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Beginning to reverse-engineer FizzyText

TOTALLY SUPER DUPER NOT MY WORK! Trying to illuminate how FizzyText (seen here, source here, isolated from dat.GUI dependency here) works. Original appears to have been written by George Michael Brower.

In the original, which I find brilliant:

  • Solid black text is drawn onto an invisible canvas, from which it gets bitmap data
  • The bitmap data is read like a collision detection array, where black means "you're on top of text" and white means "you're not"
  • Particles of size r=0 are randomly spawned on a visible canvas
  • The particles grow if they're on top of a (non-rendered) black pixel, and shrink till they disappear if not
  • When they shrink to r=0, they respawn randomly somewhere
  • The particles follow a Perlin noise flow field, a very sensible and fluid kind of random movement, in which nearby particles move similarly

I've made two changes:

  • Particles don't disappear all the way
  • They loop around the canvas like a torus instead of respawning (so eventually fall into 'attractor' channels or whatever)

This just serves to illustrate (for my own benefit) how the original works, in the hopes of maybe ripping it off in some cool way.

I think the whole thing is brilliant — using a particle system to render text, using an invisible canvas's color data as collision detection, and the Perlin flow field.

// http://mrl.nyu.edu/~perlin/noise/
var ImprovedNoise = function () {
var p = [151,160,137,91,90,15,131,13,201,95,96,53,194,233,7,225,140,36,103,30,69,142,8,99,37,240,21,10,
23,190,6,148,247,120,234,75,0,26,197,62,94,252,219,203,117,35,11,32,57,177,33,88,237,149,56,87,
174,20,125,136,171,168,68,175,74,165,71,134,139,48,27,166,77,146,158,231,83,111,229,122,60,211,
133,230,220,105,92,41,55,46,245,40,244,102,143,54,65,25,63,161,1,216,80,73,209,76,132,187,208,
89,18,169,200,196,135,130,116,188,159,86,164,100,109,198,173,186,3,64,52,217,226,250,124,123,5,
202,38,147,118,126,255,82,85,212,207,206,59,227,47,16,58,17,182,189,28,42,223,183,170,213,119,
248,152,2,44,154,163,70,221,153,101,155,167,43,172,9,129,22,39,253,19,98,108,110,79,113,224,232,
178,185,112,104,218,246,97,228,251,34,242,193,238,210,144,12,191,179,162,241,81,51,145,235,249,
14,239,107,49,192,214,31,181,199,106,157,184,84,204,176,115,121,50,45,127,4,150,254,138,236,205,
93,222,114,67,29,24,72,243,141,128,195,78,66,215,61,156,180];
for ( var i = 0; i < 256 ; i++ ) {
p[ 256 + i ] = p[ i ];
}
function fade( t ) {
return t * t * t * ( t * ( t * 6 - 15 ) + 10 );
}
function lerp( t, a, b ) {
return a + t * ( b - a );
}
function grad( hash, x, y, z ) {
var h = hash & 15;
var u = h < 8 ? x : y, v = h < 4 ? y : h == 12 || h == 14 ? x : z;
return ( ( h & 1 ) == 0 ? u : -u ) + ( ( h & 2 ) == 0 ? v : -v );
}
return {
noise: function ( x, y, z ) {
var floorX = Math.floor( x ), floorY = Math.floor( y ), floorZ = Math.floor( z );
var X = floorX & 255, Y = floorY & 255, Z = floorZ & 255;
x -= floorX;
y -= floorY;
z -= floorZ;
var xMinus1 = x -1, yMinus1 = y - 1, zMinus1 = z - 1;
var u = fade( x ), v = fade( y ), w = fade( z );
var A = p[ X ] + Y, AA = p[ A ] + Z, AB = p[ A + 1 ] + Z, B = p[ X + 1 ] + Y, BA = p[ B ] + Z, BB = p[ B + 1 ] + Z;
return lerp( w, lerp( v, lerp( u, grad( p[ AA ], x, y, z ),
grad( p[ BA ], xMinus1, y, z ) ),
lerp( u, grad( p[ AB ], x, yMinus1, z ),
grad( p[ BB ], xMinus1, yMinus1, z ) ) ),
lerp( v, lerp( u, grad( p[ AA + 1 ], x, y, zMinus1 ),
grad( p[ BA + 1 ], xMinus1, y, z - 1 ) ),
lerp( u, grad( p[ AB + 1 ], x, yMinus1, zMinus1 ),
grad( p[ BB + 1 ], xMinus1, yMinus1, zMinus1 ) ) ) );
}
}
}
var currentRandom = Math.random;
// Pseudo-random generator
function Marsaglia(i1, i2) {
// from http://www.math.uni-bielefeld.de/~sillke/ALGORITHMS/random/marsaglia-c
var z=i1 || 362436069, w= i2 || 521288629;
var nextInt = function() {
z=(36969*(z&65535)+(z>>>16)) & 0xFFFFFFFF;
w=(18000*(w&65535)+(w>>>16)) & 0xFFFFFFFF;
return (((z&0xFFFF)<<16) | (w&0xFFFF)) & 0xFFFFFFFF;
};
this.nextDouble = function() {
var i = nextInt() / 4294967296;
return i < 0 ? 1 + i : i;
};
this.nextInt = nextInt;
}
Marsaglia.createRandomized = function() {
var now = new Date();
return new Marsaglia((now / 60000) & 0xFFFFFFFF, now & 0xFFFFFFFF);
};
// Noise functions and helpers
function PerlinNoise(seed) {
var rnd = seed !== undefined ? new Marsaglia(seed) : Marsaglia.createRandomized();
var i, j;
// http://www.noisemachine.com/talk1/17b.html
// http://mrl.nyu.edu/~perlin/noise/
// generate permutation
var p = new Array(512);
for(i=0;i<256;++i) { p[i] = i; }
for(i=0;i<256;++i) { var t = p[j = rnd.nextInt() & 0xFF]; p[j] = p[i]; p[i] = t; }
// copy to avoid taking mod in p[0];
for(i=0;i<256;++i) { p[i + 256] = p[i]; }
function grad3d(i,x,y,z) {
var h = i & 15; // convert into 12 gradient directions
var u = h<8 ? x : y,
v = h<4 ? y : h===12||h===14 ? x : z;
return ((h&1) === 0 ? u : -u) + ((h&2) === 0 ? v : -v);
}
function grad2d(i,x,y) {
var v = (i & 1) === 0 ? x : y;
return (i&2) === 0 ? -v : v;
}
function grad1d(i,x) {
return (i&1) === 0 ? -x : x;
}
function lerp(t,a,b) { return a + t * (b - a); }
this.noise3d = function(x, y, z) {
var X = Math.floor(x)&255, Y = Math.floor(y)&255, Z = Math.floor(z)&255;
x -= Math.floor(x); y -= Math.floor(y); z -= Math.floor(z);
var fx = (3-2*x)*x*x, fy = (3-2*y)*y*y, fz = (3-2*z)*z*z;
var p0 = p[X]+Y, p00 = p[p0] + Z, p01 = p[p0 + 1] + Z, p1 = p[X + 1] + Y, p10 = p[p1] + Z, p11 = p[p1 + 1] + Z;
return lerp(fz,
lerp(fy, lerp(fx, grad3d(p[p00], x, y, z), grad3d(p[p10], x-1, y, z)),
lerp(fx, grad3d(p[p01], x, y-1, z), grad3d(p[p11], x-1, y-1,z))),
lerp(fy, lerp(fx, grad3d(p[p00 + 1], x, y, z-1), grad3d(p[p10 + 1], x-1, y, z-1)),
lerp(fx, grad3d(p[p01 + 1], x, y-1, z-1), grad3d(p[p11 + 1], x-1, y-1,z-1))));
};
this.noise2d = function(x, y) {
var X = Math.floor(x)&255, Y = Math.floor(y)&255;
x -= Math.floor(x); y -= Math.floor(y);
var fx = (3-2*x)*x*x, fy = (3-2*y)*y*y;
var p0 = p[X]+Y, p1 = p[X + 1] + Y;
return lerp(fy,
lerp(fx, grad2d(p[p0], x, y), grad2d(p[p1], x-1, y)),
lerp(fx, grad2d(p[p0 + 1], x, y-1), grad2d(p[p1 + 1], x-1, y-1)));
};
this.noise1d = function(x) {
var X = Math.floor(x)&255;
x -= Math.floor(x);
var fx = (3-2*x)*x*x;
return lerp(fx, grad1d(p[X], x), grad1d(p[X+1], x-1));
};
}
// these are lifted from Processing.js
// processing defaults
var noiseProfile = { generator: undefined, octaves: 4, fallout: 0.5, seed: undefined};
function noise(x, y, z) {
if(noiseProfile.generator === undefined) {
// caching
noiseProfile.generator = new PerlinNoise(noiseProfile.seed);
}
var generator = noiseProfile.generator;
var effect = 1, k = 1, sum = 0;
for(var i=0; i<noiseProfile.octaves; ++i) {
effect *= noiseProfile.fallout;
switch (arguments.length) {
case 1:
sum += effect * (1 + generator.noise1d(k*x))/2; break;
case 2:
sum += effect * (1 + generator.noise2d(k*x, k*y))/2; break;
case 3:
sum += effect * (1 + generator.noise3d(k*x, k*y, k*z))/2; break;
}
k *= 2;
}
return sum;
};
<!doctype html>
<html>
<head>
<title>FizzyText</title>
<script src='improvedNoise.js'></script>
<script src='main.js'></script>
<script>
window.onload = function() {
var fizzyText = new FizzyText('Fizzy Text!');
};
</script>
</head>
<body>
<div id='fizzytext'></div>
</body>
</html>
function FizzyText(message) {
var that = this;
// These are the variables that we manipulate with gui-dat.
// Notice they're all defined with "this". That makes them public.
// Otherwise, gui-dat can't see them.
this.growthSpeed = 0.2; // how fast do particles change size?
this.minSize = 1;
this.maxSize = 5.59; // how big can they get?
this.noiseStrength = 10; // how turbulent is the flow?
this.speed = 0.4; // how fast do particles move?
this.displayOutline = true; // should we draw the message as a stroke?
this.framesRendered = 0;
////////////////////////////////////////////////////////////////
var _this = this;
var width = 550;
var height = 200;
var textAscent = 101;
var textOffsetLeft = 80;
var noiseScale = 300;
var frameTime = 30;
var colors = ["#00aeff", "#0fa954", "#54396e", "#e61d5f"];
// This is the context we use to get a bitmap of text using
// the getImageData function.
var r = document.createElement('canvas');
var s = r.getContext('2d');
// This is the context we actually use to draw.
var c = document.createElement('canvas');
var g = c.getContext('2d');
r.setAttribute('width', width);
c.setAttribute('width', width);
r.setAttribute('height', height);
c.setAttribute('height', height);
// Add our demo to the HTML
document.getElementById('fizzytext').appendChild(c);
// Stores bitmap image
var pixels = [];
// Stores a list of particles
var particles = [];
// Set g.font to the same font as the bitmap canvas, incase we
// want to draw some outlines.
s.font = g.font = "800 82px helvetica, arial, sans-serif";
// Instantiate some particles
for (var i = 0; i < 1000; i++) {
particles.push(new Particle(Math.random() * width, Math.random() * height));
}
// This function creates a bitmap of pixels based on your message
// It's called every time we change the message property.
var createBitmap = function (msg) {
s.fillStyle = "#fff";
s.fillRect(0, 0, width, height);
s.fillStyle = "#222";
s.fillText(msg, textOffsetLeft, textAscent);
// Pull reference
var imageData = s.getImageData(0, 0, width, height);
pixels = imageData.data;
};
// Called once per frame, updates the animation.
var render = function () {
that.framesRendered ++;
g.clearRect(0, 0, width, height);
if (_this.displayOutline) {
g.globalCompositeOperation = "source-over";
g.strokeStyle = "#000";
g.lineWidth = .5;
g.strokeText(message, textOffsetLeft, textAscent);
}
g.globalCompositeOperation = "darker";
for (var i = 0; i < particles.length; i++) {
g.fillStyle = colors[i % colors.length];
particles[i].render();
}
};
// Returns x, y coordinates for a given index in the pixel array.
var getPosition = function (i) {
return {
x: (i - (width * 4) * Math.floor(i / (width * 4))) / 4,
y: Math.floor(i / (width * 4))
};
};
// Returns a color for a given pixel in the pixel array.
var getColor = function (x, y) {
var base = (Math.floor(y) * width + Math.floor(x)) * 4;
var c = {
r: pixels[base + 0],
g: pixels[base + 1],
b: pixels[base + 2],
a: pixels[base + 3]
};
return "rgb(" + c.r + "," + c.g + "," + c.b + ")";
};
this.message = message;
createBitmap(message);
var loop = function() {
requestAnimationFrame(loop);
render();
}
// This calls the render function every 30 milliseconds.
loop();
// This class is responsible for drawing and moving those little
// colored dots.
function Particle(x, y, c) {
// Position
this.x = x;
this.y = y;
// Size of particle
this.r = 1;
// This velocity is used by the explode function.
this.vx = 0;
this.vy = 0;
this.constrain = function (v, o1, o2) {
if (v < o1) v = o1;
else if (v > o2) v = o2;
return v;
};
// Called every frame
this.render = function () {
// What color is the pixel we're sitting on top of?
var c = getColor(this.x, this.y);
// Where should we move?
var angle = noise(this.x / noiseScale, this.y / noiseScale) * _this.noiseStrength;
// var angle = -Math.PI/2;
// Are we within the boundaries of the image?
var onScreen = this.x > 0 && this.x < width &&
this.y > 0 && this.y < height;
var isBlack = c != "rgb(255,255,255)" && onScreen;
// If we're on top of a black pixel, grow.
// If not, shrink.
if (isBlack) {
this.r += _this.growthSpeed;
} else {
this.r -= _this.growthSpeed;
}
// This velocity is used by the explode function.
this.vx *= 0.5;
this.vy *= 0.5;
// Change our position based on the flow field and our
// explode velocity.
this.x += Math.cos(angle) * _this.speed + this.vx;
this.y += -Math.sin(angle) * _this.speed + this.vy;
// this.r = 3;
// debugger
// console.log(DAT.GUI.constrain(this.r, 0, _this.maxSize));
this.r = this.constrain(this.r, _this.minSize, _this.maxSize);
// If we're tiny, keep moving around until we find a black
// pixel.
// if (this.r <= 0) {
// this.x = Math.random() * width;
// this.y = Math.random() * height;
// return; // Don't draw!
// }
// If we're off the screen, go over to other side
if(this.x < 0) this.x = width;
if(this.x > width) this.x = 0;
if(this.y < 0) this.y = height;
if(this.y > height) this.y = 0;
// Draw the circle.
g.beginPath();
g.arc(this.x, this.y, this.r, 0, Math.PI * 2, false);
g.fill();
}
}
}
@ntr-808
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ntr-808 commented Sep 18, 2018

thanks for this, hoping to use it in a game i'm making. will be in touch if it sees the light of day!

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