joastbg/opengl2D.cpp

## opengl2D.cpp
#include <cstdlib>
#include <iostream>
#include <cstdio>
#include <cmath>
#include <thread>
#include <string>
#include <chrono>

#include <GL/glut.h>
#include <GL/glu.h>
#include <GL/gl.h>

#include <math.h>
#include <stdlib.h>
#include <stdio.h>
 struct Vec {        // Usage: time ./smallpt 5000 && xv image.ppm
   double x, y, z;                  // position, also color (r,g,b)
   Vec(double x_=0, double y_=0, double z_=0){ x=x_; y=y_; z=z_; }
   Vec operator+(const Vec &b) const { return Vec(x+b.x,y+b.y,z+b.z); }
   Vec operator-(const Vec &b) const { return Vec(x-b.x,y-b.y,z-b.z); }
   Vec operator*(double b) const { return Vec(x*b,y*b,z*b); }
   Vec mult(const Vec &b) const { return Vec(x*b.x,y*b.y,z*b.z); }
   Vec& norm(){ return *this = *this * (1/sqrt(x*x+y*y+z*z)); }
   double dot(const Vec &b) const { return x*b.x+y*b.y+z*b.z; } // cross:
   Vec operator%(Vec&b){return Vec(y*b.z-z*b.y,z*b.x-x*b.z,x*b.y-y*b.x);}
 };
 struct Ray { Vec o, d; Ray(Vec o_, Vec d_) : o(o_), d(d_) {} };
 enum Refl_t { DIFF, SPEC, REFR };  // material types, used in radiance()
 struct Sphere {
   double rad;       // radius
   Vec p, e, c;      // position, emission, color
   Refl_t refl;      // reflection type (DIFFuse, SPECular, REFRactive)
   Sphere(double rad_, Vec p_, Vec e_, Vec c_, Refl_t refl_):
     rad(rad_), p(p_), e(e_), c(c_), refl(refl_) {}
   double intersect(const Ray &r) const { // returns distance, 0 if nohit
     Vec op = p-r.o; // Solve t^2*d.d + 2*t*(o-p).d + (o-p).(o-p)-R^2 = 0
     double t, eps=1e-4, b=op.dot(r.d), det=b*b-op.dot(op)+rad*rad;
     if (det<0) return 0; else det=sqrt(det);
     return (t=b-det)>eps ? t : ((t=b+det)>eps ? t : 0);
   }
 };
 Sphere spheres[] = {//Scene: radius, position, emission, color, material
   Sphere(1e5, Vec( 1e5+1,40.8,81.6), Vec(),Vec(.75,.25,.25),DIFF),//Left
   Sphere(1e5, Vec(-1e5+99,40.8,81.6),Vec(),Vec(.25,.25,.75),DIFF),//Rght
   Sphere(1e5, Vec(50,40.8, 1e5),     Vec(),Vec(.75,.75,.75),DIFF),//Back
   Sphere(1e5, Vec(50,40.8,-1e5+170), Vec(),Vec(),           DIFF),//Frnt
   Sphere(1e5, Vec(50, 1e5, 81.6),    Vec(),Vec(.75,.75,.75),DIFF),//Botm
   Sphere(1e5, Vec(50,-1e5+81.6,81.6),Vec(),Vec(.75,.75,.75),DIFF),//Top
   Sphere(16.5,Vec(27,16.5,47),       Vec(),Vec(1,1,1)*.999, SPEC),//Mirr
   Sphere(16.5,Vec(73,16.5,78),       Vec(),Vec(1,1,1)*.999, REFR),//Glas
   Sphere(600, Vec(50,681.6-.27,81.6),Vec(12,12,12),  Vec(), DIFF) //Lite
 };
 inline double clamp(double x){ return x<0 ? 0 : x>1 ? 1 : x; }
 inline int toInt(double x){ return int(pow(clamp(x),1/2.2)*255+.5); }
 inline bool intersect(const Ray &r, double &t, int &id){
   double n=sizeof(spheres)/sizeof(Sphere), d, inf=t=1e20;
   for(int i=int(n);i--;) if((d=spheres[i].intersect(r))&&d<t){t=d;id=i;}
   return t<inf;
 }
 Vec radiance(const Ray &r, int depth, unsigned short *Xi){
   double t;                               // distance to intersection
   int id=0;                               // id of intersected object
   if (!intersect(r, t, id)) return Vec(); // if miss, return black
   const Sphere &obj = spheres[id];        // the hit object
   Vec x=r.o+r.d*t, n=(x-obj.p).norm(), nl=n.dot(r.d)<0?n:n*-1, f=obj.c;
   double p = f.x>f.y && f.x>f.z ? f.x : f.y>f.z ? f.y : f.z; // max refl
   if (++depth>5) if (erand48(Xi)<p) f=f*(1/p); else return obj.e; //R.R.
   if (obj.refl == DIFF){                  // Ideal DIFFUSE reflection
     double r1=2*M_PI*erand48(Xi), r2=erand48(Xi), r2s=sqrt(r2);
     Vec w=nl, u=((fabs(w.x)>.1?Vec(0,1):Vec(1))%w).norm(), v=w%u;
     Vec d = (u*cos(r1)*r2s + v*sin(r1)*r2s + w*sqrt(1-r2)).norm();
     return obj.e + f.mult(radiance(Ray(x,d),depth,Xi));
   } else if (obj.refl == SPEC)            // Ideal SPECULAR reflection
     return obj.e + f.mult(radiance(Ray(x,r.d-n*2*n.dot(r.d)),depth,Xi));
   Ray reflRay(x, r.d-n*2*n.dot(r.d));     // Ideal dielectric REFRACTION
   bool into = n.dot(nl)>0;                // Ray from outside going in?
   double nc=1, nt=1.5, nnt=into?nc/nt:nt/nc, ddn=r.d.dot(nl), cos2t;
   if ((cos2t=1-nnt*nnt*(1-ddn*ddn))<0)    // Total internal reflection
     return obj.e + f.mult(radiance(reflRay,depth,Xi));
   Vec tdir = (r.d*nnt - n*((into?1:-1)*(ddn*nnt+sqrt(cos2t)))).norm();
   double a=nt-nc, b=nt+nc, R0=a*a/(b*b), c = 1-(into?-ddn:tdir.dot(n));
   double Re=R0+(1-R0)*c*c*c*c*c,Tr=1-Re,P=.25+.5*Re,RP=Re/P,TP=Tr/(1-P);
   return obj.e + f.mult(depth>2 ? (erand48(Xi)<P ?   // Russian roulette
     radiance(reflRay,depth,Xi)*RP:radiance(Ray(x,tdir),depth,Xi)*TP) :
     radiance(reflRay,depth,Xi)*Re+radiance(Ray(x,tdir),depth,Xi)*Tr);
 }

using namespace std;                    // make std accessible

GLint TIMER_DELAY = 100;                      // timer delay (10 seconds)
GLfloat RED_RGB[] = {1.0, 0.0, 0.0};            // drawing colors
GLfloat BLUE_RGB[] = {0.0, 0.0, 1.0};

static bool isReversed = false;                 // draw reversed colors?

void myReshape(int w, int h) {
    cout << "MyReshape called width=" << w << " height=" << h << endl;
    glViewport (0, 0, w, h);                    // update the viewport
    glMatrixMode(GL_PROJECTION);                // update projection
    glLoadIdentity();
    gluOrtho2D(0.0, 1.0, 0.0, 1.0);             // map unit square to viewport
    glMatrixMode(GL_MODELVIEW);
    glutPostRedisplay();                        // request redisplay
}

struct rgbf {float r; float g; float b;};

float* pixels;
unsigned int window_width = 800, window_height = 600;
   int w=window_width, h=window_height, samps = 100;
    const int size=window_width*window_height;

                          // draw diamond and rectangle
void drawObjects() {


   //for (int i=0; i<w*h; i++)
     //fprintf(f,"%d %d %d ", toInt(c[i].x), toInt(c[i].y), toInt(c[i].z));

    //for (int i=0; i<w*h; i++) {
     //for(int i=0;i<size;i+=3) {
        //pixels[i] = c[i].x;
        //pixels[i+1] = c[i].y;
        //pixels[i+2] = c[i].z;
    //}


}

void myDisplay(void) {

    glClearColor(0.0, 0.0, 0.0, 1.0);
    glClear(GL_COLOR_BUFFER_BIT);

    glDrawPixels(window_width, window_height, GL_RGB, GL_FLOAT, pixels);

    glutSwapBuffers();
}

void myTimer(int id) {

    isReversed = !isReversed;
    glutPostRedisplay();
    glutTimerFunc(TIMER_DELAY, myTimer, 0);
}

void myMouse(int b, int s, int x, int y) {
    if (s == GLUT_DOWN) {
        cout << "Mouse click detected at coordinates x="
             << x << " and y=" << y << endl;
        if (b == GLUT_LEFT_BUTTON) {
            isReversed = !isReversed;
            cout << "Left mouse click.  Reversing colors." << endl;
            glutPostRedisplay();
        }
    }
}

void myKeyboard(unsigned char c, int x, int y) {
    switch (c) {
        case 'q':
            exit(0);
            break;
        default:
            cout << "Hit q to quit.  All other characters ignored" << endl;
            break;
    }
}

void task1(string msg)
{
   Ray cam(Vec(50,52,295.6), Vec(0,-0.042612,-1).norm()); // cam pos, dir
   Vec cx=Vec(w*.5135/h), cy=(cx%cam.d).norm()*.5135, r, *c=new Vec[w*h];


   for (int y=h/2; y<h; y++){                       // Loop over image rows
     for (unsigned short x=0, Xi[3]={0,0,y*y*y}; x<w; x++)   // Loop cols
       for (int sy=0, i=(h-y-1)*w+x; sy<2; sy++)     // 2x2 subpixel rows
         for (int sx=0; sx<2; sx++, r=Vec()){        // 2x2 subpixel cols
          for (int s=0; s<samps; s++){
             double r1=2*erand48(Xi), dx=r1<1 ? sqrt(r1)-1: 1-sqrt(2-r1);
             double r2=2*erand48(Xi), dy=r2<1 ? sqrt(r2)-1: 1-sqrt(2-r2);
             Vec d = cx*( ( (sx+.5 + dx)/2 + x)/w - .5) +
                     cy*( ( (sy+.5 + dy)/2 + y)/h - .5) + cam.d;
             r = r + radiance(Ray(cam.o+d*140,d.norm()),0,Xi)*(1./samps);
            }// Camera rays are pushed ^^^^^ forward to start in interior
           c[i] = c[i] + Vec(clamp(r.x),clamp(r.y),clamp(r.z))*.25;
            pixels[w*h*3-i*3] = c[i].x;
            pixels[w*h*3-i*3+1] = c[i].y;
            pixels[w*h*3-i*3+2] = c[i].z;

         }
        glutPostRedisplay();
   }
}

void task2(string msg)
{

   Ray cam(Vec(50,52,295.6), Vec(0,-0.042612,-1).norm()); // cam pos, dir
   Vec cx=Vec(w*.5135/h), cy=(cx%cam.d).norm()*.5135, r, *c=new Vec[w*h];


   for (int y=0; y<h/2; y++){                       // Loop over image rows
     for (unsigned short x=0, Xi[3]={0,0,y*y*y}; x<w; x++)   // Loop cols
       for (int sy=0, i=(h-y-1)*w+x; sy<2; sy++)     // 2x2 subpixel rows
         for (int sx=0; sx<2; sx++, r=Vec()){        // 2x2 subpixel cols
           for (int s=0; s<samps; s++){
             double r1=2*erand48(Xi), dx=r1<1 ? sqrt(r1)-1: 1-sqrt(2-r1);
             double r2=2*erand48(Xi), dy=r2<1 ? sqrt(r2)-1: 1-sqrt(2-r2);
             Vec d = cx*( ( (sx+.5 + dx)/2 + x)/w - .5) +
                     cy*( ( (sy+.5 + dy)/2 + y)/h - .5) + cam.d;
             r = r + radiance(Ray(cam.o+d*140,d.norm()),0,Xi)*(1./samps);

           }// Camera rays are pushed ^^^^^ forward to start in interior
           c[i] = c[i] + Vec(clamp(r.x),clamp(r.y),clamp(r.z))*.25;
            pixels[w*h*3-i*3] = c[i].x;
            pixels[w*h*3-i*3+1] = c[i].y;
            pixels[w*h*3-i*3+2] = c[i].z;

         }
        glutPostRedisplay();
   }
}


int main(int argc, char** argv)
{
    glutInit(&argc, argv);                      // OpenGL initializations
    glutInitDisplayMode(GLUT_DOUBLE | GLUT_RGB);// double buffering and RGB
    glutInitWindowSize(800, 600);               // create a 400x400 window
    glutInitWindowPosition(0, 0);               // ...in the upper left
    glutCreateWindow(argv[0]);                  // create the window

    std::thread t1(task1, "Hello");
    std::thread t2(task2, "Hello");


    pixels = new float[size*3];

    glutDisplayFunc(myDisplay);                 // setup callbacks
    glutReshapeFunc(myReshape);
    //glutMouseFunc(myMouse);
    //glutKeyboardFunc(myKeyboard);
    glutTimerFunc(TIMER_DELAY, myTimer, 0);
    glutMainLoop();                             // start it running
    // Makes the main thread wait for the new thread to finish execution, therefore blocks its own execution.
    t1.join();
    t2.join();

    return 0;                                   // ANSI C expects this
}
	#include <cstdlib>
	#include <iostream>
	#include <cstdio>
	#include <cmath>
	#include <thread>
	#include <string>
	#include <chrono>

	#include <GL/glut.h>
	#include <GL/glu.h>
	#include <GL/gl.h>

	#include <math.h>
	#include <stdlib.h>
	#include <stdio.h>
	struct Vec { // Usage: time ./smallpt 5000 && xv image.ppm
	double x, y, z; // position, also color (r,g,b)
	Vec(double x_=0, double y_=0, double z_=0){ x=x_; y=y_; z=z_; }
	Vec operator+(const Vec &b) const { return Vec(x+b.x,y+b.y,z+b.z); }
	Vec operator-(const Vec &b) const { return Vec(x-b.x,y-b.y,z-b.z); }
	Vec operator(double b) const { return Vec(xb,yb,zb); }
	Vec mult(const Vec &b) const { return Vec(xb.x,yb.y,z*b.z); }
	Vec& norm(){ return this = this * (1/sqrt(xx+yy+z*z)); }
	double dot(const Vec &b) const { return xb.x+yb.y+z*b.z; } // cross:
	Vec operator%(Vec&b){return Vec(yb.z-zb.y,zb.x-xb.z,xb.y-yb.x);}
	};
	struct Ray { Vec o, d; Ray(Vec o_, Vec d_) : o(o_), d(d_) {} };
	enum Refl_t { DIFF, SPEC, REFR }; // material types, used in radiance()
	struct Sphere {
	double rad; // radius
	Vec p, e, c; // position, emission, color
	Refl_t refl; // reflection type (DIFFuse, SPECular, REFRactive)
	Sphere(double rad_, Vec p_, Vec e_, Vec c_, Refl_t refl_):
	rad(rad_), p(p_), e(e_), c(c_), refl(refl_) {}
	double intersect(const Ray &r) const { // returns distance, 0 if nohit
	Vec op = p-r.o; // Solve t^2d.d + 2t*(o-p).d + (o-p).(o-p)-R^2 = 0
	double t, eps=1e-4, b=op.dot(r.d), det=bb-op.dot(op)+radrad;
	if (det<0) return 0; else det=sqrt(det);
	return (t=b-det)>eps ? t : ((t=b+det)>eps ? t : 0);
	}
	};
	Sphere spheres[] = {//Scene: radius, position, emission, color, material
	Sphere(1e5, Vec( 1e5+1,40.8,81.6), Vec(),Vec(.75,.25,.25),DIFF),//Left
	Sphere(1e5, Vec(-1e5+99,40.8,81.6),Vec(),Vec(.25,.25,.75),DIFF),//Rght
	Sphere(1e5, Vec(50,40.8, 1e5), Vec(),Vec(.75,.75,.75),DIFF),//Back
	Sphere(1e5, Vec(50,40.8,-1e5+170), Vec(),Vec(), DIFF),//Frnt
	Sphere(1e5, Vec(50, 1e5, 81.6), Vec(),Vec(.75,.75,.75),DIFF),//Botm
	Sphere(1e5, Vec(50,-1e5+81.6,81.6),Vec(),Vec(.75,.75,.75),DIFF),//Top
	Sphere(16.5,Vec(27,16.5,47), Vec(),Vec(1,1,1)*.999, SPEC),//Mirr
	Sphere(16.5,Vec(73,16.5,78), Vec(),Vec(1,1,1)*.999, REFR),//Glas
	Sphere(600, Vec(50,681.6-.27,81.6),Vec(12,12,12), Vec(), DIFF) //Lite
	};
	inline double clamp(double x){ return x<0 ? 0 : x>1 ? 1 : x; }
	inline int toInt(double x){ return int(pow(clamp(x),1/2.2)*255+.5); }
	inline bool intersect(const Ray &r, double &t, int &id){
	double n=sizeof(spheres)/sizeof(Sphere), d, inf=t=1e20;
	for(int i=int(n);i--;) if((d=spheres[i].intersect(r))&&d<t){t=d;id=i;}
	return t<inf;
	}
	Vec radiance(const Ray &r, int depth, unsigned short *Xi){
	double t; // distance to intersection
	int id=0; // id of intersected object
	if (!intersect(r, t, id)) return Vec(); // if miss, return black
	const Sphere &obj = spheres[id]; // the hit object
	Vec x=r.o+r.dt, n=(x-obj.p).norm(), nl=n.dot(r.d)<0?n:n-1, f=obj.c;
	double p = f.x>f.y && f.x>f.z ? f.x : f.y>f.z ? f.y : f.z; // max refl
	if (++depth>5) if (erand48(Xi)<p) f=f*(1/p); else return obj.e; //R.R.
	if (obj.refl == DIFF){ // Ideal DIFFUSE reflection
	double r1=2M_PIerand48(Xi), r2=erand48(Xi), r2s=sqrt(r2);
	Vec w=nl, u=((fabs(w.x)>.1?Vec(0,1):Vec(1))%w).norm(), v=w%u;
	Vec d = (ucos(r1)r2s + vsin(r1)r2s + w*sqrt(1-r2)).norm();
	return obj.e + f.mult(radiance(Ray(x,d),depth,Xi));
	} else if (obj.refl == SPEC) // Ideal SPECULAR reflection
	return obj.e + f.mult(radiance(Ray(x,r.d-n2n.dot(r.d)),depth,Xi));
	Ray reflRay(x, r.d-n2n.dot(r.d)); // Ideal dielectric REFRACTION
	bool into = n.dot(nl)>0; // Ray from outside going in?
	double nc=1, nt=1.5, nnt=into?nc/nt:nt/nc, ddn=r.d.dot(nl), cos2t;
	if ((cos2t=1-nntnnt(1-ddn*ddn))<0) // Total internal reflection
	return obj.e + f.mult(radiance(reflRay,depth,Xi));
	Vec tdir = (r.dnnt - n((into?1:-1)(ddnnnt+sqrt(cos2t)))).norm();
	double a=nt-nc, b=nt+nc, R0=aa/(bb), c = 1-(into?-ddn:tdir.dot(n));
	double Re=R0+(1-R0)ccccc,Tr=1-Re,P=.25+.5Re,RP=Re/P,TP=Tr/(1-P);
	return obj.e + f.mult(depth>2 ? (erand48(Xi)<P ? // Russian roulette
	radiance(reflRay,depth,Xi)RP:radiance(Ray(x,tdir),depth,Xi)TP) :
	radiance(reflRay,depth,Xi)Re+radiance(Ray(x,tdir),depth,Xi)Tr);
	}

	using namespace std; // make std accessible

	GLint TIMER_DELAY = 100; // timer delay (10 seconds)
	GLfloat RED_RGB[] = {1.0, 0.0, 0.0}; // drawing colors
	GLfloat BLUE_RGB[] = {0.0, 0.0, 1.0};

	static bool isReversed = false; // draw reversed colors?

	void myReshape(int w, int h) {
	cout << "MyReshape called width=" << w << " height=" << h << endl;
	glViewport (0, 0, w, h); // update the viewport
	glMatrixMode(GL_PROJECTION); // update projection
	glLoadIdentity();
	gluOrtho2D(0.0, 1.0, 0.0, 1.0); // map unit square to viewport
	glMatrixMode(GL_MODELVIEW);
	glutPostRedisplay(); // request redisplay
	}

	struct rgbf {float r; float g; float b;};

	float* pixels;
	unsigned int window_width = 800, window_height = 600;
	int w=window_width, h=window_height, samps = 100;
	const int size=window_width*window_height;

	// draw diamond and rectangle
	void drawObjects() {






	//for (int i=0; i<w*h; i++)
	//fprintf(f,"%d %d %d ", toInt(c[i].x), toInt(c[i].y), toInt(c[i].z));

	//for (int i=0; i<w*h; i++) {
	//for(int i=0;i<size;i+=3) {
	//pixels[i] = c[i].x;
	//pixels[i+1] = c[i].y;
	//pixels[i+2] = c[i].z;
	//}




	}

	void myDisplay(void) {

	glClearColor(0.0, 0.0, 0.0, 1.0);
	glClear(GL_COLOR_BUFFER_BIT);

	glDrawPixels(window_width, window_height, GL_RGB, GL_FLOAT, pixels);

	glutSwapBuffers();
	}

	void myTimer(int id) {

	isReversed = !isReversed;
	glutPostRedisplay();
	glutTimerFunc(TIMER_DELAY, myTimer, 0);
	}

	void myMouse(int b, int s, int x, int y) {
	if (s == GLUT_DOWN) {
	cout << "Mouse click detected at coordinates x="
	<< x << " and y=" << y << endl;
	if (b == GLUT_LEFT_BUTTON) {
	isReversed = !isReversed;
	cout << "Left mouse click. Reversing colors." << endl;
	glutPostRedisplay();
	}
	}
	}

	void myKeyboard(unsigned char c, int x, int y) {
	switch (c) {
	case 'q':
	exit(0);
	break;
	default:
	cout << "Hit q to quit. All other characters ignored" << endl;
	break;
	}
	}

	void task1(string msg)
	{
	Ray cam(Vec(50,52,295.6), Vec(0,-0.042612,-1).norm()); // cam pos, dir
	Vec cx=Vec(w.5135/h), cy=(cx%cam.d).norm().5135, r, c=new Vec[wh];


	for (int y=h/2; y<h; y++){ // Loop over image rows
	for (unsigned short x=0, Xi[3]={0,0,yyy}; x<w; x++) // Loop cols
	for (int sy=0, i=(h-y-1)*w+x; sy<2; sy++) // 2x2 subpixel rows
	for (int sx=0; sx<2; sx++, r=Vec()){ // 2x2 subpixel cols
	for (int s=0; s<samps; s++){
	double r1=2*erand48(Xi), dx=r1<1 ? sqrt(r1)-1: 1-sqrt(2-r1);
	double r2=2*erand48(Xi), dy=r2<1 ? sqrt(r2)-1: 1-sqrt(2-r2);
	Vec d = cx*( ( (sx+.5 + dx)/2 + x)/w - .5) +
	cy*( ( (sy+.5 + dy)/2 + y)/h - .5) + cam.d;
	r = r + radiance(Ray(cam.o+d140,d.norm()),0,Xi)(1./samps);
	}// Camera rays are pushed ^^^^^ forward to start in interior
	c[i] = c[i] + Vec(clamp(r.x),clamp(r.y),clamp(r.z))*.25;
	pixels[wh3-i*3] = c[i].x;
	pixels[wh3-i*3+1] = c[i].y;
	pixels[wh3-i*3+2] = c[i].z;

	}
	glutPostRedisplay();
	}
	}

	void task2(string msg)
	{

	Ray cam(Vec(50,52,295.6), Vec(0,-0.042612,-1).norm()); // cam pos, dir
	Vec cx=Vec(w.5135/h), cy=(cx%cam.d).norm().5135, r, c=new Vec[wh];


	for (int y=0; y<h/2; y++){ // Loop over image rows
	for (unsigned short x=0, Xi[3]={0,0,yyy}; x<w; x++) // Loop cols
	for (int sy=0, i=(h-y-1)*w+x; sy<2; sy++) // 2x2 subpixel rows
	for (int sx=0; sx<2; sx++, r=Vec()){ // 2x2 subpixel cols
	for (int s=0; s<samps; s++){
	double r1=2*erand48(Xi), dx=r1<1 ? sqrt(r1)-1: 1-sqrt(2-r1);
	double r2=2*erand48(Xi), dy=r2<1 ? sqrt(r2)-1: 1-sqrt(2-r2);
	Vec d = cx*( ( (sx+.5 + dx)/2 + x)/w - .5) +
	cy*( ( (sy+.5 + dy)/2 + y)/h - .5) + cam.d;
	r = r + radiance(Ray(cam.o+d140,d.norm()),0,Xi)(1./samps);

	}// Camera rays are pushed ^^^^^ forward to start in interior
	c[i] = c[i] + Vec(clamp(r.x),clamp(r.y),clamp(r.z))*.25;
	pixels[wh3-i*3] = c[i].x;
	pixels[wh3-i*3+1] = c[i].y;
	pixels[wh3-i*3+2] = c[i].z;

	}
	glutPostRedisplay();
	}
	}



	int main(int argc, char** argv)
	{
	glutInit(&argc, argv); // OpenGL initializations
	glutInitDisplayMode(GLUT_DOUBLE \| GLUT_RGB);// double buffering and RGB
	glutInitWindowSize(800, 600); // create a 400x400 window
	glutInitWindowPosition(0, 0); // ...in the upper left
	glutCreateWindow(argv[0]); // create the window

	std::thread t1(task1, "Hello");
	std::thread t2(task2, "Hello");


	pixels = new float[size*3];

	glutDisplayFunc(myDisplay); // setup callbacks
	glutReshapeFunc(myReshape);
	//glutMouseFunc(myMouse);
	//glutKeyboardFunc(myKeyboard);
	glutTimerFunc(TIMER_DELAY, myTimer, 0);
	glutMainLoop(); // start it running
	// Makes the main thread wait for the new thread to finish execution, therefore blocks its own execution.
	t1.join();
	t2.join();

	return 0; // ANSI C expects this
	}