<script>
var fragCode =`
precision highp float;
uniform vec2 resolution;
uniform vec3 eye;
uniform vec3 lightPos;
uniform float time;
// https://www.iquilezles.org/www/articles/distfunctions/distfunctions.htm
// distance functions
float dot2( in vec2 v ) {
return dot(v,v);
}
float sdCappedCone( in vec3 p, in float h, in float r1, in float r2 ){
vec2 q = vec2( length(p.xz), p.y );
vec2 k1 = vec2(r2,h);
vec2 k2 = vec2(r2-r1,2.0*h);
vec2 ca = vec2(q.x-min(q.x,(q.y < 0.0)?r1:r2), abs(q.y)-h);
vec2 cb = q - k1 + k2*clamp( dot(k1-q,k2)/dot2(k2), 0.0, 1.0 );
float s = (cb.x < 0.0 && ca.y < 0.0) ? -1.0 : 1.0;
return s*sqrt( min(dot2(ca),dot2(cb)) );
}
// vertical
float sdCylinder( vec3 p, vec2 h ){
vec2 d = abs(vec2(length(p.xz),p.y)) - h;
return min(max(d.x,d.y),0.0) + length(max(d,0.0));
}
float sdSphere( vec3 p, float s ){
return length(p)-s;
}
float sdPlane( vec3 p , float down){
return p.y - down;
}
float plane(vec3 p, vec3 n, float offs) {
return dot(p, n) - offs;
}
// distance functions operations
float opS( float d1, float d2 ){
return max(-d2,d1);
}
vec2 opU( vec2 d1, vec2 d2 ){
return (d1.x<d2.x) ? d1 : d2;
}
vec3 opRep( vec3 p, vec3 c ){
return mod(p,c)-0.5*c;
}
float opSmoothU( float d1, float d2, float k ) {
float h = clamp( 0.5 + 0.5*(d2-d1)/k, 0.0, 1.0 );
return mix( d2, d1, h ) - k*h*(1.0-h);
}
vec2 rotate(vec2 p, float ang) {
float c = cos(ang), s = sin(ang);
return vec2(p.x*c - p.y*s, p.x*s + p.y*c);
}
vec2 repeatAng(vec2 p, float n) {
float ang = 2.0*3.14/n;
float sector = floor(atan(p.x, p.y)/ang + 0.5);
p = rotate(p, sector*ang);
return p;
}
///
const float PI =3.141592;
const float PI2 = 6.2831853;
const float maxd = 256.0; //Max depth
float nearestD = maxd;
vec3 color = vec3(0.0, 0.0, 1.0);
float flakes(vec3 p) {
const float snowflakeMaxDist = 20.0;
if ( (abs(p.x) > snowflakeMaxDist) ||
(abs(p.y) > snowflakeMaxDist) ||
(abs(p.z) > snowflakeMaxDist) )
return 9999.9;
float snowPush = 0.25*time;
p.x += snowPush*-3.0;
p.y += snowPush*1.5;
p.z += snowPush*-0.25;
const float modDist = 2.0;
float stepX = floor(p.x/modDist);
float stepY = floor(p.y/modDist);
float stepZ = floor(p.z/modDist);
vec3 flakeP = vec3(
mod(p.x,modDist),
mod(p.y,modDist),
mod(p.z,modDist)
);
vec3 flakePos = vec3(modDist*0.5);
flakePos.x += sin(snowPush+stepY*1.0)*(2.0/5.0)*modDist;
flakePos.y += sin(snowPush+stepZ*1.3)*(2.0/5.0)*modDist;
flakePos.z += sin(snowPush+stepX*1.7)*(2.0/5.0)*modDist;
return sdSphere(flakeP- flakePos, 0.03);
}
// noise
float hash(vec3 p) {
p = fract( p*0.3183099+.1 );
p *= 17.0;
return fract( p.x*p.y*p.z*(p.x+p.y+p.z) );
}
float noise( in vec3 x ){
vec3 p = floor(x);
vec3 f = fract(x);
f = f*f*(3.0-2.0*f);
return mix(mix(mix( hash(p+vec3(0,0,0)),
hash(p+vec3(1,0,0)),f.x),
mix( hash(p+vec3(0,1,0)),
hash(p+vec3(1,1,0)),f.x),f.y),
mix(mix( hash(p+vec3(0,0,1)),
hash(p+vec3(1,0,1)),f.x),
mix( hash(p+vec3(0,1,1)),
hash(p+vec3(1,1,1)),f.x),f.y),f.z);
}
float noise( vec2 x ){
return noise(vec3(x, 0.));
}
const float VERY_FAR = 1e11;
float ground(vec3 p){
float d = -0.50 ;
p.y += noise(p)*.33 ;
d = sdPlane(p, d);
return d;
}
vec2 star(vec3 p) {
p.y -=1.5;
p.xy = repeatAng(p.xy, 5.0); // 3. Clone five cornders radially about Z axis
p.xz = abs(p.xz); // 2. Symmetrical about XoY and ZoY
vec3 n = vec3(0.5, 0.25, 0.8);
float d = plane(p, normalize(n), 0.065); // 1. A plane cutting the corner of X+Y+Z+
return vec2(d, .900 );
}
vec2 green(vec3 p) {
float d = VERY_FAR;
float k = .12;
d = sdCappedCone( p - vec3(.0, .99, .0), .4, 0.45, .0);
d = opSmoothU(d, sdCappedCone( p - vec3(.0, .55, .0), .5, 0.55, .0), k);
d = opSmoothU(d, sdCappedCone( p - vec3(.0, .11, .0), .6, 0.65, .0), k);
return vec2( d, 0.090 );
}
vec2 trunk(vec3 p) {
float d = VERY_FAR;
d = sdCylinder(p-vec3(.0, -.5,.0), vec2(0.1, 0.6));
return vec2( d, 0.000 );
}
vec2 toy(vec3 p, float col) {
float d = VERY_FAR;
d = sdSphere(p, 0.07);
return vec2( d, col );
}
vec2 toys(vec3 p) {
vec2 res = vec2(VERY_FAR, -1);
float r = .42;
float h = -0.57;
res = opU( res, toy(p-vec3(-r, h, -r), 0.990) );
res = opU( res, toy(p-vec3(-r, h, r), 0.099) );
res = opU( res, toy(p-vec3( r, h, -r), 0.999) );
res = opU( res, toy(p-vec3( r, h, r), 0.555) );
r = .3;
h = 0.5;
res = opU( res, toy(p-vec3(-r, h, -r), 0.990) );
res = opU( res, toy(p-vec3(-r, h, r), 0.099) );
res = opU( res, toy(p-vec3( r, h, -r), 0.999) );
res = opU( res, toy(p-vec3( r, h, r), 0.555) );
r = .5;
h = -0.05;
res = opU( res, toy(p-vec3(-r, h, 0.), 0.990) );
res = opU( res, toy(p-vec3( 0, h, -r), 0.099) );
res = opU( res, toy(p-vec3( r, h, 0.), 0.999) );
res = opU( res, toy(p-vec3( 0, h, r), 0.555) );
return res;
}
vec2 tree(vec3 p) {
vec2 res = vec2(VERY_FAR, -1);
res = opU( res, green(p) );
res = opU( res, trunk(p) );
res = opU( res, star(p) );
res = opU( res, toys(p) );
return res;
}
float snowmans(vec3 p) {
// mirror 3
p.xz = repeatAng(p.xz, 3.0);
p.xz = abs(p.xz);
float k = .12;
float d = sdSphere( p - vec3(1.5, 0.7, 3.0), .2);
d = opSmoothU(d, sdSphere( p - vec3(1.5, 0.2, 3.0), .3), k);
d = opSmoothU(d, sdSphere( p - vec3(1.5, -0.4, 3.0), .4), k);
return d;
}
float snowfall(vec3 p) {
vec3 q = vec3(mod(p.x, 3.0) - 1.5, p.yz);
return sdSphere( q - vec3(1.5, 0.7, 3.0), .02);
}
vec2 snow(vec3 p) {
float k = .12;
float d = ground(p);
d = opSmoothU(d, snowmans( p ), k);
d = opSmoothU( d, flakes(p), k );
return vec2( d, .999 );
}
vec2 snowmans_accesories(vec3 p) {
// mirror 3
p.xz = repeatAng(p.xz, 3.0);
p.xz = abs(p.xz);
float k = .12;
vec2 res = vec2(sdSphere( p - vec3(1.50, 0.70, 3.20), .02), 0.00 );
res = opU(res, vec2(sdSphere( p - vec3(1.44, 0.75, 3.18), .02), 0.00 ));
res = opU(res, vec2(sdSphere( p - vec3(1.56, 0.75, 3.18), .02), 0.00 ));
res = opU(res, vec2(sdSphere( p - vec3(1.50, 0.25, 3.30), .02), 0.00 ));
res = opU(res, vec2(sdSphere( p - vec3(1.50, -0.40, 3.40), .02), 0.00 ));
return res;
}
vec2 map(vec3 p) {
vec2 res = vec2(VERY_FAR, -1);
res = opU( res, snow(p) );
res = opU( res, snowmans_accesories(p) );
res = opU( res, tree(p) );
return res;
}
// ray direction
vec3 rayDirection(float fieldOfView, vec2 size) {
vec2 xy = gl_FragCoord.xy - size / 2.0;
float z = size.y / tan(radians(fieldOfView) / 2.0);
return normalize(vec3(xy, -z));
}
// compute view matrix
mat4 viewMatrix(vec3 eye, vec3 center, vec3 up) {
vec3 f = normalize(center - eye);
vec3 s = normalize(cross(f, up));
vec3 u = cross(s, f);
return mat4(
vec4(s, 0.0),
vec4(u, 0.0),
vec4(-f, 0.0),
vec4(0.0, 0.0, 0.0, 1)
);
}
// ro - ray origin
// rd - ray direction
vec2 castRay( in vec3 ro, in vec3 rd ) {
float tmin = 1.0;
float tmax = 32.0;
float t = tmin;
float m = -1.0;
for ( int i=0; i<128; i++ ) {
float precis = 0.0001*t;
vec2 res = map( ro+rd*t );
if ( res.x<precis || t>tmax )
break;
t += res.x/1.4;
m = res.y;
}
if ( t>tmax )
m=-1.0;
return vec2( t, m );
}
// estimate normal at point
// http://iquilezles.org/www/articles/normalsSDF/normalsSDF.htm
const float NORMAL_EPSILON = 0.0005;
vec3 estimateNormal(vec3 pos) {
vec2 e = vec2(1.0,-1.0)*0.5773*NORMAL_EPSILON;
return normalize( e.xyy*map( pos + e.xyy ).x +
e.yyx*map( pos + e.yyx ).x +
e.yxy*map( pos + e.yxy ).x +
e.xxx*map( pos + e.xxx ).x );
}
const vec3 K_a = vec3(.3, .2, .2);
const vec3 K_d = vec3(.2, .4, .7);
const vec3 K_s = vec3(.1, .1, .1);
const float shininess = 3.5;
const vec3 lightIntensity = vec3(0.7, 0.7, 0.7);
vec3 phongContribForLight(vec3 k_d, vec3 k_s, float alpha, vec3 p, vec3 eye,
vec3 lightPos, vec3 lightIntensity) {
vec3 N = estimateNormal(p);
vec3 L = normalize(lightPos - p);
vec3 V = normalize(eye - p);
vec3 R = normalize(reflect(-L, N));
float dotLN = dot(L, N);
float dotRV = dot(R, V);
if (dotLN < 0.0) {
// Light not visible from this point on the surface
return vec3(0.0, 0.0, 0.0);
}
if (dotRV < 0.0) {
// Light reflection in opposite direction as viewer, apply only diffuse
// component
return lightIntensity * (k_d * dotLN);
}
return lightIntensity * (k_d * dotLN + k_s * pow(dotRV, alpha));
}
vec3 phongIllumination(vec3 k_a, vec3 k_d, vec3 k_s, float alpha, vec3 p, vec3 eye, vec3 materialColor) {
vec3 color = materialColor * k_a;
color += phongContribForLight(k_d, k_s, alpha, p, eye, lightPos, lightIntensity);
return color;
}
vec3 decodeMaterialColor(float material) {
float r = material * 10.;
r = r - fract(r);
r = r/10.;
float g = material * 100. - r * 100.;
g = g - fract(g);
g = g/10.;
float b = material * 1000. - r * 1000. - g * 100.;
b = b - fract(b);
b = b/10.;
return vec3(r, g, b);
}
vec3 phong(vec3 p, vec3 eye, float material) {
vec3 materialColor = decodeMaterialColor(material);
return phongIllumination(K_a, K_d, K_s, shininess, p, eye, materialColor);
}
// http://iquilezles.org/www/articles/rmshadows/rmshadows.htm
float softShadow( in vec3 ro, in vec3 rd, in float mint, in float tmax ){
float res = 1.0;
float t = mint;
for( int i=0; i<12; i++ )
{
float h = map( ro + rd*t ).x;
res = min( res, 8.0*h/t );
t += clamp( h, 0.02, 0.10 );
if( res<0.005 || t>tmax ) break;
}
return clamp( res, 0.0, 1.0 );
}
// ambient occlusion
float ao( in vec3 pos, in vec3 nor ){
float occ = 0.0;
float sca = 1.0;
for( int i=0; i<5; i++ )
{
float hr = 0.01 + 0.12*float(i)/4.0;
vec3 aopos = nor * hr + pos;
float dd = map( aopos ).x;
occ += -(dd-hr)*sca;
sca *= 0.95;
}
return clamp( 1.0 - 3.0*occ, 0.0, 1.0 );
}
void main(void) {
vec3 direction = rayDirection(60.0, resolution);
mat4 viewToWorld = viewMatrix(eye, vec3(0.0, 0.0, 0.0), vec3(0.0, 1.0, 0.0));
vec3 worldDir = (viewToWorld * vec4(direction, 0.0)).xyz;
vec2 dist = castRay(eye, worldDir);
if (dist.x > 24.) {
gl_FragColor = vec4(0.9, 0.9, 0.9, 1.0);
} else {
vec3 pt = eye + dist.x * worldDir;
vec3 nor = estimateNormal( pt );
float occ = ao( pt, nor );
float shadow = softShadow( pt, normalize(lightPos-pt), 0.1, 22.2);
vec3 color = phong(pt, eye, dist.y)*sqrt(occ);
color += color * shadow;
gl_FragColor = vec4(color, 1.0);
}
}
`;
</script>
<script>
function GLx() {
var canvas = document.createElement('canvas');
document.body.appendChild(canvas);
var gl = canvas.getContext('webgl') || canvas.getContext('experimental-webgl');
return {
gl: gl,
buffer: buffer,
program: program,
resize: resize
};
function program(vs, fs) {
var pid = gl.createProgram(); // program id
shader(vs, gl.VERTEX_SHADER);
shader(fs, gl.FRAGMENT_SHADER);
gl.linkProgram(pid);
var p = {
uniform: uniform,
attribute: attribute,
use: use
};
return p;
function use() {
gl.useProgram(pid);
return p;
}
function attribute(name, count) {
var al = gl.getAttribLocation(pid, name);
return {
bind: bind
};
function bind(buffer) {
buffer.bind();
gl.vertexAttribPointer(al, count, gl.FLOAT, false, 0, 0);
gl.enableVertexAttribArray(al);
}
}
function uniform(type, name) {
var ul = gl.getUniformLocation(pid, name);
return {
set: set
};
function set(v1, v2, v3, v4) {
gl['uniform' + type](ul, v1, v2, v3, v4);
}
}
function shader(src, type) {
var sid = gl.createShader(type);
gl.shaderSource(sid, src);
gl.compileShader(sid);
var message = gl.getShaderInfoLog(sid);
if (message.length > 0){
console.log(src.split('\n').map(function (str, i) {
return ("" + (1 + i)).padStart(4, "0") + ": " + str
}).join('\n'));
throw message;
}
gl.attachShader(pid, sid);
}
}
function buffer(data) {
var array = new Float32Array(data);
var buffer = gl.createBuffer();
var type = gl.ARRAY_BUFFER;
gl.bindBuffer(type, buffer);
gl.bufferData(type, array, gl.STATIC_DRAW);
gl.bindBuffer(type, data = null);
return {
bind: bind
};
function bind() {
gl.bindBuffer(type, buffer);
}
}
function resize() {
var c = canvas;
if (c.clientWidth !== c.width || c.clientHeight !== c.height) {
c.width = c.clientWidth;
c.height = c.clientHeight;
return true;
}
}
}
// full-screen-triangle with webgl
function FullScreenTriangle(fragCode) {
var glx = GLx();
var vertices = glx.buffer([-1, 3, -1, -1, 3, -1]);
var vertCode =
`attribute vec2 coords;
void main(void) {
gl_Position = vec4(coords.xy, 0.0, 1.0);
}`;
glx.triangleProgram = glx.program(vertCode, 'precision highp float;' + fragCode).use();
glx.triangleProgram.attribute("coords", 2).bind(vertices);
glx.draw = function () {
var gl = glx.gl;
glx.resize();
gl.viewport(0, 0, gl.drawingBufferWidth, gl.drawingBufferHeight);
gl.clearColor(0, 0, 0, 1);
gl.drawArrays(gl.TRIANGLES, 0, 3);
};
return glx;
}
var Mouse3D = (function(){
var theta = 0;
var phi = 0;
var mouse = {x: 0, y: 0};
var radius = 7;
var dragStartMousePosition, dragStartPhi, dragStartTheta;
var callback;
var mouse3d = {
init: init,
eye: [0, 0, radius],
callback: function (cb) {
callback = cb;
}
};
return mouse3d;
function init() {
window.addEventListener('mousemove', mouseMove, false);
window.addEventListener('mouseup', mouseUp, false);
window.addEventListener('mousedown', mouseDown, false);
window.addEventListener('mousewheel', mouseWheel, false);
}
function mouseMove(event) {
if (event.target.tagName !== 'CANVAS') return;
mouse = event;
if (dragStartMousePosition) {
rotate();
}
}
function updateCameraPosition() {
mouse3d.eye[0] = radius * Math.cos(phi) * Math.sin(theta);
mouse3d.eye[1] = radius * Math.sin(phi);
mouse3d.eye[2] = radius * Math.cos(phi) * Math.cos(theta);
callback && callback();
}
function rotate() {
var amountX = dragStartMousePosition ? dragStartMousePosition.x - mouse.x : 0;
var amountZ = mouse.y - dragStartMousePosition.y;
theta = dragStartTheta + amountX/120;
phi = dragStartPhi + amountZ/120;
var limit = Math.PI / 2;
phi = phi > limit ? limit : phi;
phi = phi < -limit ? -limit : phi;
updateCameraPosition();
}
function mouseDown(event) {
if (event.target.tagName !== 'CANVAS') return;
dragStartPhi = phi;
dragStartTheta = theta;
dragStartMousePosition = event;
}
function mouseUp() {
if (event.target.tagName !== 'CANVAS') return;
rotate();
dragStartMousePosition = null;
dragStartPhi = 0;
dragStartTheta = 0;
}
function mouseWheel(e){
radius *= e.wheelDelta > 0 ? 0.9 : 1.1;
updateCameraPosition();
}
})();
Mouse3D.init();
let fst = FullScreenTriangle(fragCode);
let resolution = fst.triangleProgram.uniform('2f', 'resolution');
let lightPos = fst.triangleProgram.uniform('3f', 'lightPos');
let time = fst.triangleProgram.uniform('1f', 'time');
let eye = fst.triangleProgram.uniform('3f', 'eye');
addEventListener('mousemove', drawFrame);
animate();
var started = new Date().getTime();
function animate() {
requestAnimationFrame(animate);
drawFrame();
}
function drawFrame() {
let t = (new Date().getTime() - started)/1000;
resolution.set(fst.gl.drawingBufferWidth, fst.gl.drawingBufferHeight);
time.set(t);
lightPos.set(Math.cos(t/10)*10,10,Math.sin(t/10)*10);
eye.set(Mouse3D.eye[0], Mouse3D.eye[1], Mouse3D.eye[2]);
fst.draw();
}
</script>
<style>
body, canvas {
position: absolute;
width: 100%;
height: 100%;
overflow: hidden;
margin: 0;
}
</style>
-150
:)