0.75f);
rlColor3f(0.75f, 0.75f, 0.75f);
rlColor3f(0.75f, 0.75f, 0.75f);
rlColor3f(0.75f, 0.75f, 0.75f);
}
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rlVertex3f((float)i*spacing, 0.0f, (float)-halfSlices*spacing);
rlVertex3f((float)i*spacing, 0.0f, (float)halfSlices*spacing);
rlVertex3f((float)-halfSlices*spacing, 0.0f, (float)i*spacing);
rlVertex3f((float)halfSlices*spacing, 0.0f, (float)i*spacing);
}
rlEnd();
}
// Draw gizmo
void DrawGizmo(Vector3 position)
{
// NOTE: RGB = XYZ
float length = 1.0f;
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rlPushMatrix();
rlTranslatef(position.x, position.y, position.z);
//rlRotatef(rotation, 0, 1, 0);
rlScalef(length, length, length);
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rlBegin(RL_LINES);
rlColor3f(1.0f, 0.0f, 0.0f); rlVertex3f(0.0f, 0.0f, 0.0f);
rlColor3f(1.0f, 0.0f, 0.0f); rlVertex3f(1.0f, 0.0f, 0.0f);
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rlColor3f(0.0f, 1.0f, 0.0f); rlVertex3f(0.0f, 0.0f, 0.0f);
rlColor3f(0.0f, 1.0f, 0.0f); rlVertex3f(0.0f, 1.0f, 0.0f);
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rlColor3f(0.0f, 0.0f, 1.0f); rlVertex3f(0.0f, 0.0f, 0.0f);
rlColor3f(0.0f, 0.0f, 1.0f); rlVertex3f(0.0f, 0.0f, 1.0f);
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rlEnd();
rlPopMatrix();
}
// Load a 3d model (from file)
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Model LoadModel(const char *fileName)
{
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Model model;
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VertexData vData = { 0 };
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// NOTE: Initialize default data for model in case loading fails, maybe a cube?
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if (strcmp(GetExtension(fileName),"obj") == 0) vData = LoadOBJ(fileName);
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else TraceLog(WARNING, "[%s] Model extension not recognized, it can't be loaded", fileName);
// NOTE: At this point we have all vertex, texcoord, normal data for the model in vData struct
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if (vData.vertexCount == 0)
{
TraceLog(WARNING, "Model could not be loaded");
}
else
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{
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// NOTE: model properties (transform, texture, shader) are initialized inside rlglLoadModel()
model = rlglLoadModel(vData); // Upload vertex data to GPU
// Now that vertex data is uploaded to GPU, we can free arrays
// NOTE: We don't need CPU vertex data on OpenGL 3.3 or ES2
if (rlGetVersion() != OPENGL_11)
{
free(vData.vertices);
free(vData.texcoords);
free(vData.normals);
free(vData.colors);
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}
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}
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return model;
}
// Load a 3d model (from vertex data)
Model LoadModelEx(VertexData data)
{
Model model;
// NOTE: model properties (transform, texture, shader) are initialized inside rlglLoadModel()
model = rlglLoadModel(data); // Upload vertex data to GPU
// NOTE: Vertex data is managed externally, must be deallocated manually
return model;
}
// Load a heightmap image as a 3d model
Model LoadHeightmap(Image heightmap, float maxHeight)
{
VertexData vData;
int mapX = heightmap.width;
int mapZ = heightmap.height;
Color *heightmapPixels = GetImageData(heightmap);
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// NOTE: One vertex per pixel
// TODO: Consider resolution when generating model data?
int numTriangles = (mapX-1)*(mapZ-1)*2; // One quad every four pixels
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vData.vertexCount = numTriangles*3;
vData.vertices = (float *)malloc(vData.vertexCount*3*sizeof(float));
vData.normals = (float *)malloc(vData.vertexCount*3*sizeof(float));
vData.texcoords = (float *)malloc(vData.vertexCount*2*sizeof(float));
vData.colors = (unsigned char *)malloc(vData.vertexCount*4*sizeof(unsigned char)); // Not used...
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int vCounter = 0; // Used to count vertices float by float
int tcCounter = 0; // Used to count texcoords float by float
int nCounter = 0; // Used to count normals float by float
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int trisCounter = 0;
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float scaleFactor = maxHeight/255; // TODO: Review scaleFactor calculation
for(int z = 0; z < mapZ-1; z++)
{
for(int x = 0; x < mapX-1; x++)
{
// Fill vertices array with data
//----------------------------------------------------------
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// one triangle - 3 vertex
vData.vertices[vCounter] = x;
vData.vertices[vCounter + 1] = GetHeightValue(heightmapPixels[x + z*mapX])*scaleFactor;
vData.vertices[vCounter + 2] = z;
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vData.vertices[vCounter + 3] = x;
vData.vertices[vCounter + 4] = GetHeightValue(heightmapPixels[x + (z+1)*mapX])*scaleFactor;
vData.vertices[vCounter + 5] = z+1;
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vData.vertices[vCounter + 6] = x+1;
vData.vertices[vCounter + 7] = GetHeightValue(heightmapPixels[(x+1) + z*mapX])*scaleFactor;
vData.vertices[vCounter + 8] = z;
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// another triangle - 3 vertex
vData.vertices[vCounter + 9] = vData.vertices[vCounter + 6];
vData.vertices[vCounter + 10] = vData.vertices[vCounter + 7];
vData.vertices[vCounter + 11] = vData.vertices[vCounter + 8];
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vData.vertices[vCounter + 12] = vData.vertices[vCounter + 3];
vData.vertices[vCounter + 13] = vData.vertices[vCounter + 4];
vData.vertices[vCounter + 14] = vData.vertices[vCounter + 5];
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vData.vertices[vCounter + 15] = x+1;
vData.vertices[vCounter + 16] = GetHeightValue(heightmapPixels[(x+1) + (z+1)*mapX])*scaleFactor;
vData.vertices[vCounter + 17] = z+1;
vCounter += 18; // 6 vertex, 18 floats
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// Fill texcoords array with data
//--------------------------------------------------------------
vData.texcoords[tcCounter] = (float)x / (mapX-1);
vData.texcoords[tcCounter + 1] = (float)z / (mapZ-1);
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vData.texcoords[tcCounter + 2] = (float)x / (mapX-1);
vData.texcoords[tcCounter + 3] = (float)(z+1) / (mapZ-1);
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vData.texcoords[tcCounter + 4] = (float)(x+1) / (mapX-1);
vData.texcoords[tcCounter + 5] = (float)z / (mapZ-1);
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vData.texcoords[tcCounter + 6] = vData.texcoords[tcCounter + 4];
vData.texcoords[tcCounter + 7] = vData.texcoords[tcCounter + 5];
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vData.texcoords[tcCounter + 8] = vData.texcoords[tcCounter + 2];
vData.texcoords[tcCounter + 9] = vData.texcoords[tcCounter + 3];
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vData.texcoords[tcCounter + 10] = (float)(x+1) / (mapX-1);
vData.texcoords[tcCounter + 11] = (float)(z+1) / (mapZ-1);
tcCounter += 12; // 6 texcoords, 12 floats
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// Fill normals array with data
//--------------------------------------------------------------
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// NOTE: Current Model implementation doe not use normals!
for (int i = 0; i < 18; i += 3)
{
vData.normals[nCounter + i] = 0.0f;
vData.normals[nCounter + i + 1] = 1.0f;
vData.normals[nCounter + i + 2] = 0.0f;
}
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// TODO: Calculate normals in an efficient way
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nCounter += 18; // 6 vertex, 18 floats
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trisCounter += 2;
}
}
free(heightmapPixels);
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// Fill color data
// NOTE: Not used any more... just one plain color defined at DrawModel()
for (int i = 0; i < (4*vData.vertexCount); i++) vData.colors[i] = 255;
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// NOTE: At this point we have all vertex, texcoord, normal data for the model in vData struct
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Model model = rlglLoadModel(vData);
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// Now that vertex data is uploaded to GPU, we can free arrays
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// NOTE: We don't need CPU vertex data on OpenGL 3.3 or ES2
if (rlGetVersion() != OPENGL_11)
{
free(vData.vertices);
free(vData.texcoords);
free(vData.normals);
free(vData.colors);
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}
return model;
}
// Load a map image as a 3d model (cubes based)
Model LoadCubicmap(Image cubicmap)
{
VertexData vData;
Color *cubicmapPixels = GetImageData(cubicmap);
// Map cube size will be 1.0
float mapCubeSide = 1.0f;
int mapWidth = cubicmap.width * (int)mapCubeSide;
int mapHeight = cubicmap.height * (int)mapCubeSide;
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// NOTE: Max possible number of triangles numCubes * (12 triangles by cube)
int maxTriangles = cubicmap.width*cubicmap.height*12;
int vCounter = 0; // Used to count vertices
int tcCounter = 0; // Used to count texcoords
int nCounter = 0; // Used to count normals
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float w = mapCubeSide;
float h = mapCubeSide;
float h2 = mapCubeSide * 1.5; // TODO: Review walls height...
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Vector3 *mapVertices = (Vector3 *)malloc(maxTriangles * 3 * sizeof(Vector3));
Vector2 *mapTexcoords = (Vector2 *)malloc(maxTriangles * 3 * sizeof(Vector2));
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Vector3 *mapNormals = (Vector3 *)malloc(maxTriangles * 3 * sizeof(Vector3));
// Define the 6 normals of the cube, we will combine them accordingly later...
Vector3 n1 = { 1.0f, 0.0f, 0.0f };
Vector3 n2 = { -1.0f, 0.0f, 0.0f };
Vector3 n3 = { 0.0f, 1.0f, 0.0f };
Vector3 n4 = { 0.0f, -1.0f, 0.0f };
Vector3 n5 = { 0.0f, 0.0f, 1.0f };
Vector3 n6 = { 0.0f, 0.0f, -1.0f };
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// NOTE: We use texture rectangles to define different textures for top-bottom-front-back-right-left (6)
typedef struct RectangleF {
float x;
float y;
float width;
float height;
} RectangleF;
RectangleF rightTexUV = { 0, 0, 0.5, 0.5 };
RectangleF leftTexUV = { 0.5, 0, 0.5, 0.5 };
RectangleF frontTexUV = { 0, 0, 0.5, 0.5 };
RectangleF backTexUV = { 0.5, 0, 0.5, 0.5 };
RectangleF topTexUV = { 0, 0.5, 0.5, 0.5 };
RectangleF bottomTexUV = { 0.5, 0.5, 0.5, 0.5 };
for (int z = 0; z < mapHeight; z += mapCubeSide)
{
for (int x = 0; x < mapWidth; x += mapCubeSide)
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{
// Define the 8 vertex of the cube, we will combine them accordingly later...
Vector3 v1 = { x - w/2, h2, z - h/2 };
Vector3 v2 = { x - w/2, h2, z + h/2 };
Vector3 v3 = { x + w/2, h2, z + h/2 };
Vector3 v4 = { x + w/2, h2, z - h/2 };
Vector3 v5 = { x + w/2, 0, z - h/2 };
Vector3 v6 = { x - w/2, 0, z - h/2 };
Vector3 v7 = { x - w/2, 0, z + h/2 };
Vector3 v8 = { x + w/2, 0, z + h/2 };
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// We check pixel color to be WHITE, we will full cubes
if ((cubicmapPixels[z*cubicmap.width + x].r == 255) &&
(cubicmapPixels[z*cubicmap.width + x].g == 255) &&
(cubicmapPixels[z*cubicmap.width + x].b == 255))
{
// Define triangles (Checking Collateral Cubes!)
//----------------------------------------------
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// Define top triangles (2 tris, 6 vertex --> v1-v2-v3, v1-v3-v4)
mapVertices[vCounter] = v1;
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mapVertices[vCounter + 1] = v2;
mapVertices[vCounter + 2] = v3;
mapVertices[vCounter + 3] = v1;
mapVertices[vCounter + 4] = v3;
mapVertices[vCounter + 5] = v4;
vCounter += 6;
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mapNormals[nCounter] = n3;
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mapNormals[nCounter + 1] = n3;
mapNormals[nCounter + 2] = n3;
mapNormals[nCounter + 3] = n3;
mapNormals[nCounter + 4] = n3;
mapNormals[nCounter + 5] = n3;
nCounter += 6;
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mapTexcoords[tcCounter] = (Vector2){ topTexUV.x, topTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ topTexUV.x, topTexUV.y + topTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ topTexUV.x + topTexUV.width, topTexUV.y + topTexUV.height };
mapTexcoords[tcCounter + 3] = (Vector2){ topTexUV.x, topTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ topTexUV.x + topTexUV.width, topTexUV.y + topTexUV.height };
mapTexcoords[tcCounter + 5] = (Vector2){ topTexUV.x + topTexUV.width, topTexUV.y };
tcCounter += 6;
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// Define bottom triangles (2 tris, 6 vertex --> v6-v8-v7, v6-v5-v8)
mapVertices[vCounter] = v6;
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mapVertices[vCounter + 1] = v8;
mapVertices[vCounter + 2] = v7;
mapVertices[vCounter + 3] = v6;
mapVertices[vCounter + 4] = v5;
mapVertices[vCounter + 5] = v8;
vCounter += 6;
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mapNormals[nCounter] = n4;
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mapNormals[nCounter + 1] = n4;
mapNormals[nCounter + 2] = n4;
mapNormals[nCounter + 3] = n4;
mapNormals[nCounter + 4] = n4;
mapNormals[nCounter + 5] = n4;
nCounter += 6;
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mapTexcoords[tcCounter] = (Vector2){ bottomTexUV.x + bottomTexUV.width, bottomTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ bottomTexUV.x, bottomTexUV.y + bottomTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ bottomTexUV.x + bottomTexUV.width, bottomTexUV.y + bottomTexUV.height };
mapTexcoords[tcCounter + 3] = (Vector2){ bottomTexUV.x + bottomTexUV.width, bottomTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ bottomTexUV.x, bottomTexUV.y };
mapTexcoords[tcCounter + 5] = (Vector2){ bottomTexUV.x, bottomTexUV.y + bottomTexUV.height };
tcCounter += 6;
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if (((z < cubicmap.height - 1) &&
(cubicmapPixels[(z + 1)*cubicmap.width + x].r == 0) &&
(cubicmapPixels[(z + 1)*cubicmap.width + x].g == 0) &&
(cubicmapPixels[(z + 1)*cubicmap.width + x].b == 0)) || (z == cubicmap.height - 1))
{
// Define front triangles (2 tris, 6 vertex) --> v2 v7 v3, v3 v7 v8
// NOTE: Collateral occluded faces are not generated
mapVertices[vCounter] = v2;
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mapVertices[vCounter + 1] = v7;
mapVertices[vCounter + 2] = v3;
mapVertices[vCounter + 3] = v3;
mapVertices[vCounter + 4] = v7;
mapVertices[vCounter + 5] = v8;
vCounter += 6;
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mapNormals[nCounter] = n6;
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mapNormals[nCounter + 1] = n6;
mapNormals[nCounter + 2] = n6;
mapNormals[nCounter + 3] = n6;
mapNormals[nCounter + 4] = n6;
mapNormals[nCounter + 5] = n6;
nCounter += 6;
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mapTexcoords[tcCounter] = (Vector2){ frontTexUV.x, frontTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ frontTexUV.x, frontTexUV.y + frontTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ frontTexUV.x + frontTexUV.width, frontTexUV.y };
mapTexcoords[tcCounter + 3] = (Vector2){ frontTexUV.x + frontTexUV.width, frontTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ frontTexUV.x, frontTexUV.y + frontTexUV.height };
mapTexcoords[tcCounter + 5] = (Vector2){ frontTexUV.x + frontTexUV.width, frontTexUV.y + frontTexUV.height };
tcCounter += 6;
}
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if (((z > 0) &&
(cubicmapPixels[(z - 1)*cubicmap.width + x].r == 0) &&
(cubicmapPixels[(z - 1)*cubicmap.width + x].g == 0) &&
(cubicmapPixels[(z - 1)*cubicmap.width + x].b == 0)) || (z == 0))
{
// Define back triangles (2 tris, 6 vertex) --> v1 v5 v6, v1 v4 v5
// NOTE: Collateral occluded faces are not generated
mapVertices[vCounter] = v1;
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mapVertices[vCounter + 1] = v5;
mapVertices[vCounter + 2] = v6;
mapVertices[vCounter + 3] = v1;
mapVertices[vCounter + 4] = v4;
mapVertices[vCounter + 5] = v5;
vCounter += 6;
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mapNormals[nCounter] = n5;
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mapNormals[nCounter + 1] = n5;
mapNormals[nCounter + 2] = n5;
mapNormals[nCounter + 3] = n5;
mapNormals[nCounter + 4] = n5;
mapNormals[nCounter + 5] = n5;
nCounter += 6;
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mapTexcoords[tcCounter] = (Vector2){ backTexUV.x + backTexUV.width, backTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ backTexUV.x, backTexUV.y + backTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ backTexUV.x + backTexUV.width, backTexUV.y + backTexUV.height };
mapTexcoords[tcCounter + 3] = (Vector2){ backTexUV.x + backTexUV.width, backTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ backTexUV.x, backTexUV.y };
mapTexcoords[tcCounter + 5] = (Vector2){ backTexUV.x, backTexUV.y + backTexUV.height };
tcCounter += 6;
}
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if (((x < cubicmap.width - 1) &&
(cubicmapPixels[z*cubicmap.width + (x + 1)].r == 0) &&
(cubicmapPixels[z*cubicmap.width + (x + 1)].g == 0) &&
(cubicmapPixels[z*cubicmap.width + (x + 1)].b == 0)) || (x == cubicmap.width - 1))
{
// Define right triangles (2 tris, 6 vertex) --> v3 v8 v4, v4 v8 v5
// NOTE: Collateral occluded faces are not generated
mapVertices[vCounter] = v3;
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mapVertices[vCounter + 1] = v8;
mapVertices[vCounter + 2] = v4;
mapVertices[vCounter + 3] = v4;
mapVertices[vCounter + 4] = v8;
mapVertices[vCounter + 5] = v5;
vCounter += 6;
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mapNormals[nCounter] = n1;
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mapNormals[nCounter + 1] = n1;
mapNormals[nCounter + 2] = n1;
mapNormals[nCounter + 3] = n1;
mapNormals[nCounter + 4] = n1;
mapNormals[nCounter + 5] = n1;
nCounter += 6;
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mapTexcoords[tcCounter] = (Vector2){ rightTexUV.x, rightTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ rightTexUV.x, rightTexUV.y + rightTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ rightTexUV.x + rightTexUV.width, rightTexUV.y };
mapTexcoords[tcCounter + 3] = (Vector2){ rightTexUV.x + rightTexUV.width, rightTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ rightTexUV.x, rightTexUV.y + rightTexUV.height };
mapTexcoords[tcCounter + 5] = (Vector2){ rightTexUV.x + rightTexUV.width, rightTexUV.y + rightTexUV.height };
tcCounter += 6;
}
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if (((x > 0) &&
(cubicmapPixels[z*cubicmap.width + (x - 1)].r == 0) &&
(cubicmapPixels[z*cubicmap.width + (x - 1)].g == 0) &&
(cubicmapPixels[z*cubicmap.width + (x - 1)].b == 0)) || (x == 0))
{
// Define left triangles (2 tris, 6 vertex) --> v1 v7 v2, v1 v6 v7
// NOTE: Collateral occluded faces are not generated
mapVertices[vCounter] = v1;
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mapVertices[vCounter + 1] = v7;
mapVertices[vCounter + 2] = v2;
mapVertices[vCounter + 3] = v1;
mapVertices[vCounter + 4] = v6;
mapVertices[vCounter + 5] = v7;
vCounter += 6;
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mapNormals[nCounter] = n2;
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mapNormals[nCounter + 1] = n2;
mapNormals[nCounter + 2] = n2;
mapNormals[nCounter + 3] = n2;
mapNormals[nCounter + 4] = n2;
mapNormals[nCounter + 5] = n2;
nCounter += 6;
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mapTexcoords[tcCounter] = (Vector2){ leftTexUV.x, leftTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ leftTexUV.x + leftTexUV.width, leftTexUV.y + leftTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ leftTexUV.x + leftTexUV.width, leftTexUV.y };
mapTexcoords[tcCounter + 3] = (Vector2){ leftTexUV.x, leftTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ leftTexUV.x, leftTexUV.y + leftTexUV.height };
mapTexcoords[tcCounter + 5] = (Vector2){ leftTexUV.x + leftTexUV.width, leftTexUV.y + leftTexUV.height };
tcCounter += 6;
}
}
// We check pixel color to be BLACK, we will only draw floor and roof
else if ((cubicmapPixels[z*cubicmap.width + x].r == 0) &&
(cubicmapPixels[z*cubicmap.width + x].g == 0) &&
(cubicmapPixels[z*cubicmap.width + x].b == 0))
{
// Define top triangles (2 tris, 6 vertex --> v1-v2-v3, v1-v3-v4)
mapVertices[vCounter] = v1;
mapVertices[vCounter + 1] = v3;
mapVertices[vCounter + 2] = v2;
mapVertices[vCounter + 3] = v1;
mapVertices[vCounter + 4] = v4;
mapVertices[vCounter + 5] = v3;
vCounter += 6;
mapNormals[nCounter] = n4;
mapNormals[nCounter + 1] = n4;
mapNormals[nCounter + 2] = n4;
mapNormals[nCounter + 3] = n4;
mapNormals[nCounter + 4] = n4;
mapNormals[nCounter + 5] = n4;
nCounter += 6;
mapTexcoords[tcCounter] = (Vector2){ topTexUV.x, topTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ topTexUV.x + topTexUV.width, topTexUV.y + topTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ topTexUV.x, topTexUV.y + topTexUV.height };
mapTexcoords[tcCounter + 3] = (Vector2){ topTexUV.x, topTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ topTexUV.x + topTexUV.width, topTexUV.y };
mapTexcoords[tcCounter + 5] = (Vector2){ topTexUV.x + topTexUV.width, topTexUV.y + topTexUV.height };
tcCounter += 6;
// Define bottom triangles (2 tris, 6 vertex --> v6-v8-v7, v6-v5-v8)
mapVertices[vCounter] = v6;
mapVertices[vCounter + 1] = v7;
mapVertices[vCounter + 2] = v8;
mapVertices[vCounter + 3] = v6;
mapVertices[vCounter + 4] = v8;
mapVertices[vCounter + 5] = v5;
vCounter += 6;
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mapNormals[nCounter] = n3;
mapNormals[nCounter + 1] = n3;
mapNormals[nCounter + 2] = n3;
mapNormals[nCounter + 3] = n3;
mapNormals[nCounter + 4] = n3;
mapNormals[nCounter + 5] = n3;
nCounter += 6;
mapTexcoords[tcCounter] = (Vector2){ bottomTexUV.x + bottomTexUV.width, bottomTexUV.y };
mapTexcoords[tcCounter + 1] = (Vector2){ bottomTexUV.x + bottomTexUV.width, bottomTexUV.y + bottomTexUV.height };
mapTexcoords[tcCounter + 2] = (Vector2){ bottomTexUV.x, bottomTexUV.y + bottomTexUV.height };
mapTexcoords[tcCounter + 3] = (Vector2){ bottomTexUV.x + bottomTexUV.width, bottomTexUV.y };
mapTexcoords[tcCounter + 4] = (Vector2){ bottomTexUV.x, bottomTexUV.y + bottomTexUV.height };
mapTexcoords[tcCounter + 5] = (Vector2){ bottomTexUV.x, bottomTexUV.y };
tcCounter += 6;
}
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}
}
// Move data from mapVertices temp arays to vertices float array
vData.vertexCount = vCounter;
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vData.vertices = (float *)malloc(vData.vertexCount*3*sizeof(float));
vData.normals = (float *)malloc(vData.vertexCount*3*sizeof(float));
vData.texcoords = (float *)malloc(vData.vertexCount*2*sizeof(float));
vData.colors = (unsigned char *)malloc(vData.vertexCount*4*sizeof(unsigned char)); // Not used...
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// Fill color data
// NOTE: Not used any more... just one plain color defined at DrawModel()
for (int i = 0; i < (4*vData.vertexCount); i++) vData.colors[i] = 255;
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int fCounter = 0;
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// Move vertices data
for (int i = 0; i < vCounter; i++)
{
vData.vertices[fCounter] = mapVertices[i].x;
vData.vertices[fCounter + 1] = mapVertices[i].y;
vData.vertices[fCounter + 2] = mapVertices[i].z;
fCounter += 3;
}
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fCounter = 0;
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// Move normals data
for (int i = 0; i < nCounter; i++)
{
vData.normals[fCounter] = mapNormals[i].x;
vData.normals[fCounter + 1] = mapNormals[i].y;
vData.normals[fCounter + 2] = mapNormals[i].z;
fCounter += 3;
}
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fCounter = 0;
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// Move texcoords data
for (int i = 0; i < tcCounter; i++)
{
vData.texcoords[fCounter] = mapTexcoords[i].x;
vData.texcoords[fCounter + 1] = mapTexcoords[i].y;
fCounter += 2;
}
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free(mapVertices);
free(mapNormals);
free(mapTexcoords);
free(cubicmapPixels);
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// NOTE: At this point we have all vertex, texcoord, normal data for the model in vData struct
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Model model = rlglLoadModel(vData);
// Now that vertex data is uploaded to GPU, we can free arrays
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// NOTE: We don't need CPU vertex data on OpenGL 3.3 or ES2
if (rlGetVersion() != OPENGL_11)
{
free(vData.vertices);
free(vData.texcoords);
free(vData.normals);
free(vData.colors);
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}
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return model;
}
// Unload 3d model from memory
void UnloadModel(Model model)
{
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if (rlGetVersion() == OPENGL_11)
{
free(model.mesh.vertices);
free(model.mesh.texcoords);
free(model.mesh.normals);
}
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rlDeleteBuffers(model.mesh.vboId[0]);
rlDeleteBuffers(model.mesh.vboId[1]);
rlDeleteBuffers(model.mesh.vboId[2]);
rlDeleteVertexArrays(model.mesh.vaoId);
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if (model.mesh.vaoId > 0) TraceLog(INFO, "[VAO ID %i] Unloaded model data from VRAM (GPU)", model.mesh.vaoId);
else TraceLog(INFO, "[VBO ID %i][VBO ID %i][VBO ID %i] Unloaded model data from VRAM (GPU)", model.mesh.vboId[0], model.mesh.vboId[1], model.mesh.vboId[2]);
}
// Link a texture to a model
void SetModelTexture(Model *model, Texture2D texture)
{
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if (texture.id <= 0)
{
// Use default white texture (use mesh color)
model->texture.id = whiteTexture; // OpenGL 1.1
model->shader.texDiffuseId = whiteTexture; // OpenGL 3.3 / ES 2.0
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}
else
{
model->texture = texture;
model->shader.texDiffuseId = texture.id;
}
}
// Draw a model (with texture if set)
void DrawModel(Model model, Vector3 position, float scale, Color tint)
{
Vector3 vScale = { scale, scale, scale };
Vector3 rotationAxis = { 0, 0, 0 };
DrawModelEx(model, position, 0.0f, rotationAxis, vScale, tint);
}
// Draw a model with extended parameters
void DrawModelEx(Model model, Vector3 position, float rotationAngle, Vector3 rotationAxis, Vector3 scale, Color tint)
{
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// NOTE: Rotation must be provided in degrees, it's converted to radians inside rlglDrawModel()
rlglDrawModel(model, position, rotationAngle, rotationAxis, scale, tint, false);
}
// Draw a model wires (with texture if set)
void DrawModelWires(Model model, Vector3 position, float scale, Color color)
{
Vector3 vScale = { scale, scale, scale };
Vector3 rotationAxis = { 0, 0, 0 };
rlglDrawModel(model, position, 0.0f, rotationAxis, vScale, color, true);
}
// Draw a model wires (with texture if set) with extended parameters
void DrawModelWiresEx(Model model, Vector3 position, float rotationAngle, Vector3 rotationAxis, Vector3 scale, Color tint)
{
// NOTE: Rotation must be provided in degrees, it's converted to radians inside rlglDrawModel()
rlglDrawModel(model, position, rotationAngle, rotationAxis, scale, tint, true);
}
// Draw a billboard
void DrawBillboard(Camera camera, Texture2D texture, Vector3 center, float size, Color tint)
{
// NOTE: Billboard size will maintain texture aspect ratio, size will be billboard width
Vector2 sizeRatio = { size, size * (float)texture.height/texture.width };
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Matrix viewMatrix = MatrixLookAt(camera.position, camera.target, camera.up);
MatrixTranspose(&viewMatrix);
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Vector3 right = { viewMatrix.m0, viewMatrix.m4, viewMatrix.m8 };
//Vector3 up = { viewMatrix.m1, viewMatrix.m5, viewMatrix.m9 };
// NOTE: Billboard locked to axis-Y
Vector3 up = { 0, 1, 0 };
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/*
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a-------b
| |
| * |
| |
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d-------c
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*/
VectorScale(&right, sizeRatio.x/2);
VectorScale(&up, sizeRatio.y/2);
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Vector3 p1 = VectorAdd(right, up);
Vector3 p2 = VectorSubtract(right, up);
Vector3 a = VectorSubtract(center, p2);
Vector3 b = VectorAdd(center, p1);
Vector3 c = VectorAdd(center, p2);
Vector3 d = VectorSubtract(center, p1);
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rlEnableTexture(texture.id);
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rlBegin(RL_QUADS);
rlColor4ub(tint.r, tint.g, tint.b, tint.a);
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rlTexCoord2f(0.0f, 0.0f); rlVertex3f(a.x, a.y, a.z);
rlTexCoord2f(0.0f, 1.0f); rlVertex3f(d.x, d.y, d.z);
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rlTexCoord2f(1.0f, 1.0f); rlVertex3f(c.x, c.y, c.z);
rlTexCoord2f(1.0f, 0.0f); rlVertex3f(b.x, b.y, b.z);
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rlEnd();
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rlDisableTexture();
}
// Draw a billboard (part of a texture defined by a rectangle)
void DrawBillboardRec(Camera camera, Texture2D texture, Rectangle sourceRec, Vector3 center, float size, Color tint)
{
// NOTE: Billboard size will maintain sourceRec aspect ratio, size will represent billboard width
Vector2 sizeRatio = { size, size * (float)sourceRec.height/sourceRec.width };
Matrix viewMatrix = MatrixLookAt(camera.position, camera.target, camera.up);
MatrixTranspose(&viewMatrix);
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Vector3 right = { viewMatrix.m0, viewMatrix.m4, viewMatrix.m8 };
Vector3 up = { viewMatrix.m1, viewMatrix.m5, viewMatrix.m9 };
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/*
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a-------b
| |
| * |
| |
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d-------c
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*/
VectorScale(&right, sizeRatio.x/2);
VectorScale(&up, sizeRatio.y/2);
Vector3 p1 = VectorAdd(right, up);
Vector3 p2 = VectorSubtract(right, up);
Vector3 a = VectorSubtract(center, p2);
Vector3 b = VectorAdd(center, p1);
Vector3 c = VectorAdd(center, p2);
Vector3 d = VectorSubtract(center, p1);
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rlEnableTexture(texture.id);
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rlBegin(RL_QUADS);
rlColor4ub(tint.r, tint.g, tint.b, tint.a);
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// Bottom-left corner for texture and quad
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rlTexCoord2f((float)sourceRec.x / texture.width, (float)sourceRec.y / texture.height);
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rlVertex3f(a.x, a.y, a.z);
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// Top-left corner for texture and quad
rlTexCoord2f((float)sourceRec.x / texture.width, (float)(sourceRec.y + sourceRec.height) / texture.height);
rlVertex3f(d.x, d.y, d.z);
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// Top-right corner for texture and quad
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rlTexCoord2f((float)(sourceRec.x + sourceRec.width) / texture.width, (float)(sourceRec.y + sourceRec.height) / texture.height);
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rlVertex3f(c.x, c.y, c.z);
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// Bottom-right corner for texture and quad
rlTexCoord2f((float)(sourceRec.x + sourceRec.width) / texture.width, (float)sourceRec.y / texture.height);
rlVertex3f(b.x, b.y, b.z);
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rlEnd();
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rlDisableTexture();
}
// Detect collision between two spheres
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bool CheckCollisionSpheres(Vector3 centerA, float radiusA, Vector3 centerB, float radiusB)
{
bool collision = false;
float dx = centerA.x - centerB.x; // X distance between centers
float dy = centerA.y - centerB.y; // Y distance between centers
float dz = centerA.z - centerB.z; // Y distance between centers
float distance = sqrt(dx*dx + dy*dy + dz*dz); // Distance between centers
if (distance <= (radiusA + radiusB)) collision = true;
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return collision;
}
// Detect collision between two boxes
// NOTE: Boxes are defined by two points minimum and maximum
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bool CheckCollisionBoxes(Vector3 minBBox1, Vector3 maxBBox1, Vector3 minBBox2, Vector3 maxBBox2)
{
bool collision = true;
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if ((maxBBox1.x >= minBBox2.x) && (minBBox1.x <= maxBBox2.x))
{
if ((maxBBox1.y < minBBox2.y) || (minBBox1.y > maxBBox2.y)) collision = false;
if ((maxBBox1.z < minBBox2.z) || (minBBox1.z > maxBBox2.z)) collision = false;
}
else collision = false;
return collision;
}
// Detect collision between box and sphere
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bool CheckCollisionBoxSphere(Vector3 minBBox, Vector3 maxBBox, Vector3 centerSphere, float radiusSphere)
{
bool collision = false;
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if ((centerSphere.x - minBBox.x > radiusSphere) && (centerSphere.y - minBBox.y > radiusSphere) && (centerSphere.z - minBBox.z > radiusSphere) &&
(maxBBox.x - centerSphere.x > radiusSphere) && (maxBBox.y - centerSphere.y > radiusSphere) && (maxBBox.z - centerSphere.z > radiusSphere))
{
collision = true;
}
else
{
float dmin = 0;
if (centerSphere.x - minBBox.x <= radiusSphere) dmin += (centerSphere.x - minBBox.x)*(centerSphere.x - minBBox.x);
else if (maxBBox.x - centerSphere.x <= radiusSphere) dmin += (centerSphere.x - maxBBox.x)*(centerSphere.x - maxBBox.x);
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if (centerSphere.y - minBBox.y <= radiusSphere) dmin += (centerSphere.y - minBBox.y)*(centerSphere.y - minBBox.y);
else if (maxBBox.y - centerSphere.y <= radiusSphere) dmin += (centerSphere.y - maxBBox.y)*(centerSphere.y - maxBBox.y);
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if (centerSphere.z - minBBox.z <= radiusSphere) dmin += (centerSphere.z - minBBox.z)*(centerSphere.z - minBBox.z);
else if (maxBBox.z - centerSphere.z <= radiusSphere) dmin += (centerSphere.z - maxBBox.z)*(centerSphere.z - maxBBox.z);
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if (dmin <= radiusSphere*radiusSphere) collision = true;
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}
return collision;
}
// TODO: Useful function to check collision area?
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//BoundingBox GetCollisionArea(BoundingBox box1, BoundingBox box2)
// Detect and resolve cubicmap collisions
// NOTE: player position (or camera) is modified inside this function
Vector3 ResolveCollisionCubicmap(Image cubicmap, Vector3 mapPosition, Vector3 *playerPosition, float radius)
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{
Color *cubicmapPixels = GetImageData(cubicmap);
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// Detect the cell where the player is located
Vector3 impactDirection = { 0, 0, 0 };
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int locationCellX = 0;
int locationCellY = 0;
locationCellX = floor(playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE);
locationCellY = floor(playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE);
if (locationCellX >= 0 && locationCellY >= 0 && locationCellX < cubicmap.width && locationCellY < cubicmap.height)
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{
// Multiple Axis --------------------------------------------------------------------------------------------
// Axis x-, y-
if (locationCellX > 0 && locationCellY > 0)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX - 1)].r != 0) &&
(cubicmapPixels[(locationCellY - 1) * cubicmap.width + (locationCellX)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX < radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY < radius))
{
playerPosition->x = locationCellX + mapPosition.x - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
playerPosition->z = locationCellY + mapPosition.z - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 1, 0, 1};
}
}
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}
// Axis x-, y+
if (locationCellX > 0 && locationCellY < cubicmap.height - 1)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX - 1)].r != 0) &&
(cubicmapPixels[(locationCellY + 1) * cubicmap.width + (locationCellX)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX < radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY > 1 - radius))
{
playerPosition->x = locationCellX + mapPosition.x - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
playerPosition->z = locationCellY + mapPosition.z + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 1, 0, 1};
}
}
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}
// Axis x+, y-
if (locationCellX < cubicmap.width - 1 && locationCellY > 0)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX + 1)].r != 0) &&
(cubicmapPixels[(locationCellY - 1) * cubicmap.width + (locationCellX)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX > 1 - radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY < radius))
{
playerPosition->x = locationCellX + mapPosition.x + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
playerPosition->z = locationCellY + mapPosition.z - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 1, 0, 1};
}
}
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}
// Axis x+, y+
if (locationCellX < cubicmap.width - 1 && locationCellY < cubicmap.height - 1)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX + 1)].r != 0) &&
(cubicmapPixels[(locationCellY + 1) * cubicmap.width + (locationCellX)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX > 1 - radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY > 1 - radius))
{
playerPosition->x = locationCellX + mapPosition.x + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
playerPosition->z = locationCellY + mapPosition.z + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 1, 0, 1};
}
}
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}
// Single Axis ---------------------------------------------------------------------------------------------------
// Axis x-
if (locationCellX > 0)
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{
if (cubicmapPixels[locationCellY * cubicmap.width + (locationCellX - 1)].r != 0)
{
if ((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX < radius)
{
playerPosition->x = locationCellX + mapPosition.x - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 1, 0, 0};
}
}
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}
// Axis x+
if (locationCellX < cubicmap.width - 1)
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{
if (cubicmapPixels[locationCellY * cubicmap.width + (locationCellX + 1)].r != 0)
{
if ((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX > 1 - radius)
{
playerPosition->x = locationCellX + mapPosition.x + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 1, 0, 0};
}
}
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}
// Axis y-
if (locationCellY > 0)
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{
if (cubicmapPixels[(locationCellY - 1) * cubicmap.width + (locationCellX)].r != 0)
{
if ((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY < radius)
{
playerPosition->z = locationCellY + mapPosition.z - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 0, 0, 1};
}
}
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}
// Axis y+
if (locationCellY < cubicmap.height - 1)
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{
if (cubicmapPixels[(locationCellY + 1) * cubicmap.width + (locationCellX)].r != 0)
{
if ((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY > 1 - radius)
{
playerPosition->z = locationCellY + mapPosition.z + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
impactDirection = (Vector3) { 0, 0, 1};
}
}
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}
// Diagonals -------------------------------------------------------------------------------------------------------
// Axis x-, y-
if (locationCellX > 0 && locationCellY > 0)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX - 1)].r == 0) &&
(cubicmapPixels[(locationCellY - 1) * cubicmap.width + (locationCellX)].r == 0) &&
(cubicmapPixels[(locationCellY - 1) * cubicmap.width + (locationCellX - 1)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX < radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY < radius))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX) > ((playerPosition->z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY)) playerPosition->x = locationCellX + mapPosition.x - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
else playerPosition->z = locationCellY + mapPosition.z - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
// Return ricochet
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX < radius / 3) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY < radius / 3))
{
impactDirection = (Vector3) { 1, 0, 1};
}
}
}
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}
// Axis x-, y+
if (locationCellX > 0 && locationCellY < cubicmap.height - 1)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX - 1)].r == 0) &&
(cubicmapPixels[(locationCellY + 1) * cubicmap.width + (locationCellX)].r == 0) &&
(cubicmapPixels[(locationCellY + 1) * cubicmap.width + (locationCellX - 1)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX < radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY > 1 - radius))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX) > (1 - ((playerPosition->z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY))) playerPosition->x = locationCellX + mapPosition.x - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
else playerPosition->z = locationCellY + mapPosition.z + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
// Return ricochet
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX < radius / 3) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY > 1 - radius / 3))
{
impactDirection = (Vector3) { 1, 0, 1};
}
}
}
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}
// Axis x+, y-
if (locationCellX < cubicmap.width - 1 && locationCellY > 0)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX + 1)].r == 0) &&
(cubicmapPixels[(locationCellY - 1) * cubicmap.width + (locationCellX)].r == 0) &&
(cubicmapPixels[(locationCellY - 1) * cubicmap.width + (locationCellX + 1)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX > 1 - radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY < radius))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX) < (1 - ((playerPosition->z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY))) playerPosition->x = locationCellX + mapPosition.x + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
else playerPosition->z = locationCellY + mapPosition.z - (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
// Return ricochet
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX > 1 - radius / 3) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY < radius / 3))
{
impactDirection = (Vector3) { 1, 0, 1};
}
}
}
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}
// Axis x+, y+
if (locationCellX < cubicmap.width - 1 && locationCellY < cubicmap.height - 1)
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{
if ((cubicmapPixels[locationCellY * cubicmap.width + (locationCellX + 1)].r == 0) &&
(cubicmapPixels[(locationCellY + 1) * cubicmap.width + (locationCellX)].r == 0) &&
(cubicmapPixels[(locationCellY + 1) * cubicmap.width + (locationCellX + 1)].r != 0))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX > 1 - radius) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY > 1 - radius))
{
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX) < ((playerPosition->z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY)) playerPosition->x = locationCellX + mapPosition.x + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
else playerPosition->z = locationCellY + mapPosition.z + (CUBIC_MAP_HALF_BLOCK_SIZE - radius);
// Return ricochet
if (((playerPosition->x - mapPosition.x + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellX > 1 - radius / 3) &&
((playerPosition->z - mapPosition.z + CUBIC_MAP_HALF_BLOCK_SIZE) - locationCellY > 1 - radius / 3))
{
impactDirection = (Vector3) { 1, 0, 1};
}
}
}
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}
}
// Floor collision
if (playerPosition->y <= radius)
{
playerPosition->y = radius + 0.01;
impactDirection = (Vector3) { impactDirection.x, 1, impactDirection.z};
}
// Roof collision
else if (playerPosition->y >= 1.5 - radius)
{
playerPosition->y = (1.5 - radius) - 0.01;
impactDirection = (Vector3) { impactDirection.x, 1, impactDirection.z};
}
free(cubicmapPixels);
return impactDirection;
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}
//----------------------------------------------------------------------------------
// Module specific Functions Definition
//----------------------------------------------------------------------------------
// Get current vertex y altitude (proportional to pixel colors in grayscale)
static float GetHeightValue(Color pixel)
{
return (((float)pixel.r + (float)pixel.g + (float)pixel.b)/3);
}
// Load OBJ mesh data
static VertexData LoadOBJ(const char *fileName)
{
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VertexData vData = { 0 };
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char dataType;
char comments[200];
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int numVertex = 0;
int numNormals = 0;
int numTexCoords = 0;
int numTriangles = 0;
FILE *objFile;
objFile = fopen(fileName, "rt");
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if (objFile == NULL)
{
TraceLog(WARNING, "[%s] OBJ file could not be opened", fileName);
return vData;
}
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// First reading pass: Get numVertex, numNormals, numTexCoords, numTriangles
// NOTE: vertex, texcoords and normals could be optimized (to be used indexed on faces definition)
// NOTE: faces MUST be defined as TRIANGLES, not QUADS
while(!feof(objFile))
{
fscanf(objFile, "%c", &dataType);
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switch(dataType)
{
case '#': // Comments
case 'o': // Object name (One OBJ file can contain multible named meshes)
case 'g': // Group name
case 's': // Smoothing level
case 'm': // mtllib [external .mtl file name]
case 'u': // usemtl [material name]
{
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fgets(comments, 200, objFile);
} break;
case 'v':
{
fscanf(objFile, "%c", &dataType);
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if (dataType == 't') // Read texCoord
{
numTexCoords++;
fgets(comments, 200, objFile);
}
else if (dataType == 'n') // Read normals
{
numNormals++;
fgets(comments, 200, objFile);
}
else // Read vertex
{
numVertex++;
fgets(comments, 200, objFile);
}
} break;
case 'f':
{
numTriangles++;
fgets(comments, 200, objFile);
} break;
default: break;
}
}
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TraceLog(DEBUG, "[%s] Model num vertices: %i", fileName, numVertex);
TraceLog(DEBUG, "[%s] Model num texcoords: %i", fileName, numTexCoords);
TraceLog(DEBUG, "[%s] Model num normals: %i", fileName, numNormals);
TraceLog(DEBUG, "[%s] Model num triangles: %i", fileName, numTriangles);
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// Once we know the number of vertices to store, we create required arrays
Vector3 *midVertices = (Vector3 *)malloc(numVertex*sizeof(Vector3));
Vector3 *midNormals = NULL;
if (numNormals > 0) midNormals = (Vector3 *)malloc(numNormals*sizeof(Vector3));
Vector2 *midTexCoords = NULL;
if (numTexCoords > 0) midTexCoords = (Vector2 *)malloc(numTexCoords*sizeof(Vector2));
int countVertex = 0;
int countNormals = 0;
int countTexCoords = 0;
rewind(objFile); // Return to the beginning of the file, to read again
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// Second reading pass: Get vertex data to fill intermediate arrays
// NOTE: This second pass is required in case of multiple meshes defined in same OBJ
// TODO: Consider that different meshes can have different vertex data available (position, texcoords, normals)
while(!feof(objFile))
{
fscanf(objFile, "%c", &dataType);
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switch(dataType)
{
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case '#': case 'o': case 'g': case 's': case 'm': case 'u': case 'f': fgets(comments, 200, objFile); break;
case 'v':
{
fscanf(objFile, "%c", &dataType);
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if (dataType == 't') // Read texCoord
{
float useless = 0;
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fscanf(objFile, "%f %f %f", &midTexCoords[countTexCoords].x, &midTexCoords[countTexCoords].y, &useless);
countTexCoords++;
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fscanf(objFile, "%c", &dataType);
}
else if (dataType == 'n') // Read normals
{
fscanf(objFile, "%f %f %f", &midNormals[countNormals].x, &midNormals[countNormals].y, &midNormals[countNormals].z );
countNormals++;
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fscanf(objFile, "%c", &dataType);
}
else // Read vertex
{
fscanf(objFile, "%f %f %f", &midVertices[countVertex].x, &midVertices[countVertex].y, &midVertices[countVertex].z );
countVertex++;
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fscanf(objFile, "%c", &dataType);
}
} break;
default: break;
}
}
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// At this point all vertex data (v, vt, vn) has been gathered on midVertices, midTexCoords, midNormals
// Now we can organize that data into our VertexData struct
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vData.vertexCount = numTriangles*3;
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// Additional arrays to store vertex data as floats
vData.vertices = (float *)malloc(vData.vertexCount*3*sizeof(float));
vData.texcoords = (float *)malloc(vData.vertexCount*2*sizeof(float));
vData.normals = (float *)malloc(vData.vertexCount*3*sizeof(float));
vData.colors = (unsigned char *)malloc(vData.vertexCount*4*sizeof(unsigned char));
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int vCounter = 0; // Used to count vertices float by float
int tcCounter = 0; // Used to count texcoords float by float
int nCounter = 0; // Used to count normals float by float
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int vNum[3], vtNum[3], vnNum[3]; // Used to store triangle indices for v, vt, vn
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rewind(objFile); // Return to the beginning of the file, to read again
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if (numNormals == 0) TraceLog(INFO, "[%s] No normals data on OBJ, normals will be generated from faces data", fileName);
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// Third reading pass: Get faces (triangles) data and fill VertexArray
while(!feof(objFile))
{
fscanf(objFile, "%c", &dataType);
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switch(dataType)
{
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case '#': case 'o': case 'g': case 's': case 'm': case 'u': case 'v': fgets(comments, 200, objFile); break;
case 'f':
{
// NOTE: It could be that OBJ does not have normals or texcoords defined!
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if ((numNormals == 0) && (numTexCoords == 0)) fscanf(objFile, "%i %i %i", &vNum[0], &vNum[1], &vNum[2]);
else if (numNormals == 0) fscanf(objFile, "%i/%i %i/%i %i/%i", &vNum[0], &vtNum[0], &vNum[1], &vtNum[1], &vNum[2], &vtNum[2]);
else fscanf(objFile, "%i/%i/%i %i/%i/%i %i/%i/%i", &vNum[0], &vtNum[0], &vnNum[0], &vNum[1], &vtNum[1], &vnNum[1], &vNum[2], &vtNum[2], &vnNum[2]);
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vData.vertices[vCounter] = midVertices[vNum[0]-1].x;
vData.vertices[vCounter + 1] = midVertices[vNum[0]-1].y;
vData.vertices[vCounter + 2] = midVertices[vNum[0]-1].z;
vCounter += 3;
vData.vertices[vCounter] = midVertices[vNum[1]-1].x;
vData.vertices[vCounter + 1] = midVertices[vNum[1]-1].y;
vData.vertices[vCounter + 2] = midVertices[vNum[1]-1].z;
vCounter += 3;
vData.vertices[vCounter] = midVertices[vNum[2]-1].x;
vData.vertices[vCounter + 1] = midVertices[vNum[2]-1].y;
vData.vertices[vCounter + 2] = midVertices[vNum[2]-1].z;
vCounter += 3;
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if (numNormals > 0)
{
vData.normals[nCounter] = midNormals[vnNum[0]-1].x;
vData.normals[nCounter + 1] = midNormals[vnNum[0]-1].y;
vData.normals[nCounter + 2] = midNormals[vnNum[0]-1].z;
nCounter += 3;
vData.normals[nCounter] = midNormals[vnNum[1]-1].x;
vData.normals[nCounter + 1] = midNormals[vnNum[1]-1].y;
vData.normals[nCounter + 2] = midNormals[vnNum[1]-1].z;
nCounter += 3;
vData.normals[nCounter] = midNormals[vnNum[2]-1].x;
vData.normals[nCounter + 1] = midNormals[vnNum[2]-1].y;
vData.normals[nCounter + 2] = midNormals[vnNum[2]-1].z;
nCounter += 3;
}
else
{
// If normals not defined, they are calculated from the 3 vertices [N = (V2 - V1) x (V3 - V1)]
Vector3 norm = VectorCrossProduct(VectorSubtract(midVertices[vNum[1]-1], midVertices[vNum[0]-1]), VectorSubtract(midVertices[vNum[2]-1], midVertices[vNum[0]-1]));
VectorNormalize(&norm);
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vData.normals[nCounter] = norm.x;
vData.normals[nCounter + 1] = norm.y;
vData.normals[nCounter + 2] = norm.z;
nCounter += 3;
vData.normals[nCounter] = norm.x;
vData.normals[nCounter + 1] = norm.y;
vData.normals[nCounter + 2] = norm.z;
nCounter += 3;
vData.normals[nCounter] = norm.x;
vData.normals[nCounter + 1] = norm.y;
vData.normals[nCounter + 2] = norm.z;
nCounter += 3;
}
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if (numTexCoords > 0)
{
// NOTE: If using negative texture coordinates with a texture filter of GL_CLAMP_TO_EDGE doesn't work!
// NOTE: Texture coordinates are Y flipped upside-down
vData.texcoords[tcCounter] = midTexCoords[vtNum[0]-1].x;
vData.texcoords[tcCounter + 1] = 1.0f - midTexCoords[vtNum[0]-1].y;
tcCounter += 2;
vData.texcoords[tcCounter] = midTexCoords[vtNum[1]-1].x;
vData.texcoords[tcCounter + 1] = 1.0f - midTexCoords[vtNum[1]-1].y;
tcCounter += 2;
vData.texcoords[tcCounter] = midTexCoords[vtNum[2]-1].x;
vData.texcoords[tcCounter + 1] = 1.0f - midTexCoords[vtNum[2]-1].y;
tcCounter += 2;
}
} break;
default: break;
}
}
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fclose(objFile);
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// Security check, just in case no normals or no texcoords defined in OBJ
if (numTexCoords == 0) for (int i = 0; i < (2*vData.vertexCount); i++) vData.texcoords[i] = 0.0f;
// NOTE: We set all vertex colors to white
// NOTE: Not used any more... just one plain color defined at DrawModel()
for (int i = 0; i < (4*vData.vertexCount); i++) vData.colors[i] = 255;
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// Now we can free temp mid* arrays
free(midVertices);
free(midNormals);
free(midTexCoords);
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// NOTE: At this point we have all vertex, texcoord, normal data for the model in vData struct
TraceLog(INFO, "[%s] Model loaded successfully in RAM (CPU)", fileName);
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return vData;
}