Merge pull request #1 from sunyinqi0508/hw2

Hw2
4 years ago · e87f15d2a5
parent db81299aef f7eb9cb123
commit e87f15d2a5
5 changed files with 277 additions and 236 deletions
--- a/earthmap1k.jpg
+++ b/earthmap1k.jpg
--- a/2.jpg
+++ b/2.jpg
--- a/index.html
+++ b/index.html
@ -1,4 +1,4 @@
-<script src=lib1.js></script>
+<script src=lib2.js></script>
 <script src="https://cdnjs.cloudflare.com/ajax/libs/ace/1.4.12/ace.js"crossorigin="anonymous"></script>
 <script src="https://cdnjs.cloudflare.com/ajax/libs/ace/1.4.12/ext-language_tools.js" crossorigin="anonymous"></script>
 <style>
@ -21,7 +21,7 @@
 </style>
 <body bgcolor=white text=black link=black alink=blue vlink=blue>
 <center>
-<canvas id='canvas1' width=600 height=600></canvas>
+<canvas id='canvas1' style="width: 600px; height:600px;" width=1200 height=1200></canvas>
 </center>
 </body>
@ -39,197 +39,22 @@
 <!!-------- FRAGMENT SHADER: THIS IS WHERE YOU WILL DO YOUR WORK -------->
-
+<!!-------- FRAGMENT SHADER: MOVED TO ./shader.frag LOADED IN lib2.js -------->
-<script id='my_fragment_shader' type='x-shader/x-fragment'>
+<!--script src="shader.frag" id='my_fragment_shader' type='x-shader/x-fragment'> </script>
 uniform float uTime;   // TIME, IN SECONDS
 uniform int flags;
 varying vec3 vPos;     // -1 < vPos.x < +1
                        // -1 < vPos.y < +1
                        //      vPos.z == 0
 uniform sampler2D uSampler;
 // YOU MUST DEFINE A main() FUNCTION.
 void main() {
 ////////////////////////////////////////////////
 //
 // HERE, FOR YOUR HOMEWORK, YOU CAN WRITE ANY
 // CODE YOU LIKE
    //DEFINE A COLOR FOR THIS FRAGMENT.
    // LIGHT DIRECTION AND COLOR
    vec3 LDir = vec3(1, 1, 1);
    vec3 LCol = vec3(1.,.98,.9);
    vec3 VDir = vec3(0., 0., 1.);
    float R = 0.5 + 0.3*sin(uTime/10.);
    // vPos IS THE 3D LOCATION OF THIS FRAGMENT.
    // SURFACE REFLECTANCE PROPERTIES
    vec3 diffuse = vec3(.7,.7,.6);
    vec3 ambient = vec3(.1,.1,.09);
    vec3 specular = vec3(.35,.35,.3);
    // CREATE A WACKY BACKGROUND PATTERN.
    vec3 color = vec3(.5 + .5 * sin(20. * vPos.x + sin(10. * vPos.y + 5. * uTime)),
                      .5,
                      .5 + .5 * sin(20. * vPos.y + sin(10. * vPos.x + 5. * uTime)));
    vec3 specularlight; //specular light should disregard object color.
    float x = vPos.x;
    float y = vPos.y;
    // CREATE BOUNCING ANIMATION.
    y += .5 - 2. * abs(.5 * sin(uTime));
    // FIGURE OUT WHETHER THIS PIXEL IS ON THE SPHERE.
    float rr = x * x + y * y;
    // IF SO, THEN SHADE THE SPHERE.
    if (rr < R*R) {
       // COMPUTE THE z AND NORMAL OF THE SPHERE.
       float z = R * sqrt(1. - rr/(R*R));
       vec3 N = vec3(x,y,z) / R;
       // APPLY SHADING AND LIGHTING.
       vec3 realVPos = vec3(vPos.x, vPos.y, z);
       //*DIRECTIONS ARE NORMALIZED TO GET THE CORRECT PHONG LIGHTING
       LDir = normalize(LDir - realVPos);
       VDir = normalize(VDir - realVPos);
       vec3 lcolor = ambient;
       lcolor += diffuse * max(0., dot(N, LDir)) * LCol;
       //*SPECULAR LIGHTS ARE ADDED
       specularlight = specular * 
                  pow(max(0.,dot(2.*dot(N, LDir) * N - LDir, VDir)),3.) * LCol;
       // ROTATE THE TEXTURE OVER TIME.
       float angle = 0.4 * uTime;
       float px =  cos(angle) * N.x + sin(angle) * N.z;
       float pz = -sin(angle) * N.x + cos(angle) * N.z;
       vec3 P = vec3(px, N.y, pz);
       // APPLY PROCEDURAL NOISE TEXTURE.
       float cloud = min(0.85, max(-0.05, 2. * noise(1.1 * P)));
       //const float rspeed = 10.;
      //*CALCULATING THE TEXTURE COORDINATE.
      const float pi = 3.14159265359;
      float tex_x = acos(abs(x)/sqrt(R*R-y*y));
      if(x > 0.)
         tex_x = pi - tex_x;
      tex_x = R * tex_x;
      tex_x *= 1.5708;//*Correct aspect ratio of texture 2:1 -> 2pir:2r
      tex_x = tex_x + float(uTime)*R;
      float _2pir = 2. * pi * R;
      float quo = float(int(tex_x/_2pir));
      tex_x = (tex_x - quo * _2pir) / _2pir;
      //*TEXTURE MAPPING
      vec3 texture_color;
      if(flags /*& 0x1*/ == 0)
         texture_color = texture2D(uSampler, vec2(tex_x, ((R - y)/(2.*R)))).xyz;
      else
         texture_color = vec3(.0841, .5329, .9604);
      color = lcolor * 
            (cloud + texture_color) + specularlight;
    }
    //*CALCULATING LIGHTING AND SHADOWS FOR THE BACKGROUND
    else{
      vec3 realVPos = vec3(vPos.x, vPos.y, -1.);
      vec3 N = vec3(0., 0., 1.);
      vec3 C = vec3(0., vPos.y - y, 0.);
      // APPLY SHADING AND LIGHTING.
      vec3 lcolor = 6.*ambient;
      //*CALCULATING DISTANCE BETWEEN SPHERE CENTER TO THE RAY 
       //BETWEEN THE POINT TO LIGHT SOURCE
      vec3 LV = realVPos - LDir;
      vec3 LC = C - LDir;
      vec3 VC = C - realVPos;
      float lLV = dot(LV, LV);
      float lLC = dot(LC, LC);
      float lVC = dot(VC, VC);
      float RR = R*R;
      float d_VCVL = -dot(VC, LV);
      float dist = min(lLC, lVC);
      if (d_VCVL > 0.)
         dist = min(dist, lVC - d_VCVL*d_VCVL/lLV);
      //*CALCULATE DISTANCE BETWEEN SPHERE CENTER TO THE RAY BETWEEN POINT TO CAMERA
      vec3 EV = realVPos - VDir;
      vec3 EC = C - VDir;
      float lEV = dot(EV, EV);
      float lEC = dot(EC, EC);
      float d_VCVE = -dot(VC, EV);
      float dist2 = min(lEC, lVC);
      if (d_VCVE > 0.)
         dist2 = min(dist2, lVC - d_VCVE*d_VCVE/lEV);
      //*AMBIENT LIGHT WILL DECAY WHEN BACKGROUND POINT IS CLOSER TO THE SPHERE
      //*FIRST THE DISTANCE IS NORMALIZED, THEN I CURVED IT WITH LOGISTIC FUNCTION
      float aratio0 = 1./(1.+pow(2.71828,15.*(.2-(sqrt(lVC) - R - .4806)/1.381)));
      lcolor *= aratio0;
      diffuse *= pow(aratio0, 0.3);
      //*TEST IF CAMERA CAN SEE THE POINT
      if(dist2 < RR)
      {
         specular *= 0.;
         float d = sqrt(dist2);
         float ratio = pow(2., sqrt(dist2)/R) - 1.;
         diffuse *= ratio;
      }
      //*TEST IF THE LIGHT CAN REACH THE BACKGROUND POINT DIRECTLY
      if(dist < RR)
      {
         specular *= 0.;
         float ratio = pow(2.7, sqrt(dist)/R) - 1.7;
         float aratio = pow(2., sqrt(dist)/R) - 1.;
         if(ratio < 0.)
            ratio = 0.;
         diffuse *= ratio;
         lcolor *= aratio;
      }
      LDir = normalize(LDir - realVPos);
      VDir = normalize(VDir - realVPos); 
      lcolor += 1.2*diffuse * max(0., dot(N, LDir)) * LCol;
      specularlight = 0.3*specular * 
            pow(max(0., dot(2.*dot(N, LDir) * N - LDir, VDir)),32.) * LCol;
      color = color * lcolor + specularlight;
    }
    // APPLY GAMMA CORRECTION AND SET THE PIXEL COLOR.
    gl_FragColor = vec4(sqrt(color), 1.0);
 }
 </script>
 <!!-------- CREATE A PROPERLY DESCRIPTIVE TITLE BELOW -------->
 <script id='my_title' type='text/html'>
-The Bouncing Earth
+Solar RTX
 </script>
 <!!-------- HERE IS WHERE YOU CAN PROVIDE A LONGER TEXT DESCRIPTION -------->
 <script id='my_instructions' type='text/html'><font color=#909090>
-<p style="font-size:30px; ">This is a description 
+<p style="font-size:30px; ">In this homework, I implemented Global illumination w/ 
-of my cool homework 
+   Realtime Recursive Ray Tracing! 
 that you are seeing now.</p>
 <p>
 <i style="font-size:25px;">Here is how it works:</i>
 <ul>
@ -245,7 +70,7 @@ that you are seeing now.</p>
      <ul>
         <li>The Ambient lights and diffusion lights are reduced with respect to the distance between the background point and the sphere.</li>
         <li>The specular light of the background wall is eliminated and the diffusion factor is reduced when the ray shooting from the background point 
-         towards the light source or from the background point towards the camera position intersect with the sphere.</li>
+       towards the light source or from the background point towards the camera position intersect with the sphere.</li>
      </ul>
   <li>I added basic interactions such as press ctrl + 't' key to hide/show texture, click on the above canvas to pause/unpause animations. 
      Just a proof of concept.</li>   
@ -260,16 +85,30 @@ that you are seeing now.</p>
 </script>
-<!!-------- YOU PROBABLY DON'T WANT TO CHANGE ANYTHING BELOW FOR NOW -------->
+<!!-------- YOU PROBABLY WANT TO CHANGE ANYTHING BELOW RIGHT NOW -------->
 <script>
 // CREATE THE HTML DOCUMENT
 let flags = 0x0;
-let vs = my_vertex_shader.innerHTML,
+let vs = my_vertex_shader.innerHTML;
-    fs = my_fragment_shader.innerHTML;
+    //* LOADING FRAGMENT SHADER
-    fs = fs.substring(1, fs.length);
+    var client = new XMLHttpRequest();
-
+    client.open('GET', './shader.frag');
    client.onloadend = function() {
      fs = (client.responseText);
      //* START EVERYTHING AFTER FRAGMENT SHADER IS DOWNLOADED.
      gl_start(canvas1, vs, fs);
      editor.getSession().setValue(fs);
      editor.session.on('change', function(delta) {
         if(typeof canvas1.setShaders === "function")
         {
            canvas1.setShaders(vs, editor.getSession().getValue());
            setUniform('1i', 'flags', flags);
         }
      });
    }
   client.send();
 document.body.innerHTML = [''
   ,'<font size=7 color=#909090>' + my_title.innerHTML
   ,'<TABLE cellspacing=0 cellpadding=0><TR>'
@ -285,10 +124,6 @@ document.body.innerHTML = [''
   ].join('');
 // SET UP THE EDITABLE TEXT AREA ON THE LEFT SIDE.
 let text = fs.split('\n'), cols = 0;
 for (let i = 0 ; i < text.length ; i++)
   cols = Math.max(cols, text[i].length);
 ace.require("ace/ext/language_tools");
 var editor = ace.edit("ace", {
   mode:"ace/mode/glsl",
@ -305,12 +140,8 @@ editor.setOptions({
   showPrintMargin: false,
 });
 editor.setAutoScrollEditorIntoView(true);
 editor.getSession().setValue(fs);
 // REPARSE THE SHADER PROGRAM AFTER EVERY KEYSTROKE.
-editor.session.on('change', function(delta) {
+delete editor.KeyBinding;
   canvas1.setShaders(vs, editor.getSession().getValue());
 });
 let lastTime = Date.now();
 let animating = true;
 let ctrl = false;
@ -322,17 +153,23 @@ canvas1.addEventListener('click',function(ev){
   animating = !animating;
 });
 document.addEventListener('keydown',(e)=>{
-
+   if(e.code.startsWith('Control'))
-if(e.code.startsWith('Control'))
+   {
-{
+      ctrl = true;
-   ctrl = true;
+   }
-}
+   else if(ctrl && e.code == 'KeyT')
 else if(ctrl && e.code == 'KeyT')
   {
      mask = 0x1;
-      flags = flags&!mask | (!(flags&mask)*mask);
+      flags = flags&!mask | (!(flags&mask)?mask:0);
      setUniform('1i', 'flags', flags);
   }
   else if (ctrl && e.code == 'KeyS')
   {
      let a = document.createElement('a');
      a.href = "data:text/plain,"+encodeURIComponent(editor.getSession().getValue());
      a.download = 'shader.frag';
      a.click();
   }
 });
 document.addEventListener('keyup',(e)=>{
@ -353,8 +190,6 @@ function animate(gl) {
 }
 // START EVERYTHING.
 gl_start(canvas1, vs, fs);
 </script>
--- a/lib2.js
+++ b/lib2.js
@ -24,15 +24,17 @@ let errorMsg = '';
 // Initialize a texture and load an image.
 // When the image finished loading copy it into the texture.
 //
-function loadTexture(gl, url) {
+function getBlob(data) {
-   const texture = gl.createTexture();
+   let bytes = new Array(data.length);
-   gl.bindTexture(gl.TEXTURE_2D, texture);
+   for (let i = 0; i < data.length; i++) {
-
+     bytes[i] = data.charCodeAt(i);
-   // Because images have to be downloaded over the internet
+   } 
-   // they might take a moment until they are ready.
+   return new Blob([new Uint8Array(bytes)]);
-   // Until then put a single pixel in the texture so we can
+ }
-   // use it immediately. When the image has finished downloading
+let texture = [], gl, program;
-   // we'll update the texture with the contents of the image.
+let textures = []; 
 let lock = false;
 function loadTexture(gl, url, i) {
   const level = 0;
   const internalFormat = gl.RGBA;
   const width = 1;
@ -40,14 +42,26 @@ function loadTexture(gl, url) {
   const border = 0;
   const srcFormat = gl.RGBA;
   const srcType = gl.UNSIGNED_BYTE;
-   const pixel = new Uint8Array([0, 0, 255, 255]);  // opaque blue
+   if (texture[i] == null)
-   gl.texImage2D(gl.TEXTURE_2D, level, internalFormat,
+   {
-      width, height, border, srcFormat, srcType,
+      texture[i] = gl.createTexture();
-      pixel);
+      const pixel = new Uint8Array([0, 0, 255, 255]);  // opaque blue
      gl.activeTexture(gl.TEXTURE0+i);
      gl.bindTexture(gl.TEXTURE_2D, texture[i]);
      gl.texImage2D(gl.TEXTURE_2D, level, internalFormat,
         width, height, border, srcFormat, srcType,
         pixel);
   }
   // Because images have to be downloaded over the internet
   // they might take a moment until they are ready.
   // Until then put a single pixel in the texture so we can
   // use it immediately. When the image has finished downloading
   // we'll update the texture with the contents of the image.
   const image = new Image();
   image.onload = function () {
-      gl.bindTexture(gl.TEXTURE_2D, texture);
+      gl.activeTexture(gl.TEXTURE0+i);
      gl.bindTexture(gl.TEXTURE_2D, texture[i]);
      gl.texImage2D(gl.TEXTURE_2D, level, internalFormat,
         srcFormat, srcType, image);
@ -57,6 +71,7 @@ function loadTexture(gl, url) {
      if (isPowerOf2(image.width) && isPowerOf2(image.height)) {
         // Yes, it's a power of 2. Generate mips.
         gl.generateMipmap(gl.TEXTURE_2D);
         gl.texParameteri(gl.TEXTURE_2D, gl.TEXTURE_MIN_FILTER, gl.LINEAR_MIPMAP_LINEAR);
      } else {
         // No, it's not a power of 2. Turn off mips and set
         // wrapping to clamp to edge
@ -66,8 +81,6 @@ function loadTexture(gl, url) {
      }
   };
   image.src = url;
   return texture;
 }
 function isPowerOf2(value) {
@ -77,12 +90,13 @@ function gl_start(canvas, vertexShader, fragmentShader) {           // START WEB
   setTimeout(function () {
      try {
-         canvas.gl = canvas.getContext('experimental-webgl');              // Make sure WebGl is supported. IT WOULD BE GREAT TO USE WEBGL2 INSTEAD.
+         canvas.gl = canvas.getContext('webgl2');              // Make sure WebGl is supported. IT WOULD BE GREAT TO USE WEBGL2 INSTEAD.
      } catch (e) { throw 'Sorry, your browser does not support WebGL.'; }
      canvas.setShaders = function (vertexShader, fragmentShader) {         // Add the vertex and fragment shaders:
-         let gl = this.gl, program = gl.createProgram();                        // Create the WebGL program.
+         gl = this.gl;
         program = gl.createProgram();                        // Create the WebGL program.
         function addshader(type, src) {                                        // Create and attach a WebGL shader.
            function spacer(color, width, height) {
@ -131,15 +145,12 @@ function gl_start(canvas, vertexShader, fragmentShader) {           // START WEB
            console.log('Could not link the shader program!');
         gl.useProgram(program);
         gl.program = program;
-
+         const ns = 2;
-         let texture = loadTexture(gl, './earthmap1k.jpg') //Texture loading.
+         for(let i = 0; i < ns; ++i){
-         // Tell WebGL we want to affect texture unit 0
+            loadTexture(gl, './'+(i+1)+'.jpg', i); //Texture loading.
-         gl.activeTexture(gl.TEXTURE0);
+            textures[i] = i;
-         // Bind the texture to texture unit 0
+         }
-         gl.bindTexture(gl.TEXTURE_2D, texture);
+         gl.uniform1iv(gl.getUniformLocation(program, 'uSampler'), textures);
         // Tell the shader we bound the texture to texture unit 0
         gl.uniform1i(gl.getUniformLocation(program, 'uSampler'), 0);
         gl.bindBuffer(gl.ARRAY_BUFFER, gl.createBuffer());                     // Create a square as a triangle strip
         gl.bufferData(gl.ARRAY_BUFFER, new Float32Array(                       //    consisting of two triangles.
@ -151,7 +162,6 @@ function gl_start(canvas, vertexShader, fragmentShader) {           // START WEB
      }
      canvas.setShaders(vertexShader, fragmentShader);                     // Initialize everything,
      setInterval(function () {                                             // Start the animation loop.
         gl = canvas.gl;
         if (gl.startTime === undefined)                                            // First time through,
@ -167,7 +177,6 @@ function gl_start(canvas, vertexShader, fragmentShader) {           // START WEB
 function animate() { }
 let gl;
 function setUniform(type, name, a, b, c, d, e, f) {
   let loc = gl.getUniformLocation(gl.program, name);
   (gl['uniform' + type])(loc, a, b, c, d, e, f);
--- a/shader.frag
+++ b/shader.frag
@ -0,0 +1,197 @@
 vec3 foregroundColor = vec3(.0841, .5329, .9604);
 vec3 groundColor = vec3(.2, .3, .5);
 vec4 groundSpecular = vec4(.71, .71, .71, 10.);
 uniform float uTime;// TIME, IN SECONDS
 uniform int flags;
 //FLAGS 0-RT, 1-TEX, 2-
 varying vec3 vPos;// -1 < vPos.x < +1
 // -1 < vPos.y < +1
 //      vPos.z == 0
 float fl=3.;
 const float pi=3.14159265359;
 const int n_ref=2;
 const int ns=2;
 vec4 Sph[ns];
 uniform sampler2D uSampler[ns];
 vec3 Ambient[ns];
 vec3 Diffuse[ns];
 vec4 Specular[ns];
 struct RT{
   vec3 color;
   float ks;
   // vec3 ptr;
   // vec3 normal;
 } stack[n_ref];
 bool getflag(int flag,int bit){
   float shifted = float(int(float(flag)/ pow(2.,float(bit))));
   return fract(shifted/2.)>0.;
 }
 float clampv(float val,float l,float h){
   return val<l?l:val>h?h:val;
 }
 void main(){
   ////////////////////////////////////////////////
   //
   // HERE, FOR YOUR HOMEWORK, YOU CAN WRITE ANY
   // CODE YOU LIKDEFINE A COLOR FOR THIS FRAGMENT.
   // LIGHT DIRECTION AND COLOR
   vec3 LDir=vec3(.5,.5,.5);
   vec3 LCol=vec3(1.,1.,1.);
   // SPHERE
   Sph[0]=vec4(.5*sin(uTime),0.,.5*cos(uTime),.2);
   Sph[1]=vec4(0.,0.,0.,.2);
   // SURFACE REFLECTANCE PROPERTIES
   Ambient[1]=vec3(.1,.05,.05);// r,g,b
   Diffuse[1]=vec3(1.,.5,.5);// r,g,b
   Specular[1]=vec4(1.,.5,.5,10.);// r,g,b,power
   Ambient[0]=vec3(.05,.05,.1);// r,g,b
   Diffuse[0]=vec3(.5,.5,1.);// r,g,b
   Specular[0]=vec4(1.,.5,.5,20.);// r,g,b,power
   // INITIALIZE TO A BACKGROUND COLOR
   vec3 color=vec3(.2, .3, .5);
   // COMPUTE THE RAY ORIGIN AND DIRECTION
   float x=vPos.x;
   float y=vPos.y;
   vec3 V=vec3(0.,0.,fl);
   vec3 W=normalize(vec3(x,y,-fl));
   // RAY TRACE TO ALL OBJECTS IN THE SCENE
   bool rtxoff = getflag(flags, 1);
   int cnt_ref = n_ref;
   for(int j=0;j<n_ref;j++)
   {
      float tMin=10000.;
      int iMin = -1;
      for(int i=0;i<ns;i++){
         // SHIFT COORDINATES, SO THAT SPHERE IS AT (0,0,0)
         vec3 Vp=V-Sph[i].xyz;
         // SOLVE FOR QUADRATIC EQUATION IN t
         float B=dot(W,Vp);
         float C=dot(Vp,Vp)-Sph[i].w*Sph[i].w;
         float D=B*B-C;
         if(D>0.){
            float t=-B-sqrt(D);
            if(t > 0. && t < tMin){
               tMin = t;
               iMin = i;
            }
         }
      }
      // IF RAY HITS SPHERE
      if(iMin >= 0){
         float t = tMin;
         vec3 S=V+t*W;
         for(int i = 0; i < ns; ++ i)
            if(i == iMin)
            {
               //*TEXTURE MAPPING
               vec3 tex_sph=S-Sph[i].xyz;
               float R=Sph[i].w;
               float tex_x=acos(abs(tex_sph.x)/sqrt(R*R-tex_sph.y*tex_sph.y));
               if(tex_sph.x>0.)
                  tex_x=pi-tex_x;
               tex_x=R*tex_x;
               tex_x*=1.5708;//*Correct aspect ratio of texture 2:1 -> 2pir:2r
               tex_x=tex_x+float(uTime)*R;
               float _2pir=2.*pi*R;
               float quo=float(int(tex_x/_2pir));
               tex_x=clampv((tex_x-quo*_2pir),0.,_2pir)/_2pir;
               vec3 texture_color;
               if(!getflag(flags,0))
                  texture_color=texture2D(uSampler[i],vec2(tex_x,((R-tex_sph.y)/(2.*R)))).xyz;
               else texture_color = foregroundColor;
               vec3 N=normalize(S-Sph[i].xyz);
               //*DIRECTIONS ARE NORMALIZED TO GET THE CORRECT PHONG LIGHTING
               vec3 realLDir=normalize(LDir-S);
               color=(
                     Ambient[i]
                     +Diffuse[i]*max(0.,dot(N,realLDir))*LCol
                  )*texture_color
               ;
               // + SPECULAR COMPONENT GOES HERE
               if(rtxoff || j == n_ref - 1)
                  color += float(j) * Specular[i].xyz*pow(max(0.,dot(2.*dot(N,realLDir)*N-realLDir,-W)),Specular[i].w);
               stack[j] = RT(color, 0.15);
               V = S;
               W = -normalize(2. * dot(N, W) * N - W);
               break;
            }
      }
      else {
      // TO SIMIPIFY THINGS UP, I'LL ASSUME THAT EVERYTHING 
      // IS INSIDE THE BOUNDING BOX [(-1,-1,-1), (1,1,1)]
      // AND THERE'S A INFINITE FLOOR [y = -1]
         float t = -(.2+V.y)/W.y;
         float sx = V.x + t* W.x, sz = V.z + t * W.z;
         if(t >= 0.&&abs(sx)<1.5 && abs(sz+.6)<3.)
         {   
            vec3 S = vec3(sx, -.2, sz);
            vec3 realLDir=normalize(LDir - S);
            color=(
                  0.5
                  +0.5*max(0.,realLDir.y)*LCol
               )*groundColor
            ;
            // + SPECULAR COMPONENT GOES HERE
            if(rtxoff || j == n_ref - 1)
               color += float(j)*groundSpecular.xyz*
                  pow(max(0., dot(vec3(-realLDir.x, realLDir.y,-realLDir.z),-W)),groundSpecular.w);
            stack[j] = RT(color, 0.1);
            V = S;
            W = vec3(W.x, -W.y, W.z);
         }
         else{
            if(j > 0)
            {
               stack[j] = RT(vec3(12.,12.,12.)*pow(max(0.,dot(W, normalize(LDir - V))), 10.), 0.);
               cnt_ref = j + 1;
            }
            else
               cnt_ref = j;
            break;
         }
      }       
      // RTX off
      if(rtxoff)
         break;
   }
   if(rtxoff)
      color = stack[0].color;
   else
   {
      color = vec3(0,0,0);
      float currks = 1.;
      for(int i = 0; i < n_ref; ++i)
      {
         if(i >= cnt_ref)
         {
            color += currks * stack[i - 1].color;
            break;
         }
         color += currks *(1.-stack[i].ks) * stack[i].color;
         currks *= stack[i].ks;
      }
      if(n_ref == cnt_ref)
         color += currks * stack[n_ref - 1].color;
   }
   // APPLY GAMMA CORRECTION AND SET THE PIXEL COLOR.
   gl_FragColor=vec4(sqrt(color),1.);
 }