一团揉动 · Blob Shader · ▶ 在线运行案例
案例合集: 三维可视化功能案例(threehub.cn)
开源仓库github地址: https://github.com/z2586300277/three-cesium-examples
**400个案例代码: ** 网盘链接

你将学到什么
- ShaderMaterial 自定义着色器实现核心视觉效果
- OrbitControls 相机轨道交互
- THREE.Points 粒子点渲染
- GSAP 时间轴与补间动画
requestAnimationFrame渲染循环与resize自适应
效果说明
本案例演示 一团揉动 效果:基于 WebGL 实现「一团揉动」可视化效果,附完整可运行源码;核心用到 ShaderMaterial、OrbitControls、THREE.Points。建议先打开文首在线案例查看动态画面,再对照下方源码逐步理解。
核心概念
- Scene / Camera / WebGLRenderer 构成最小渲染闭环;大场景可开
logarithmicDepthBuffer缓解 Z-fighting。 - ShaderMaterial 通过
uniforms+ 自定义 GLSL 控制逐像素/逐点效果;透明粒子常配合depthTest: false。 - OrbitControls 提供轨道旋转/缩放;开启
enableDamping后需在 animate 中controls.update()。 - THREE.Points 将每个顶点渲染为可控大小的粒子;可用自定义 attribute(如
u_index)驱动片元/顶点动画。
实现步骤
- 搭建 Scene、PerspectiveCamera、WebGLRenderer,挂载 canvas 并处理
resize - 定义 uniforms / onBeforeCompile 或 ShaderMaterial,编写 GLSL 与材质参数
- 创建 OrbitControls(及 Raycaster 等交互控件,若源码包含)
- 在定时器或 GSAP 时间轴中更新 uniform / 变换,驱动特效播放
- 在
requestAnimationFrame循环中更新状态并 render(Cesium 为viewer.render或自动渲染)
代码要点
import * as THREE from 'three'
import { OrbitControls } from "three/examples/jsm/controls/OrbitControls.js"
import * as dat from 'dat.gui'
import gsap from 'gsap'
var Theme = {
primary: 0xFFFFFF,
secundary: 0x292733,
danger: 0xFF0000,
darker: 0x000000
};
// reference https://codepen.io/vcomics/pen/ZwNgvX
var scene, camera, renderer, mat;
var _width, _height;
var _primitive;
var shapeGroup = new THREE.Group();
var start = Date.now();
function createWorld() {
_width = window.innerWidth;
_height= window.innerHeight;
scene = new THREE.Scene();
scene.background = new THREE.Color(Theme.secundary);
camera = new THREE.PerspectiveCamera(35, _width/_height, 1, 1000);
camera.position.set(0,10,26);
renderer = new THREE.WebGLRenderer({antialias:false, alpha:false});
renderer.setSize(_width, _height);
renderer.shadowMap.enabled = true;
const controls = new OrbitControls(camera, renderer.domElement)
document.body.appendChild(renderer.domElement);
window.addEventListener('resize', onWindowResize, false);
}
function onWindowResize() {
_width = window.innerWidth;
_height = window.innerHeight;
renderer.setSize(_width, _height);
camera.aspect = _width / _height;
camera.updateProjectionMatrix();
console.log('- resize -');
}
var primitiveElement = function() {
this.mesh = new THREE.Object3D();
mat = new THREE.ShaderMaterial( {
side:THREE.DoubleSide,
uniforms: {
time: {
type: "f",
value: 0.1
},
pointscale: {
type: "f",
value: 0.2
},
decay: {
type: "f",
value: 0.3
},
size: {
type: "f",
value: 0.3
},
displace: {
type: "f",
value: 0.3
},
complex: {
type: "f",
value: 0.0
},
waves: {
type: "f",
value: 0.10
},
eqcolor: {
type: "f",
value: 0.0
},
rcolor: {
type: "f",
value: 0.0
},
gcolor: {
type: "f",
value: 0.0
},
bcolor: {
type: "f",
value: 0.0
},
fragment: {
type: "i",
value: true
},
redhell: {
type: "i",
value: true
}
},
vertexShader: `
vec3 mod289(vec3 x)
{
return x - floor(x * (1.0 / 289.0)) * 289.0;
}
vec4 mod289(vec4 x)
{
return x - floor(x * (1.0 / 289.0)) * 289.0;
}
vec4 permute(vec4 x)
{
return mod289(((x*34.0)+1.0)*x);
}
vec4 taylorInvSqrt(vec4 r)
{
return 1.79284291400159 - 0.85373472095314 * r;
}
vec3 fade(vec3 t) {
return t*t*t*(t*(t*6.0-15.0)+10.0);
}
// Classic Perlin noise
float cnoise(vec3 P)
{
vec3 Pi0 = floor(P); // Integer part for indexing
vec3 Pi1 = Pi0 + vec3(1.0); // Integer part + 1
Pi0 = mod289(Pi0);
Pi1 = mod289(Pi1);
vec3 Pf0 = fract(P); // Fractional part for interpolation
vec3 Pf1 = Pf0 - vec3(1.0); // Fractional part - 1.0
vec4 ix = vec4(Pi0.x, Pi1.x, Pi0.x, Pi1.x);
vec4 iy = vec4(Pi0.yy, Pi1.yy);
vec4 iz0 = Pi0.zzzz;
vec4 iz1 = Pi1.zzzz;
vec4 ixy = permute(permute(ix) + iy);
vec4 ixy0 = permute(ixy + iz0);
vec4 ixy1 = permute(ixy + iz1);
vec4 gx0 = ixy0 * (1.0 / 5.0);
vec4 gy0 = fract(floor(gx0) * (1.0 / 5.0)) - 0.5;
gx0 = fract(gx0);
vec4 gz0 = vec4(0.5) - abs(gx0) - abs(gy0);
vec4 sz0 = step(gz0, vec4(0.0));
gx0 -= sz0 * (step(0.0, gx0) - 0.5);
gy0 -= sz0 * (step(0.0, gy0) - 0.5);
vec4 gx1 = ixy1 * (1.0 / 5.0);
vec4 gy1 = fract(floor(gx1) * (1.0 / 5.0)) - 0.5;
gx1 = fract(gx1);
vec4 gz1 = vec4(0.5) - abs(gx1) - abs(gy1);
vec4 sz1 = step(gz1, vec4(0.0));
gx1 -= sz1 * (step(0.0, gx1) - 0.5);
gy1 -= sz1 * (step(0.0, gy1) - 0.5);
vec3 g000 = vec3(gx0.x,gy0.x,gz0.x);
vec3 g100 = vec3(gx0.y,gy0.y,gz0.y);
vec3 g010 = vec3(gx0.z,gy0.z,gz0.z);
vec3 g110 = vec3(gx0.w,gy0.w,gz0.w);
vec3 g001 = vec3(gx1.x,gy1.x,gz1.x);
vec3 g101 = vec3(gx1.y,gy1.y,gz1.y);
vec3 g011 = vec3(gx1.z,gy1.z,gz1.z);
vec3 g111 = vec3(gx1.w,gy1.w,gz1.w);
vec4 norm0 = taylorInvSqrt(vec4(dot(g000, g000), dot(g010, g010), dot(g100, g100), dot(g110, g110)));
g000 *= norm0.x;
g010 *= norm0.y;
g100 *= norm0.z;
g110 *= norm0.w;
vec4 norm1 = taylorInvSqrt(vec4(dot(g001, g001), dot(g011, g011), dot(g101, g101), dot(g111, g111)));
g001 *= norm1.x;
g011 *= norm1.y;
g101 *= norm1.z;
g111 *= norm1.w;
float n000 = dot(g000, Pf0);
float n100 = dot(g100, vec3(Pf1.x, Pf0.yz));
float n010 = dot(g010, vec3(Pf0.x, Pf1.y, Pf0.z));
float n110 = dot(g110, vec3(Pf1.xy, Pf0.z));
float n001 = dot(g001, vec3(Pf0.xy, Pf1.z));
float n101 = dot(g101, vec3(Pf1.x, Pf0.y, Pf1.z));
float n011 = dot(g011, vec3(Pf0.x, Pf1.yz));
float n111 = dot(g111, Pf1);
vec3 fade_xyz = fade(Pf0);
vec4 n_z = mix(vec4(n000, n100, n010, n110), vec4(n001, n101, n011, n111), fade_xyz.z);
vec2 n_yz = mix(n_z.xy, n_z.zw, fade_xyz.y);
float n_xyz = mix(n_yz.x, n_yz.y, fade_xyz.x);
return 2.2 * n_xyz;
}
// Classic Perlin noise, periodic variant
float pnoise(vec3 P, vec3 rep)
{
vec3 Pi0 = mod(floor(P), rep); // Integer part, modulo period
vec3 Pi1 = mod(Pi0 + vec3(1.0), rep); // Integer part + 1, mod period
Pi0 = mod289(Pi0);
Pi1 = mod289(Pi1);
vec3 Pf0 = fract(P); // Fractional part for interpolation
vec3 Pf1 = Pf0 - vec3(1.0); // Fractional part - 1.0
vec4 ix = vec4(Pi0.x, Pi1.x, Pi0.x, Pi1.x);
vec4 iy = vec4(Pi0.yy, Pi1.yy);
vec4 iz0 = Pi0.zzzz;
vec4 iz1 = Pi1.zzzz;
vec4 ixy = permute(permute(ix) + iy);
vec4 ixy0 = permute(ixy + iz0);
vec4 ixy1 = permute(ixy + iz1);
vec4 gx0 = ixy0 * (1.0 / 5.0);
vec4 gy0 = fract(floor(gx0) * (1.0 / 5.0)) - 0.5;
gx0 = fract(gx0);
vec4 gz0 = vec4(0.5) - abs(gx0) - abs(gy0);
vec4 sz0 = step(gz0, vec4(0.0));
gx0 -= sz0 * (step(0.0, gx0) - 0.5);
gy0 -= sz0 * (step(0.0, gy0) - 0.5);
vec4 gx1 = ixy1 * (1.0 / 5.0);
vec4 gy1 = fract(floor(gx1) * (1.0 / 5.0)) - 0.5;
gx1 = fract(gx1);
vec4 gz1 = vec4(0.5) - abs(gx1) - abs(gy1);
vec4 sz1 = step(gz1, vec4(0.0));
gx1 -= sz1 * (step(0.0, gx1) - 0.5);
gy1 -= sz1 * (step(0.0, gy1) - 0.5);
vec3 g000 = vec3(gx0.x,gy0.x,gz0.x);
vec3 g100 = vec3(gx0.y,gy0.y,gz0.y);
vec3 g010 = vec3(gx0.z,gy0.z,gz0.z);
vec3 g110 = vec3(gx0.w,gy0.w,gz0.w);
vec3 g001 = vec3(gx1.x,gy1.x,gz1.x);
vec3 g101 = vec3(gx1.y,gy1.y,gz1.y);
vec3 g011 = vec3(gx1.z,gy1.z,gz1.z);
vec3 g111 = vec3(gx1.w,gy1.w,gz1.w);
vec4 norm0 = taylorInvSqrt(vec4(dot(g000, g000), dot(g010, g010), dot(g100, g100), dot(g110, g110)));
g000 *= norm0.x;
g010 *= norm0.y;
g100 *= norm0.z;
g110 *= norm0.w;
vec4 norm1 = taylorInvSqrt(vec4(dot(g001, g001), dot(g011, g011), dot(g101, g101), dot(g111, g111)));
g001 *= norm1.x;
g011 *= norm1.y;
g101 *= norm1.z;
g111 *= norm1.w;
float n000 = dot(g000, Pf0);
float n100 = dot(g100, vec3(Pf1.x, Pf0.yz));
float n010 = dot(g010, vec3(Pf0.x, Pf1.y, Pf0.z));
float n110 = dot(g110, vec3(Pf1.xy, Pf0.z));
float n001 = dot(g001, vec3(Pf0.xy, Pf1.z));
float n101 = dot(g101, vec3(Pf1.x, Pf0.y, Pf1.z));
float n011 = dot(g011, vec3(Pf0.x, Pf1.yz));
float n111 = dot(g111, Pf1);
vec3 fade_xyz = fade(Pf0);
vec4 n_z = mix(vec4(n000, n100, n010, n110), vec4(n001, n101, n011, n111), fade_xyz.z);
vec2 n_yz = mix(n_z.xy, n_z.zw, fade_xyz.y);
float n_xyz = mix(n_yz.x, n_yz.y, fade_xyz.x);
return 1.5 * n_xyz;
}
// Turbulence By Jaume Sanchez => https://codepen.io/spite/
varying vec2 vUv;
varying float noise;
varying float qnoise;
varying float displacement;
uniform float time;
uniform float displace;
uniform float pointscale;
uniform float decay;
uniform float size;
uniform float complex;
uniform float waves;
uniform float eqcolor;
uniform bool fragment;
float turbulence( vec3 p) {
float t = - 0.005;
for (float f = 1.0 ; f <= 1.0 ; f++ ){
float power = pow( 1.3, f );
t += abs( pnoise( vec3( power * p ), vec3( 10.0, 10.0, 10.0 ) ) / power );
}
return t;
}
void main() {
vUv = uv;
noise = (2.0 * - waves) * turbulence( decay * abs(normal + time));
qnoise = (0.3 * - eqcolor) * turbulence( decay * abs(normal + time));
float b = pnoise( complex * (position) + vec3( (decay * 2.0) * time ), vec3( 100.0 ) );
displacement = - atan(noise) + tan(b * displace);
vec3 newPosition = (position) + (normal * displacement);
gl_Position = (projectionMatrix * modelViewMatrix) * vec4( newPosition, abs(size) );
gl_PointSize = (3.0);
}
`,
fragmentShader:`
varying float qnoise;
varying float noise;
uniform float time;
uniform bool redhell;
uniform float rcolor;
uniform float gcolor;
uniform float bcolor;
void main() {
float r, g, b;
if (!redhell == true) {
r = sin(qnoise + rcolor);
g = normalize(qnoise + (gcolor / 2.0));
b = tan(qnoise + bcolor);
} else {
r = normalize(qnoise + rcolor);
g = cos(qnoise + gcolor);
b = sin(qnoise + bcolor);
}
gl_FragColor = vec4(r, g, b, 1.0);
}`
});
var wir_mat = new THREE.MeshBasicMaterial({color:Theme.darker});
var geo = new THREE.IcosahedronGeometry(2, 60);
var wir = new THREE.IcosahedronGeometry(2.3, 20);
this.shape = new THREE.Mesh(geo, mat);
this.point = new THREE.Points(wir, mat);
shapeGroup.add(this.point);
shapeGroup.add(this.shape);
scene.add(shapeGroup);
}
function createPrimitive() {
_primitive = new primitiveElement();
}
var options = {
perlin: {
speed: 0.4,
size: 0.7,
perlins: 1.0,
decay: 1.20,
displace: 1.00,
complex: 0.50,
waves: 3.7,
eqcolor: 10.0,
rcolor: 1.5,
gcolor: 1.5,
bcolor: 1.5,
fragment: true,
points: true,
redhell: true
},
perlinRandom: function() {
gsap.to(this.perlin, 2, {
//decay: Math.random() * 1.0,
waves: Math.random() * 20.0,
complex: Math.random() * 1.0,
displace: Math.random() * 2.5,
});
},
random: function() {
//this.perlin.redhell = Math.random() >= 0.5; // 10 1 0.1 1.2
gsap.to(this.perlin, 1, {
eqcolor: 11.0,
rcolor: Math.random() * 1.5,
gcolor: Math.random() * 0.5,
bcolor: Math.random() * 1.5,
});
},
normal: function() {
this.perlin.redhell = true; // 10 1 0.1 1.2
gsap.to(this.perlin, 1, {
//speed: 0.12,
eqcolor: 10.0,
rcolor: 1.5,
gcolor: 1.5,
bcolor: 1.5,
});
},
darker: function() {
this.perlin.redhell = false; // 10 1 0.1 1.2
gsap.to(this.perlin, 1, {
//speed: 0.5,
eqcolor: 9.0,
rcolor: 0.4,
gcolor: 0.05,
bcolor: 0.6,
});
},
volcano: function() {
this.perlin.redhell = false; // 10 1 0.1 1.2
//this.perlin.speed = 0.83;
gsap.to(this.perlin, 1, {
size: 0.7,
waves: 0.6,
complex: 1.0,
displace: 0.3,
eqcolor: 9.0,
rcolor: 0.85,
gcolor: 0.05,
bcolor: 0.32,
});
},
cloud: function() {
this.perlin.redhell = true; // 10 1 0.1 1.2
//this.perlin.speed = 0.1;
gsap.to(this.perlin, 1, {
size: 1.0,
waves :20.0,
complex: 0.1,
displace: 0.1,
eqcolor: 4.0,
rcolor: 1.5,
gcolor: 0.7,
bcolor: 1.5,
});
},
tornasol: function() {
this.perlin.redhell = true; // 10 1 0.1 1.2
//this.perlin.speed = 0.25;
gsap.to(this.perlin, 1, {
size: 1.0,
waves: 3.0,
complex: 0.65,
displace: 0.5,
eqcolor: 9.5,
rcolor: 1.5,
gcolor: 1.5,
bcolor: 1.5,
});
}
}
function createGUI() {
var gui = new dat.GUI();
var perlinGUI = gui.addFolder('Shape Setup');
perlinGUI.add(options, 'perlinRandom').name('• Random Shape');
perlinGUI.add(options.perlin, 'speed', 0.1, 1.0).name('Speed').listen();
perlinGUI.add(options.perlin, 'size', 0.0, 3.0).name('Size').listen();
//perlinGUI.add(options.perlin, 'decay', 0.0, 1.0).name('Decay').listen();
perlinGUI.add(options.perlin, 'waves', 0.0, 20.0).name('Waves').listen();
perlinGUI.add(options.perlin, 'complex', 0.1, 1.0).name('Complex').listen();
perlinGUI.add(options.perlin, 'displace', 0.1, 2.5).name('Displacement').listen();
//perlinGUI.open();
var colorGUI = gui.addFolder('Color');
colorGUI.add(options, 'random').name('• Random colors');
colorGUI.add(options, 'normal').name('• Normal colors');
colorGUI.add(options, 'darker').name('• Dark colors');
colorGUI.add(options.perlin, 'eqcolor', 0.0, 30.0).name('Hue').listen();
colorGUI.add(options.perlin, 'rcolor', 0.0, 2.5).name('R').listen();
colorGUI.add(options.perlin, 'gcolor', 0.0, 2.5).name('G').listen();
colorGUI.add(options.perlin, 'bcolor', 0.0, 2.5).name('B').listen();
colorGUI.add(options.perlin, 'redhell', true).name('Electroflow');
//colorGUI.open();
gui.add(options, 'volcano').name('• Volcano');
gui.add(options, 'tornasol').name('• Tornasol');
gui.add(options, 'cloud').name('• Cotton Candy');
gui.add(options.perlin, 'points', true).name('Points');
}
function animation() {
var performance = Date.now() * 0.003;
//_primitive.shape.visible = !options.perlin.points;
_primitive.point.visible = options.perlin.points;
mat.uniforms['time'].value = (options.perlin.speed / 1000) * (Date.now() - start);
mat.uniforms['pointscale'].value = options.perlin.perlins;
mat.uniforms['decay'].value = options.perlin.decay;
mat.uniforms['size'].value = options.perlin.size;
mat.uniforms['displace'].value = options.perlin.displace;
mat.uniforms['complex'].value = options.perlin.complex;
mat.uniforms['waves'].value = options.perlin.waves;
mat.uniforms['fragment'].value = options.perlin.fragment;
mat.uniforms['redhell'].value = options.perlin.redhell;
mat.uniforms['eqcolor'].value = options.perlin.eqcolor;
mat.uniforms['rcolor'].value = options.perlin.rcolor;
mat.uniforms['gcolor'].value = options.perlin.gcolor;
mat.uniforms['bcolor'].value = options.perlin.bcolor;
requestAnimationFrame(animation);
renderer.render(scene, camera);
}
createWorld();
createGUI();
createPrimitive();
animation();
完整源码:GitHub
小结
- 本文提供 一团揉动 完整 Three.js 源码与在线 Demo,建议先运行案例再改 uniform/参数做二次实验
- 更多 Three.js 实战案例见 three-cesium-examples 合集 与 GitHub 开源仓库