Skill

threejs-webgl

Builds interactive 3D web scenes with Three.js using WebGL/WebGPU. Guides on scenes, cameras, renderers, geometries, materials, meshes, lights, animations, and OrbitControls.

Javascript

Html

frontend

npx claudepluginhub freshtechbro/claudedesignskills --plugin core-3d-animation

Tool Access

This skill uses the workspace's default tool permissions.

Preview

Three.js is the industry-standard JavaScript library for creating 3D graphics in web browsers using WebGL and WebGPU. This skill provides comprehensive guidance for building performant, interactive 3D experiences including scenes, cameras, renderers, geometries, materials, lights, textures, and animations.

Supporting Assets

assets/starter_scene/README.mdassets/starter_scene/index.htmlassets/starter_scene/main.jsreferences/api_reference.mdreferences/materials_guide.mdreferences/optimization_checklist.mdscripts/setup_scene.py

SKILL.md

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Last CommitNov 14, 2025

Used By2 plugins

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Three.js WebGL/WebGPU Development

Overview

Core Concepts

Scene Graph Architecture

Three.js uses a hierarchical scene graph where all 3D objects are organized in a tree structure:

Scene
├── Camera
├── Lights
│   ├── AmbientLight
│   ├── DirectionalLight
│   └── PointLight
├── Meshes
│   ├── Mesh (Geometry + Material)
│   └── InstancedMesh
└── Groups

Essential Components

Every Three.js application requires these core elements:

Scene: Container for all 3D objects
Camera: Defines the viewing perspective
Renderer: Draws the scene to canvas (WebGL or WebGPU)
Geometry: Defines the shape of objects
Material: Defines the surface appearance
Mesh: Combines geometry and material

Quick Start Pattern

Basic Scene Setup

import * as THREE from 'three';
import { OrbitControls } from 'three/addons/controls/OrbitControls.js';

// Scene, Camera, Renderer
const scene = new THREE.Scene();
scene.background = new THREE.Color(0x333333);

const camera = new THREE.PerspectiveCamera(
  75, // FOV
  window.innerWidth / window.innerHeight, // Aspect ratio
  0.1, // Near clipping plane
  1000 // Far clipping plane
);
camera.position.set(0, 2, 5);

const renderer = new THREE.WebGLRenderer({ antialias: true });
renderer.setSize(window.innerWidth, window.innerHeight);
renderer.setPixelRatio(window.devicePixelRatio);
renderer.shadowMap.enabled = true;
document.body.appendChild(renderer.domElement);

// Lighting
const ambientLight = new THREE.AmbientLight(0xffffff, 0.5);
scene.add(ambientLight);

const directionalLight = new THREE.DirectionalLight(0xffffff, 1);
directionalLight.position.set(5, 10, 7.5);
directionalLight.castShadow = true;
scene.add(directionalLight);

// Controls
const controls = new OrbitControls(camera, renderer.domElement);
controls.enableDamping = true;
controls.dampingFactor = 0.05;

// Animation Loop
function animate() {
  requestAnimationFrame(animate);
  controls.update();
  renderer.render(scene, camera);
}

animate();

// Handle Resize
window.addEventListener('resize', () => {
  camera.aspect = window.innerWidth / window.innerHeight;
  camera.updateProjectionMatrix();
  renderer.setSize(window.innerWidth, window.innerHeight);
});

WebGPU Setup (Modern Alternative)

import * as THREE from 'three/webgpu';

const renderer = new THREE.WebGPURenderer({ antialias: true });
renderer.setPixelRatio(window.devicePixelRatio);
renderer.setSize(window.innerWidth, window.innerHeight);
renderer.setAnimationLoop(animate);
renderer.toneMapping = THREE.LinearToneMapping;
renderer.toneMappingExposure = 1;
document.body.appendChild(renderer.domElement);

Common Patterns

1. Creating Meshes with Materials

// Basic Mesh
const geometry = new THREE.BoxGeometry(1, 1, 1);
const material = new THREE.MeshStandardMaterial({
  color: 0x00ff00,
  roughness: 0.5,
  metalness: 0.5
});
const cube = new THREE.Mesh(geometry, material);
scene.add(cube);

// Textured Mesh
const loader = new THREE.TextureLoader();
const texture = loader.load('texture.jpg');
texture.colorSpace = THREE.SRGBColorSpace;

const texturedMaterial = new THREE.MeshStandardMaterial({
  map: texture
});
const mesh = new THREE.Mesh(geometry, texturedMaterial);
scene.add(mesh);

2. Lighting Strategies

// Three-Point Lighting Setup
function setupThreePointLight(scene) {
  // Key Light (Main)
  const keyLight = new THREE.DirectionalLight(0xffffff, 3);
  keyLight.position.set(5, 10, 7.5);
  keyLight.castShadow = true;
  scene.add(keyLight);

  // Fill Light (Softens shadows)
  const fillLight = new THREE.DirectionalLight(0xffffff, 1);
  fillLight.position.set(-5, 5, -5);
  scene.add(fillLight);

  // Rim Light (Edge definition)
  const rimLight = new THREE.DirectionalLight(0xffffff, 0.5);
  rimLight.position.set(0, 5, -10);
  scene.add(rimLight);

  // Ambient (Base illumination)
  const ambient = new THREE.AmbientLight(0x404040, 0.5);
  scene.add(ambient);
}

// Physical Light (Realistic)
const bulbLight = new THREE.PointLight(0xffee88, 1, 100, 2);
bulbLight.power = 1700; // Lumens (100W bulb equivalent)
bulbLight.castShadow = true;
scene.add(bulbLight);

// Hemisphere Light (Sky + Ground)
const hemiLight = new THREE.HemisphereLight(
  0xddeeff, // Sky color
  0x0f0e0d, // Ground color
  0.02
);
scene.add(hemiLight);

3. Instanced Geometry (Performance)

// For rendering thousands of similar objects efficiently
const geometry = new THREE.SphereGeometry(0.1, 16, 16);
const material = new THREE.MeshStandardMaterial({ color: 0xff0000 });
const instancedMesh = new THREE.InstancedMesh(geometry, material, 1000);

const matrix = new THREE.Matrix4();
const color = new THREE.Color();

for (let i = 0; i < 1000; i++) {
  matrix.setPosition(
    Math.random() * 10 - 5,
    Math.random() * 10 - 5,
    Math.random() * 10 - 5
  );
  instancedMesh.setMatrixAt(i, matrix);
  instancedMesh.setColorAt(i, color.setHex(Math.random() * 0xffffff));
}

instancedMesh.instanceMatrix.needsUpdate = true;
scene.add(instancedMesh);

4. Loading 3D Models (glTF)

import { GLTFLoader } from 'three/addons/loaders/GLTFLoader.js';
import { DRACOLoader } from 'three/addons/loaders/DRACOLoader.js';

// Setup loaders
const dracoLoader = new DRACOLoader();
dracoLoader.setDecoderPath('/draco/');

const gltfLoader = new GLTFLoader();
gltfLoader.setDRACOLoader(dracoLoader);

// Load model
gltfLoader.load('model.glb', (gltf) => {
  const model = gltf.scene;

  // Enable shadows
  model.traverse((child) => {
    if (child.isMesh) {
      child.castShadow = true;
      child.receiveShadow = true;
    }
  });

  scene.add(model);

  // Handle animations
  if (gltf.animations.length > 0) {
    const mixer = new THREE.AnimationMixer(model);
    const action = mixer.clipAction(gltf.animations[0]);
    action.play();

    // In animation loop:
    // mixer.update(deltaTime);
  }
});

5. Shadow Configuration

// Enable shadows on renderer
renderer.shadowMap.enabled = true;
renderer.shadowMap.type = THREE.PCFSoftShadowMap; // or VSMShadowMap

// Configure light shadows
directionalLight.castShadow = true;
directionalLight.shadow.mapSize.width = 2048;
directionalLight.shadow.mapSize.height = 2048;
directionalLight.shadow.camera.near = 0.5;
directionalLight.shadow.camera.far = 50;
directionalLight.shadow.camera.left = -10;
directionalLight.shadow.camera.right = 10;
directionalLight.shadow.camera.top = 10;
directionalLight.shadow.camera.bottom = -10;
directionalLight.shadow.radius = 4;
directionalLight.shadow.blurSamples = 8;

// Objects casting/receiving shadows
mesh.castShadow = true;
mesh.receiveShadow = true;

6. Raycasting (Interaction)

const raycaster = new THREE.Raycaster();
const mouse = new THREE.Vector2();

function onMouseClick(event) {
  mouse.x = (event.clientX / window.innerWidth) * 2 - 1;
  mouse.y = -(event.clientY / window.innerHeight) * 2 + 1;

  raycaster.setFromCamera(mouse, camera);
  const intersects = raycaster.intersectObjects(scene.children, true);

  if (intersects.length > 0) {
    const object = intersects[0].object;
    object.material.color.set(0xff0000);
  }
}

window.addEventListener('click', onMouseClick);

Integration Patterns

With GSAP for Animation

import gsap from 'gsap';

// Animate camera
gsap.to(camera.position, {
  x: 5,
  y: 3,
  z: 10,
  duration: 2,
  ease: "power2.inOut",
  onUpdate: () => {
    camera.lookAt(scene.position);
  }
});

// Animate mesh properties
gsap.to(mesh.rotation, {
  y: Math.PI * 2,
  duration: 3,
  repeat: -1,
  ease: "none"
});

With React (see react-three-fiber skill)

// Three.js integrates naturally with React Three Fiber
// Use the react-three-fiber skill for React integration patterns

With Post-Processing

import { EffectComposer } from 'three/addons/postprocessing/EffectComposer.js';
import { RenderPass } from 'three/addons/postprocessing/RenderPass.js';
import { UnrealBloomPass } from 'three/addons/postprocessing/UnrealBloomPass.js';

const composer = new EffectComposer(renderer);
composer.addPass(new RenderPass(scene, camera));

const bloomPass = new UnrealBloomPass(
  new THREE.Vector2(window.innerWidth, window.innerHeight),
  1.5, // strength
  0.4, // radius
  0.85 // threshold
);
composer.addPass(bloomPass);

// In animation loop:
composer.render();

Performance Optimization

1. Geometry Reuse

// Bad: Creates new geometry for each mesh
for (let i = 0; i < 100; i++) {
  const geometry = new THREE.BoxGeometry(1, 1, 1);
  const mesh = new THREE.Mesh(geometry, material);
  scene.add(mesh);
}

// Good: Reuse geometry
const sharedGeometry = new THREE.BoxGeometry(1, 1, 1);
for (let i = 0; i < 100; i++) {
  const mesh = new THREE.Mesh(sharedGeometry, material);
  scene.add(mesh);
}

2. Use InstancedMesh for Repeated Objects

For hundreds/thousands of identical objects, use InstancedMesh (see pattern above).

3. Texture Optimization

// Compress textures
texture.generateMipmaps = true;
texture.minFilter = THREE.LinearMipmapLinearFilter;
texture.magFilter = THREE.LinearFilter;

// Use power-of-two dimensions (512, 1024, 2048)
// Consider texture atlases for multiple small textures

4. Level of Detail (LOD)

const lod = new THREE.LOD();
lod.addLevel(highDetailMesh, 0);    // 0-50 units
lod.addLevel(mediumDetailMesh, 50);  // 50-100 units
lod.addLevel(lowDetailMesh, 100);    // 100+ units
scene.add(lod);

5. Frustum Culling

Three.js automatically culls objects outside the camera's view. Ensure objects have correct bounding spheres:

mesh.geometry.computeBoundingSphere();

6. Dispose Resources

function disposeScene() {
  scene.traverse((object) => {
    if (object.geometry) object.geometry.dispose();
    if (object.material) {
      if (Array.isArray(object.material)) {
        object.material.forEach(material => material.dispose());
      } else {
        object.material.dispose();
      }
    }
  });
  renderer.dispose();
}

Best Practices

1. Use Animation Clocks for Consistent Timing

const clock = new THREE.Clock();

function animate() {
  const deltaTime = clock.getDelta();
  const elapsedTime = clock.getElapsedTime();

  // Use deltaTime for frame-independent animations
  mesh.rotation.y += deltaTime * Math.PI * 0.5; // 90° per second

  renderer.render(scene, camera);
}

2. Camera Setup Guidelines

FOV: 45-75° for most applications
Near plane: As far as possible (avoid z-fighting)
Far plane: As close as possible (precision)
Aspect ratio: Always match canvas dimensions

3. Material Selection

MeshBasicMaterial: Unlit, flat colors (debugging, UI)
MeshLambertMaterial: Cheap diffuse lighting (mobile)
MeshPhongMaterial: Specular highlights (older standard)
MeshStandardMaterial: PBR, realistic (recommended)
MeshPhysicalMaterial: Advanced PBR (clearcoat, transmission)

4. Coordinate System

Three.js uses right-handed coordinate system
+Y is up, +Z is toward camera, +X is right
Rotations use radians (Math.PI = 180°)

5. Scene Organization

// Group related objects
const building = new THREE.Group();
building.add(walls, roof, windows);
scene.add(building);

// Use meaningful names
mesh.name = 'player-character';
const found = scene.getObjectByName('player-character');

Common Pitfalls

1. Not Updating Aspect Ratio on Resize

Always update camera aspect ratio and projection matrix when window resizes.

2. Creating New Objects in Animation Loop

// Bad: Memory leak
function animate() {
  const geometry = new THREE.BoxGeometry(); // Created every frame!
  // ...
}

// Good: Create once outside loop
const geometry = new THREE.BoxGeometry();
function animate() {
  // Reuse geometry
}

3. Forgetting to Enable Shadows

Remember to enable shadows on renderer, lights, and objects.

4. Z-Fighting (Flickering)

Increase near plane distance
Decrease far plane distance
Avoid overlapping coplanar surfaces
Use material.polygonOffset = true with material.polygonOffsetFactor

5. Color Space Issues

// Always set color space for textures
texture.colorSpace = THREE.SRGBColorSpace;

// Set renderer output encoding
renderer.outputColorSpace = THREE.SRGBColorSpace;

6. Not Disposing Resources

Always call .dispose() on geometries, materials, textures, and renderers when no longer needed.

Resources

This skill includes bundled resources to accelerate Three.js development:

references/

api_reference.md: Quick API reference for core classes (Scene, Camera, Renderer, etc.)
materials_guide.md: Comprehensive material types and properties
optimization_checklist.md: Performance optimization strategies

scripts/

setup_scene.py: Generate boilerplate Three.js scene setup code
texture_optimizer.py: Batch optimize textures for web (resize, compress)
gltf_validator.py: Validate glTF models before use

assets/

starter_scene/: Complete HTML/JS boilerplate project
shaders/: Custom GLSL shader examples (vertex, fragment)
hdri/: Environment maps for PBR lighting
draco/: DRACO decoder for compressed models

Advanced Topics

Custom Shaders (GLSL)

const material = new THREE.ShaderMaterial({
  uniforms: {
    uTime: { value: 0.0 },
    uColor: { value: new THREE.Color(0x00ff00) }
  },
  vertexShader: `
    varying vec2 vUv;
    void main() {
      vUv = uv;
      gl_Position = projectionMatrix * modelViewMatrix * vec4(position, 1.0);
    }
  `,
  fragmentShader: `
    uniform float uTime;
    uniform vec3 uColor;
    varying vec2 vUv;
    void main() {
      gl_FragColor = vec4(uColor * vUv.x, 1.0);
    }
  `
});

Render Targets (Render-to-Texture)

const renderTarget = new THREE.WebGLRenderTarget(512, 512);

// Render scene to texture
renderer.setRenderTarget(renderTarget);
renderer.render(scene, camera);
renderer.setRenderTarget(null);

// Use texture
const material = new THREE.MeshBasicMaterial({
  map: renderTarget.texture
});

GPU Computation (GPGPU)

Use GPUComputationRenderer for particle simulations, cloth physics, etc.

When to Use This Skill

Use this skill when:

Building interactive 3D web experiences
Creating product configurators or visualizers
Implementing WebGL/WebGPU rendering
Working with 3D models, scenes, or animations
Optimizing Three.js performance
Integrating Three.js with other libraries (GSAP, React, etc.)
Debugging Three.js rendering issues

For React integration, use the react-three-fiber skill. For animation, combine with the gsap-scrolltrigger skill. For UI animations, use the motion-framer skill.