Suzanne Knop

README.md

@@ -1,118 +1,44 @@
-# [Project 1: Noise](https://github.com/CIS700-Procedural-Graphics/Project1-Noise)
+# Noise
 
-## Objective
+#### [Check out the project here!](https://sknop8.github.io/Noise/)
 
-Get comfortable with using three.js and its shader support and generate an interesting 3D, continuous surface using a multi-octave noise algorithm.
+<img src="https://github.com/sknop8/Project1-Noise/blob/00b21b004ebf203cceee8bcb04f9b57635195d22/imgs/noisebasic.gif" width="600px">
 
-## Getting Started
+## Overview
 
-1. [Install Node.js](https://nodejs.org/en/download/). Node.js is a JavaScript runtime. It basically allows you to run JavaScript when not in a browser. For our purposes, this is not necessary. The important part is that with it comes `npm`, the Node Package Manager. This allows us to easily declare and install external dependencies such as [three.js](https://threejs.org/), [dat.GUI](https://workshop.chromeexperiments.com/examples/gui/#1--Basic-Usage), and [glMatrix](http://glmatrix.net/). Some other packages we'll be using make it significantly easier to develop your code and create modules for better code reuse and clarity. These tools make it _signficantly_ easier to write code in multiple `.js` files without globally defining everything.
+A 3D visual representation of multi-octave noise written using [three.js](https://threejs.org/) and its shader support, and [dat.GUI](https://workshop.chromeexperiments.com/examples/gui/#1--Basic-Usage). The output is a continous surface deformation of a sphere mesh, with lots of customization capabilites to allow users to create interesting results!
 
-2. Fork and clone [this repository](https://github.com/CIS700-Procedural-Graphics/Project1-Noise).
+### Noise Features
+Continous, multi-octave noise
+- Approximately 50 octaves of pseudo-randomly generated noise
+- Cosine interpolation between lattice values
 
-3. In the root directory of your project, run `npm install`. This will download all of those dependencies.
 
-4. Do either of the following (but I highly recommend the first one for reasons I will explain later).
+### Interactive Features
 
-    a. Run `npm start` and then go to `localhost:7000` in your web browser
+<img src="https://github.com/sknop8/Project1-Noise/blob/00b21b004ebf203cceee8bcb04f9b57635195d22/imgs/Screen%20Shot%202017-10-09%20at%203.39.25%20AM.png" height="400px">
 
-    b. Run `npm run build` and then go open `index.html` in your web browser
+1. Mesh color control    
+a. Base color    
+b. Outer color (based on the generated noise)    
+c. Inner color (based on the generated noise)     
+2. Stripes (based on noise offset)      
+a. Stripe density control     
+b. Stripe color control   
+    <img src="https://github.com/sknop8/Project1-Noise/blob/00b21b004ebf203cceee8bcb04f9b57635195d22/imgs/nosestripes.gif" width="300px">
+3. Pattern (procedurally generated by finding mod intersections between 2 different noise outputs)      
+a. Pattern density control       
+b. Pattern color control    
+    <img src="https://github.com/sknop8/Project1-Noise/blob/00b21b004ebf203cceee8bcb04f9b57635195d22/imgs/noisepattern.gif" width=300px>
+4. Pixelate mesh      
+a. Control pixelate power (how much pixelization)    
+    <img src="https://github.com/sknop8/Project1-Noise/blob/00b21b004ebf203cceee8bcb04f9b57635195d22/imgs/noisepixelate.gif" width=300px>
 
-    You should hopefully see the framework code with a 3D cube at the center of the screen!
+## About
 
+This project was created for the class CIS 700: Procedural Graphics, Spring 2017, at the University of Pennsylvania.
 
-## Developing Your Code
-All of the JavaScript code is living inside the `src` directory. The main file that gets executed when you load the page as you may have guessed is `main.js`. Here, you can make any changes you want, import functions from other files, etc. The reason that I highly suggest you build your project with `npm start` is that doing so will start a process that watches for any changes you make to your code. If it detects anything, it'll automagically rebuild your project and then refresh your browser window for you. Wow. That's cool. If you do it the other way, you'll need to run `npm build` and then refresh your page every time you want to test something.
+The base code can be found [here](https://github.com/CIS700-Procedural-Graphics/Project1-Noise).
 
-## Publishing Your Code
-We highly suggest that you put your code on GitHub. One of the reasons we chose to make this course using JavaScript is that the Web is highly accessible and making your awesome work public and visible can be a huge benefit when you're looking to score a job or internship. To aid you in this process, running `npm run deploy` will automatically build your project and push it to `gh-pages` where it will be visible at `username.github.io/repo-name`.
 
-## What is Actually Happening?
-You can skip this part if you really want, but I highly suggest you read it.
 
-### npm install
-`npm install` will install all dependencies into a folder called `node_modules`. That's about it.
-
-### package.json
-
-This is the important file that `npm` looks at. In it, you can see the commands it's using for the `start`, `build`, and `deploy` scripts mentioned above. You can also see all of the dependencies the project requires. I will briefly go through what each of these is.
- - dat-gui: Gives us a nice and simple GUI for modifying variables in our program
-
- - gl-matrix: Useful library for linear algebra, much like glm
-
- - stats-js: Gives us a nice graph for timing things. We use it to report how long it takes to render each frame
-
- - three: Three.js is the main library we're using to draw stuff
-
- - three-orbit-controls: Handles mouse / touchscreen camera controls
-
- - babel-core, babel-loader, babel-preset-es2015: JavaScript is a a really fast moving language. It is constantly, constantly changing. Unfortunately, web browsers don't keep up nearly as quickly. Babel does the job of converting your code to a form that current browsers support. This allows us to use newer JavaScript features such as classes and imports without worrying about compatibility.
-
- - gh-pages-deploy: This is the library that automates publishing your code to Github
-
- - webpack: Webpack serves the role of packaging your project into a single file. Browsers don't actually support "importing" from other files, so without Webpack, to access data and functions in other files we would need to globally define EVERYTHING. This is an extremely bad idea. Webpack lets us use imports and develop code in separate files. Running `npm build` or `npm start` is what bundles all of your code together.
-
-- webpack-dev-server: This is an extremely useful tool for development. It essentially creates a file watcher and rebuilds your project whenever you make changes. It also injects code into your page that gets notified when these changes occur so it can automatically refresh your page.
-
- - webpack-glsl-loader: Webpack does much more than just JavaScript. We can use it to load glsl, css, images, etc. For whatever you want to import, somebody has probably made a webpack loader for it.
-
-### webpack.config.js
-
-This is the configuration file in webpack. The most important part is `entry` and `output`. These define the input and output for webpack. It will start from `entry`, explore all dependencies, and package them all into `output`. Here, the `output` is `bundle.js`. If you look in `index.html`, you can see that the page is loading `bundle.js`, not `main.js`.
-
-The other sections are just configuration settings for `webpack-dev-server` and setup for loading different types of files.
-
-## Setting up a shader
-
-Using the provided framework code, create a new three.js material which references a vertex and fragment shader. Look at the adamMaterial for reference. It should reference at least one uniform variable (you'll need a time variable to animate your mesh later on).
-
-Create [an icosahedron](https://threejs.org/docs/index.html#Reference/Geometries/IcosahedronBufferGeometry), instead of the default cube geometry provided in the scene. Test your shader setup by applying the material to the icosahedron and color the mesh in the fragment shader using the normals' XYZ components as RGB.
-
-Note that three.js automatically injects several uniform and attribute variables into your shaders by default; they are listed in the [documentation](https://threejs.org/docs/api/renderers/webgl/WebGLProgram.html) for three.js's WebGLProgram class.
-
-## Noise Generation
-
-In the shader, write a 3D multi-octave lattice-value noise function that takes three input parameters and generates output in a controlled range, say [0,1] or [-1, 1]. This will require the following steps. 
-
-1. Write several (for however many octaves of noise you want) basic pseudo-random 3D noise functions (the hash-like functions we discussed in class). It's fine to reference one from the slides or elsewhere on the Internet. Again, this should just be a set of math operations, often using large prime numbers to random-looking output from three input parameters.
-
-2. Write an interpolation function. Lerp is fine, but for better results, we suggest cosine interpolation.
-
-3. (Optional) Write a smoothing function that will average the results of the noise value at some (x, y, z) with neighboring values, that is (x+-1, y+-1, z+-1).
-
-4. Write an 'interpolate noise' function that takes some (x, y, z) point as input and produces a noise value for that point by interpolating the surrounding lattice values (for 3D, this means the surrounding eight 'corner' points). Use your interpolation function and pseudo-random noise generator to accomplish this.
-
-5. Write a multi-octave noise generation function that sums multiple noise functions together, with each subsequent noise function increasing in frequency and decreasing in amplitude. You should use the interpolate noise function you wrote previously to accomplish this, as it generates a single octave of noise. The slides contain pseudocode for writing your multi-octave noise function.
-
-
-## Noise Application
-
-View your noise in action by applying it as a displacement on the surface of your icosahedron, giving your icosahedron a bumpy, cloud-like appearance. Simply take the noise value as a height, and offset the vertices along the icosahedron's surface normals. You are, of course, free to alter the way your noise perturbs your icosahedron's surface as you see fit; we are simply recommending an easy way to visualize your noise. You could even apply a couple of different noise functions to perturb your surface to make it even less spherical.
-
-In order to animate the vertex displacement, use time as the third dimension or as some offset to the (x, y, z) input to the noise function. Pass the current time since start of program as a uniform to the shaders.
-
-For both visual impact and debugging help, also apply color to your geometry using the noise value at each point. There are several ways to do this. For example, you might use the noise value to create UV coordinates to read from a texture (say, a simple gradient image), or just compute the color by hand by lerping between values.
-
-## Interactivity
-
-Using dat.GUI and the examples provided in the reference code, make some aspect of your demo an interactive variable. For example, you could add a slider to adjust the strength or scale of the noise, change the number of noise octaves, etc.
-
-## For the overachievers (extra credit)
-
-- More interactivity (easy): pretty self-explanatory. Make more aspects of your demo interactive by adding more controlable variables in the GUI.
-
-- Custom mesh (easy): Figure out how to import a custom mesh rather than using an icosahedron for a fancy-shaped cloud.
-
-- Mouse interactivity (medium): Find out how to get the current mouse position in your scene and use it to deform your cloud, such that users can deform the cloud with their cursor.
-
-- Music (hard): Figure out a way to use music to drive your noise animation in some way, such that your noise cloud appears to dance.
-
-## Submission
-
-- Update README.md to contain a solid description of your project
-
-- Publish your project to gh-pages. `npm run deploy`. It should now be visible at http://username.github.io/repo-name
-
-- Create a [pull request](https://help.github.com/articles/creating-a-pull-request/) to this repository, and in the comment, include a link to your published project.
-
-- Submit the link to your pull request on Canvas.

src/main.js

@@ -2,48 +2,168 @@
 const THREE = require('three'); // older modules are imported like this. You shouldn't have to worry about this much
 import Framework from './framework'
 
+var myIco;
+var noiseBlob = {
+  'Base Color': [200, 50, 50],
+  'Outer Color': [0, 0, 0],
+  'Inner Color': [255, 255, 100],
+  'Stripes': false,
+  'Stripe Density': 0.3,
+  'Pattern': false,
+  'Pattern Color': [0, 0, 0],
+  'Stripe Color': [255, 255, 255],
+  'Pattern Density': 0.5,
+  'Pixelate': false,
+  'Pixel Power': 2.0
+};
+
 // called after the scene loads
 function onLoad(framework) {
-  var scene = framework.scene;
-  var camera = framework.camera;
-  var renderer = framework.renderer;
-  var gui = framework.gui;
-  var stats = framework.stats;
-
-  // LOOK: the line below is synyatic sugar for the code above. Optional, but I sort of recommend it.
-  // var {scene, camera, renderer, gui, stats} = framework; 
+  var {scene, camera, renderer, gui, stats} = framework; 
 
   // initialize a simple box and material
   var box = new THREE.BoxGeometry(1, 1, 1);
-
-  var adamMaterial = new THREE.ShaderMaterial({
+
+  // Create a new material 
+  var velvetMaterial = new THREE.ShaderMaterial({
     uniforms: {
-      image: { // Check the Three.JS documentation for the different allowed types and values
-        type: "t", 
-        value: THREE.ImageUtils.loadTexture('./adam.jpg')
+      image: {
+       type: 't',
+        value: THREE.ImageUtils.loadTexture('./bh_velvet.jpg')
+      },
+      time: {
+        type: 'f',
+        value: 0.0
+      },
+      baseColor: {
+        type: 'v3',
+        value: new THREE.Vector3(
+            noiseBlob['Base Color'][0] / 255, 
+            noiseBlob['Base Color'][1] / 255, 
+            noiseBlob['Base Color'][2] / 255)
+      },
+      outerColor: {
+        type: 'v3',
+        value: new THREE.Vector3(
+            noiseBlob['Outer Color'][0] / 255, 
+            noiseBlob['Outer Color'][1] / 255, 
+            noiseBlob['Outer Color'][2] / 255)
+      },
+      innerColor: {
+        type: 'v3',
+        value: new THREE.Vector3(
+            noiseBlob['Inner Color'][0] / 255, 
+            noiseBlob['Inner Color'][1] / 255, 
+            noiseBlob['Inner Color'][2] / 255)
+      },
+      stripes: {
+        type: 'uInt',
+        value: noiseBlob['Stripes']
+      },
+      pattern: {
+        type: 'uInt',
+        value: noiseBlob['Pattern']
+      },
+      stripeDensity: {
+        type: 'f',
+        value: noiseBlob['Stripe Density']
+      },
+      patternColor: {
+        type: 'v3',
+        value: new THREE.Vector3(
+            noiseBlob['Pattern Color'][0] / 255, 
+            noiseBlob['Pattern Color'][1] / 255, 
+            noiseBlob['Pattern Color'][2] / 255)
+      },
+      stripeColor: {
+        type: 'v3',
+        value: new THREE.Vector3(
+            noiseBlob['Stripe Color'][0] / 255, 
+            noiseBlob['Stripe Color'][1] / 255, 
+            noiseBlob['Stripe Color'][2] / 255)
+      },
+      patternDensity: {
+        type: 'f',
+        value: noiseBlob['Pattern Density']
+      },
+      pixelate: {
+        type: 'uInt',
+        value: noiseBlob['Pixelate']
+      },
+      pixelPower: {
+        type: 'f',
+        value: noiseBlob['Pixel Power']
       }
     },
-    vertexShader: require('./shaders/adam-vert.glsl'),
-    fragmentShader: require('./shaders/adam-frag.glsl')
+    vertexShader: require('./shaders/ico-vert.glsl'),
+    fragmentShader: require('./shaders/ico-frag.glsl')
   });
-  var adamCube = new THREE.Mesh(box, adamMaterial);
+
+  // Create icosahedron
+  var icosahedron = new THREE.IcosahedronBufferGeometry(0.8, 5);
+  myIco = new THREE.Mesh(icosahedron, velvetMaterial);
+
 
   // set camera position
-  camera.position.set(1, 1, 2);
+  camera.position.set(1, 1, -100);
   camera.lookAt(new THREE.Vector3(0,0,0));
-
-  scene.add(adamCube);
+  scene.add(myIco);
 
   // edit params and listen to changes like this
   // more information here: https://workshop.chromeexperiments.com/examples/gui/#1--Basic-Usage
   gui.add(camera, 'fov', 0, 180).onChange(function(newVal) {
     camera.updateProjectionMatrix();
   });
+
+  gui.addColor(noiseBlob, 'Base Color').onChange(function (value) {
+    myIco.material.uniforms.baseColor.value = new THREE.Vector3(value[0] / 255, value[1] / 255, value[2] / 255);
+  });
+  gui.addColor(noiseBlob, 'Outer Color').onChange(function (value) {
+    myIco.material.uniforms.outerColor.value = new THREE.Vector3(value[0] / 255, value[1] / 255, value[2] / 255);
+  });
+  gui.addColor(noiseBlob, 'Inner Color').onChange(function (value) {
+    myIco.material.uniforms.innerColor.value = new THREE.Vector3(value[0] / 255, value[1] / 255, value[2] / 255);
+  });
+
+  gui.add(noiseBlob, 'Stripes').onChange(function (value) {
+    myIco.material.uniforms.stripes.value = value;
+  });
+
+  gui.add(noiseBlob, 'Stripe Density', 0, 1).onChange(function (value) {
+    myIco.material.uniforms.stripeDensity.value = value;
+  });
+  gui.addColor(noiseBlob, 'Stripe Color').onChange(function (value) {
+    myIco.material.uniforms.stripeColor.value = new THREE.Vector3(value[0] / 255, value[1] / 255, value[2] / 255);
+  });
+
+  gui.add(noiseBlob, 'Pattern').onChange(function (value) {
+    myIco.material.uniforms.pattern.value = value;
+  });
+
+  gui.addColor(noiseBlob, 'Pattern Color').onChange(function (value) {
+    myIco.material.uniforms.patternColor.value = new THREE.Vector3(value[0] / 255, value[1] / 255, value[2] / 255);
+  });
+
+  gui.add(noiseBlob, 'Pattern Density', 0, 1).onChange(function (value) {
+    myIco.material.uniforms.patternDensity.value = value;
+  }); 
+
+  gui.add(noiseBlob, 'Pixelate').onChange(function (value) {
+    myIco.material.uniforms.pixelate.value = value;
+  }); 
+
+  gui.add(noiseBlob, 'Pixel Power', 0, 5).onChange(function (value) {
+    myIco.material.uniforms.pixelPower.value = value;
+  }); 
+
 }
 
+var incr = 0.01279;
 // called on frame updates
 function onUpdate(framework) {
-  console.log(`the time is ${new Date()}`);
+  if (myIco) {
+    myIco.material.uniforms.time.value += incr;
+  }
 }
 
 // when the scene is done initializing, it will call onLoad, then on frame updates, call onUpdate

src/shaders/ico-frag.glsl

@@ -0,0 +1,44 @@
+varying vec2 vUv;
+varying float noise;
+varying float noise2;
+uniform sampler2D image;
+varying vec3 color; 
+uniform float time;
+uniform vec3 baseColor;
+uniform vec3 outerColor;
+uniform vec3 innerColor;
+uniform bool stripes;
+uniform float stripeDensity;
+uniform bool pattern;
+uniform vec3 patternColor;
+uniform vec3 stripeColor;
+uniform float patternDensity;
+
+void main() {
+  vec4 color =  texture2D( image, vUv );
+  vec4 base_color = vec4(baseColor, 1.0);
+  color += base_color / 1.5;
+
+  vec4 outer = vec4(outerColor, 1.0);
+  vec4 inner = vec4(innerColor, 1.0);
+
+  color += outer * noise / 40.0;
+  color -= (vec4(1,1,1,1) - outer) / 1.5;
+  color += inner *  5.0 / noise;
+
+  if (pattern) {
+	  if (mod(floor(noise * patternDensity * 8.0), floor(noise2 * 50.0)) < 4.0){
+	  	color = vec4(patternColor, 1.0);
+	  }
+	}
+
+	if (stripes) {
+	  if(mod(floor(noise * stripeDensity * 30.0), 8.0) == 0.0 ) {
+	  	color = vec4(stripeColor, 1.0);
+	  }
+	}
+
+  gl_FragColor = vec4( color.rgb, 1.0 );
+
+}
+