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使用 Three.js 的太阳能系统

WBOY
WBOY原创
2024-08-22 18:57:42775浏览

嗨!今天,我将使用 Three.js 构建一个太阳能系统。但在我们开始之前,您应该知道本文的灵感来自于我目前正在从事的项目的客户代表。是的,那就是你——相信地球是平的。

JavaScript/Node 拥有最大的库生态系统,涵盖大量可简化开发的功能,因此我始终可以选择哪个更适合您的目的。然而,如果我们谈论 3D 图形,没有那么多酷的选择,而 Three.js 可能是其中最好的,并且拥有最大的社区。

所以让我们深入研究 Three.js 并使用它构建 Solar 系统。在这篇文章中我将介绍:

  • 初始化项目和场景
  • 创造太阳
  • 创造行星
  • 部署到 GitHub Pages

初始化项目和场景

首先要做的事情:为了初始化项目,我使用 Vite 并安装 Three.js 依赖项。现在的问题是如何设置 Three.js。为此,您需要三样东西:场景、相机和渲染器。我还使用内置插件 OrbitControls,它允许我在场景中导航。启动应用程序后,应该会出现黑屏。

import { Scene, WebGLRenderer, PerspectiveCamera } from "three";
import { OrbitControls } from "three/addons/controls/OrbitControls.js";

const w = window.innerWidth;
const h = window.innerHeight;

const scene = new Scene();
const camera = new PerspectiveCamera(75, w / h, 0.1, 100);
const renderer = new WebGLRenderer();
const controls = new OrbitControls(camera, renderer.domElement);

controls.minDistance = 10;
controls.maxDistance = 60;
camera.position.set(30 * Math.cos(Math.PI / 6), 30 * Math.sin(Math.PI / 6), 40);

renderer.setSize(w, h);
document.body.appendChild(renderer.domElement);

renderer.render(scene, camera);

window.addEventListener("resize", () => {
  const w = window.innerWidth;
  const h = window.innerHeight;
  renderer.setSize(w, h);
  camera.aspect = w / h;
  camera.updateProjectionMatrix();
});

const animate = () => {
  requestAnimationFrame(animate);
  controls.update();
  renderer.render(scene, camera);
};

animate();

您可能会注意到,我通过控件限制了缩放,并且还更改了相机的默认角度。这将有助于后续步骤中正确显示场景。

现在是时候添加一个简单的星空了,因为我们的太阳系应该被恒星包围。为了简化说明,假设您有一个球体,并且在该球体上随机选取 1,000 个点。然后,通过将星形纹理映射到这些点上来创建星形。最后,我添加动画以使所有这些点绕 y 轴旋转。这样,星空就可以添加到场景中了。

import {
  Group,
  Color,
  Points,
  Vector3,
  TextureLoader,
  PointsMaterial,
  BufferGeometry,
  AdditiveBlending,
  Float32BufferAttribute,
} from "three";

export class Starfield {
  group;
  loader;
  animate;

  constructor({ numStars = 1000 } = {}) {
    this.numStars = numStars;

    this.group = new Group();
    this.loader = new TextureLoader();

    this.createStarfield();

    this.animate = this.createAnimateFunction();
    this.animate();
  }

  createStarfield() {
    let col;
    const verts = [];
    const colors = [];
    const positions = [];

    for (let i = 0; i < this.numStars; i += 1) {
      let p = this.getRandomSpherePoint();
      const { pos, hue } = p;
      positions.push(p);
      col = new Color().setHSL(hue, 0.2, Math.random());
      verts.push(pos.x, pos.y, pos.z);
      colors.push(col.r, col.g, col.b);
    }

    const geo = new BufferGeometry();
    geo.setAttribute("position", new Float32BufferAttribute(verts, 3));
    geo.setAttribute("color", new Float32BufferAttribute(colors, 3));
    const mat = new PointsMaterial({
      size: 0.2,
      alphaTest: 0.5,
      transparent: true,
      vertexColors: true,
      blending: AdditiveBlending,
      map: this.loader.load("/solar-system-threejs/assets/circle.png"),
    });
    const points = new Points(geo, mat);
    this.group.add(points);
  }

  getRandomSpherePoint() {
    const radius = Math.random() * 25 + 25;
    const u = Math.random();
    const v = Math.random();
    const theta = 2 * Math.PI * u;
    const phi = Math.acos(2 * v - 1);
    let x = radius * Math.sin(phi) * Math.cos(theta);
    let y = radius * Math.sin(phi) * Math.sin(theta);
    let z = radius * Math.cos(phi);

    return {
      pos: new Vector3(x, y, z),
      hue: 0.6,
      minDist: radius,
    };
  }

  createAnimateFunction() {
    return () => {
      requestAnimationFrame(this.animate);
      this.group.rotation.y += 0.00005;
    };
  }

  getStarfield() {
    return this.group;
  }
}

添加星空很简单,只需使用场景类中的 add 方法即可

const starfield = new Starfield().getStarfield();
scene.add(starfield);

至于纹理,您可以在存储库中找到此项目中使用的所有纹理,该存储库链接在文章末尾。大多数纹理均取自此站点,但恒星和行星环纹理除外。


创造太阳

对于太阳,我使用了二十面体几何体并在其上映射了纹理。使用改进的噪声,我实现了太阳脉冲的效果,模拟真实恒星向太空发射能量流的方式。太阳不仅仅是一个带有映射纹理的图形;它也是一个图形。它还需要成为场景中的光源,所以我使用 PointLight 来模拟它。

import {
  Mesh,
  Group,
  Color,
  Vector3,
  BackSide,
  PointLight,
  TextureLoader,
  ShaderMaterial,
  AdditiveBlending,
  DynamicDrawUsage,
  MeshBasicMaterial,
  IcosahedronGeometry,
} from "three";
import { ImprovedNoise } from "three/addons/math/ImprovedNoise.js";

export class Sun {
  group;
  loader;
  animate;
  corona;
  sunRim;
  glow;

  constructor() {
    this.sunTexture = "/solar-system-threejs/assets/sun-map.jpg";

    this.group = new Group();
    this.loader = new TextureLoader();

    this.createCorona();
    this.createRim();
    this.addLighting();
    this.createGlow();
    this.createSun();

    this.animate = this.createAnimateFunction();
    this.animate();
  }

  createSun() {
    const map = this.loader.load(this.sunTexture);
    const sunGeometry = new IcosahedronGeometry(5, 12);
    const sunMaterial = new MeshBasicMaterial({
      map,
      emissive: new Color(0xffff99),
      emissiveIntensity: 1.5,
    });
    const sunMesh = new Mesh(sunGeometry, sunMaterial);
    this.group.add(sunMesh);

    this.group.add(this.sunRim);

    this.group.add(this.corona);

    this.group.add(this.glow);

    this.group.userData.update = (t) => {
      this.group.rotation.y = -t / 5;
      this.corona.userData.update(t);
    };
  }

  createCorona() {
    const coronaGeometry = new IcosahedronGeometry(4.9, 12);
    const coronaMaterial = new MeshBasicMaterial({
      color: 0xff0000,
      side: BackSide,
    });
    const coronaMesh = new Mesh(coronaGeometry, coronaMaterial);
    const coronaNoise = new ImprovedNoise();

    let v3 = new Vector3();
    let p = new Vector3();
    let pos = coronaGeometry.attributes.position;
    pos.usage = DynamicDrawUsage;
    const len = pos.count;

    const update = (t) => {
      for (let i = 0; i < len; i += 1) {
        p.fromBufferAttribute(pos, i).normalize();
        v3.copy(p).multiplyScalar(5);
        let ns = coronaNoise.noise(
          v3.x + Math.cos(t),
          v3.y + Math.sin(t),
          v3.z + t
        );
        v3.copy(p)
          .setLength(5)
          .addScaledVector(p, ns * 0.4);
        pos.setXYZ(i, v3.x, v3.y, v3.z);
      }
      pos.needsUpdate = true;
    };

    coronaMesh.userData.update = update;
    this.corona = coronaMesh;
  }

  createGlow() {
    const uniforms = {
      color1: { value: new Color(0x000000) },
      color2: { value: new Color(0xff0000) },
      fresnelBias: { value: 0.2 },
      fresnelScale: { value: 1.5 },
      fresnelPower: { value: 4.0 },
    };

    const vertexShader = `
    uniform float fresnelBias;
    uniform float fresnelScale;
    uniform float fresnelPower;

    varying float vReflectionFactor;

    void main() {
      vec4 mvPosition = modelViewMatrix * vec4( position, 1.0 );
      vec4 worldPosition = modelMatrix * vec4( position, 1.0 );

      vec3 worldNormal = normalize( mat3( modelMatrix[0].xyz, modelMatrix[1].xyz, modelMatrix[2].xyz ) * normal );

      vec3 I = worldPosition.xyz - cameraPosition;

      vReflectionFactor = fresnelBias + fresnelScale * pow( 1.0 + dot( normalize( I ), worldNormal ), fresnelPower );

      gl_Position = projectionMatrix * mvPosition;
    }
    `;

    const fragmentShader = `
      uniform vec3 color1;
      uniform vec3 color2;

      varying float vReflectionFactor;

      void main() {
        float f = clamp( vReflectionFactor, 0.0, 1.0 );
        gl_FragColor = vec4(mix(color2, color1, vec3(f)), f);
      }
    `;

    const sunGlowMaterial = new ShaderMaterial({
      uniforms,
      vertexShader,
      fragmentShader,
      transparent: true,
      blending: AdditiveBlending,
    });
    const sunGlowGeometry = new IcosahedronGeometry(5, 12);
    const sunGlowMesh = new Mesh(sunGlowGeometry, sunGlowMaterial);
    sunGlowMesh.scale.setScalar(1.1);
    this.glow = sunGlowMesh;
  }

  createRim() {
    const uniforms = {
      color1: { value: new Color(0xffff99) },
      color2: { value: new Color(0x000000) },
      fresnelBias: { value: 0.2 },
      fresnelScale: { value: 1.5 },
      fresnelPower: { value: 4.0 },
    };

    const vertexShader = `
    uniform float fresnelBias;
    uniform float fresnelScale;
    uniform float fresnelPower;

    varying float vReflectionFactor;

    void main() {
      vec4 mvPosition = modelViewMatrix * vec4( position, 1.0 );
      vec4 worldPosition = modelMatrix * vec4( position, 1.0 );

      vec3 worldNormal = normalize( mat3( modelMatrix[0].xyz, modelMatrix[1].xyz, modelMatrix[2].xyz ) * normal );

      vec3 I = worldPosition.xyz - cameraPosition;

      vReflectionFactor = fresnelBias + fresnelScale * pow( 1.0 + dot( normalize( I ), worldNormal ), fresnelPower );

      gl_Position = projectionMatrix * mvPosition;
    }
    `;
    const fragmentShader = `
    uniform vec3 color1;
    uniform vec3 color2;

    varying float vReflectionFactor;

    void main() {
      float f = clamp( vReflectionFactor, 0.0, 1.0 );
      gl_FragColor = vec4(mix(color2, color1, vec3(f)), f);
    }
    `;

    const sunRimMaterial = new ShaderMaterial({
      uniforms,
      vertexShader,
      fragmentShader,
      transparent: true,
      blending: AdditiveBlending,
    });
    const sunRimGeometry = new IcosahedronGeometry(5, 12);
    const sunRimMesh = new Mesh(sunRimGeometry, sunRimMaterial);
    sunRimMesh.scale.setScalar(1.01);
    this.sunRim = sunRimMesh;
  }

  addLighting() {
    const sunLight = new PointLight(0xffff99, 1000);
    sunLight.position.set(0, 0, 0);
    this.group.add(sunLight);
  }

  createAnimateFunction() {
    return (t = 0) => {
      const time = t * 0.00051;
      requestAnimationFrame(this.animate);
      this.group.userData.update(time);
    };
  }

  getSun() {
    return this.group;
  }
}

创造行星

所有行星都是使用类似的逻辑构建的:每个行星都需要一个轨道、纹理、轨道速度和自转速度。对于需要它们的行星,还应该添加环。

import {
  Mesh,
  Color,
  Group,
  DoubleSide,
  RingGeometry,
  TorusGeometry,
  TextureLoader,
  ShaderMaterial,
  SRGBColorSpace,
  AdditiveBlending,
  MeshPhongMaterial,
  MeshBasicMaterial,
  IcosahedronGeometry,
} from "three";

export class Planet {
  group;
  loader;
  animate;
  planetGroup;
  planetGeometry;

  constructor({
    orbitSpeed = 1,
    orbitRadius = 1,
    orbitRotationDirection = "clockwise",

    planetSize = 1,
    planetAngle = 0,
    planetRotationSpeed = 1,
    planetRotationDirection = "clockwise",
    planetTexture = "/solar-system-threejs/assets/mercury-map.jpg",

    rimHex = 0x0088ff,
    facingHex = 0x000000,

    rings = null,
  } = {}) {
    this.orbitSpeed = orbitSpeed;
    this.orbitRadius = orbitRadius;
    this.orbitRotationDirection = orbitRotationDirection;

    this.planetSize = planetSize;
    this.planetAngle = planetAngle;
    this.planetTexture = planetTexture;
    this.planetRotationSpeed = planetRotationSpeed;
    this.planetRotationDirection = planetRotationDirection;

    this.rings = rings;

    this.group = new Group();
    this.planetGroup = new Group();
    this.loader = new TextureLoader();
    this.planetGeometry = new IcosahedronGeometry(this.planetSize, 12);

    this.createOrbit();
    this.createRings();
    this.createPlanet();
    this.createGlow(rimHex, facingHex);

    this.animate = this.createAnimateFunction();
    this.animate();
  }

  createOrbit() {
    const orbitGeometry = new TorusGeometry(this.orbitRadius, 0.01, 100);
    const orbitMaterial = new MeshBasicMaterial({
      color: 0xadd8e6,
      side: DoubleSide,
    });
    const orbitMesh = new Mesh(orbitGeometry, orbitMaterial);
    orbitMesh.rotation.x = Math.PI / 2;
    this.group.add(orbitMesh);
  }

  createPlanet() {
    const map = this.loader.load(this.planetTexture);
    const planetMaterial = new MeshPhongMaterial({ map });
    planetMaterial.map.colorSpace = SRGBColorSpace;
    const planetMesh = new Mesh(this.planetGeometry, planetMaterial);
    this.planetGroup.add(planetMesh);
    this.planetGroup.position.x = this.orbitRadius - this.planetSize / 9;
    this.planetGroup.rotation.z = this.planetAngle;
    this.group.add(this.planetGroup);
  }

  createGlow(rimHex, facingHex) {
    const uniforms = {
      color1: { value: new Color(rimHex) },
      color2: { value: new Color(facingHex) },
      fresnelBias: { value: 0.2 },
      fresnelScale: { value: 1.5 },
      fresnelPower: { value: 4.0 },
    };

    const vertexShader = `
    uniform float fresnelBias;
    uniform float fresnelScale;
    uniform float fresnelPower;

    varying float vReflectionFactor;

    void main() {
      vec4 mvPosition = modelViewMatrix * vec4( position, 1.0 );
      vec4 worldPosition = modelMatrix * vec4( position, 1.0 );

      vec3 worldNormal = normalize( mat3( modelMatrix[0].xyz, modelMatrix[1].xyz, modelMatrix[2].xyz ) * normal );

      vec3 I = worldPosition.xyz - cameraPosition;

      vReflectionFactor = fresnelBias + fresnelScale * pow( 1.0 + dot( normalize( I ), worldNormal ), fresnelPower );

      gl_Position = projectionMatrix * mvPosition;
    }
    `;

    const fragmentShader = `
      uniform vec3 color1;
      uniform vec3 color2;

      varying float vReflectionFactor;

      void main() {
        float f = clamp( vReflectionFactor, 0.0, 1.0 );
        gl_FragColor = vec4(mix(color2, color1, vec3(f)), f);
      }
    `;

    const planetGlowMaterial = new ShaderMaterial({
      uniforms,
      vertexShader,
      fragmentShader,
      transparent: true,
      blending: AdditiveBlending,
    });
    const planetGlowMesh = new Mesh(this.planetGeometry, planetGlowMaterial);
    planetGlowMesh.scale.setScalar(1.1);
    this.planetGroup.add(planetGlowMesh);
  }

  createRings() {
    if (!this.rings) return;

    const innerRadius = this.planetSize + 0.1;
    const outerRadius = innerRadius + this.rings.ringsSize;

    const ringsGeometry = new RingGeometry(innerRadius, outerRadius, 32);

    const ringsMaterial = new MeshBasicMaterial({
      side: DoubleSide,
      transparent: true,
      map: this.loader.load(this.rings.ringsTexture),
    });

    const ringMeshs = new Mesh(ringsGeometry, ringsMaterial);
    ringMeshs.rotation.x = Math.PI / 2;
    this.planetGroup.add(ringMeshs);
  }

  createAnimateFunction() {
    return () => {
      requestAnimationFrame(this.animate);

      this.updateOrbitRotation();
      this.updatePlanetRotation();
    };
  }

  updateOrbitRotation() {
    if (this.orbitRotationDirection === "clockwise") {
      this.group.rotation.y -= this.orbitSpeed;
    } else if (this.orbitRotationDirection === "counterclockwise") {
      this.group.rotation.y += this.orbitSpeed;
    }
  }

  updatePlanetRotation() {
    if (this.planetRotationDirection === "clockwise") {
      this.planetGroup.rotation.y -= this.planetRotationSpeed;
    } else if (this.planetRotationDirection === "counterclockwise") {
      this.planetGroup.rotation.y += this.planetRotationSpeed;
    }
  }

  getPlanet() {
    return this.group;
  }
}

对于地球,我扩展了 Planet 类以添加额外的纹理,例如云和行星夜面的夜间纹理。

import {
  Mesh,
  AdditiveBlending,
  MeshBasicMaterial,
  MeshStandardMaterial,
} from "three";
import { Planet } from "./planet";

export class Earth extends Planet {
  constructor(props) {
    super(props);

    this.createPlanetLights();
    this.createPlanetClouds();
  }

  createPlanetLights() {
    const planetLightsMaterial = new MeshBasicMaterial({
      map: this.loader.load("/solar-system-threejs/assets/earth-map-2.jpg"),
      blending: AdditiveBlending,
    });
    const planetLightsMesh = new Mesh(
      this.planetGeometry,
      planetLightsMaterial
    );
    this.planetGroup.add(planetLightsMesh);

    this.group.add(this.planetGroup);
  }

  createPlanetClouds() {
    const planetCloudsMaterial = new MeshStandardMaterial({
      map: this.loader.load("/solar-system-threejs/assets/earth-map-3.jpg"),
      transparent: true,
      opacity: 0.8,
      blending: AdditiveBlending,
      alphaMap: this.loader.load(
        "/solar-system-threejs/assets/earth-map-4.jpg"
      ),
    });
    const planetCloudsMesh = new Mesh(
      this.planetGeometry,
      planetCloudsMaterial
    );
    planetCloudsMesh.scale.setScalar(1.003);
    this.planetGroup.add(planetCloudsMesh);

    this.group.add(this.planetGroup);
  }
}

通过在 Google 上搜索大约五分钟,您将看到一个表格,其中包含将行星添加到场景中所需的所有值。

Planet Size (diameter) Rotation speed Rotation direction Orbit speed
Mercury 4,880 km 10.83 km/h Counterclockwise 47.87 km/s
Venus 12,104 km 6.52 km/h Clockwise 35.02 km/s
Earth 12,742 km 1674.4 km/h Counterclockwise 29.78 km/s
Mars 6,779 km 866.5 km/h Counterclockwise 24.07 km/s
Jupiter 142,984 km 45,300 km/h Counterclockwise 13.07 km/s
Saturn 120,536 km 35,500 km/h Counterclockwise 9.69 km/s
Uranus 51,118 km 9,320 km/h Clockwise 6.81 km/s
Neptune 49,528 km 9,720 km/h Counterclockwise 5.43 km/s

Now, all the planets and the sun can be added to the scene.

const planets = [
  {
    orbitSpeed: 0.00048,
    orbitRadius: 10,
    orbitRotationDirection: "clockwise",
    planetSize: 0.2,
    planetRotationSpeed: 0.005,
    planetRotationDirection: "counterclockwise",
    planetTexture: "/solar-system-threejs/assets/mercury-map.jpg",
    rimHex: 0xf9cf9f,
  },
  {
    orbitSpeed: 0.00035,
    orbitRadius: 13,
    orbitRotationDirection: "clockwise",
    planetSize: 0.5,
    planetRotationSpeed: 0.0005,
    planetRotationDirection: "clockwise",
    planetTexture: "/solar-system-threejs/assets/venus-map.jpg",
    rimHex: 0xb66f1f,
  },
  {
    orbitSpeed: 0.00024,
    orbitRadius: 19,
    orbitRotationDirection: "clockwise",
    planetSize: 0.3,
    planetRotationSpeed: 0.01,
    planetRotationDirection: "counterclockwise",
    planetTexture: "/solar-system-threejs/assets/mars-map.jpg",
    rimHex: 0xbc6434,
  },
  {
    orbitSpeed: 0.00013,
    orbitRadius: 22,
    orbitRotationDirection: "clockwise",
    planetSize: 1,
    planetRotationSpeed: 0.06,
    planetRotationDirection: "counterclockwise",
    planetTexture: "/solar-system-threejs/assets/jupiter-map.jpg",
    rimHex: 0xf3d6b6,
  },
  {
    orbitSpeed: 0.0001,
    orbitRadius: 25,
    orbitRotationDirection: "clockwise",
    planetSize: 0.8,
    planetRotationSpeed: 0.05,
    planetRotationDirection: "counterclockwise",
    planetTexture: "/solar-system-threejs/assets/saturn-map.jpg",
    rimHex: 0xd6b892,
    rings: {
      ringsSize: 0.5,
      ringsTexture: "/solar-system-threejs/assets/saturn-rings.jpg",
    },
  },
  {
    orbitSpeed: 0.00007,
    orbitRadius: 28,
    orbitRotationDirection: "clockwise",
    planetSize: 0.5,
    planetRotationSpeed: 0.02,
    planetRotationDirection: "clockwise",
    planetTexture: "/solar-system-threejs/assets/uranus-map.jpg",
    rimHex: 0x9ab6c2,
    rings: {
      ringsSize: 0.4,
      ringsTexture: "/solar-system-threejs/assets/uranus-rings.jpg",
    },
  },
  {
    orbitSpeed: 0.000054,
    orbitRadius: 31,
    orbitRotationDirection: "clockwise",
    planetSize: 0.5,
    planetRotationSpeed: 0.02,
    planetRotationDirection: "counterclockwise",
    planetTexture: "/solar-system-threejs/assets/neptune-map.jpg",
    rimHex: 0x5c7ed7,
  },
];

planets.forEach((item) => {
  const planet = new Planet(item).getPlanet();
  scene.add(planet);
});

const earth = new Earth({
  orbitSpeed: 0.00029,
  orbitRadius: 16,
  orbitRotationDirection: "clockwise",
  planetSize: 0.5,
  planetAngle: (-23.4 * Math.PI) / 180,
  planetRotationSpeed: 0.01,
  planetRotationDirection: "counterclockwise",
  planetTexture: "/solar-system-threejs/assets/earth-map-1.jpg",
}).getPlanet();

scene.add(earth);

In result all solar system will look sth like:

Solar system with Three.js

Deploying to GitHub Pages

For deploying to set the correct base in vite.config.js.

If you are deploying to https://.github.io/, or to a custom domain through GitHub Pages, set base to '/'. Alternatively, you can remove base from the configuration, as it defaults to '/'.

If you are deploying to https://.github.io// (eg. your repository is at https://github.com//), then set base to '//'.

Go to your GitHub Pages configuration in the repository settings page and choose the source of deployment as "GitHub Actions", this will lead you to create a workflow that builds and deploys your project, a sample workflow that installs dependencies and builds using npm is provided:

# Simple workflow for deploying static content to GitHub Pages
name: Deploy static content to Pages

on:
  # Runs on pushes targeting the default branch
  push:
    branches: ['main']

  # Allows you to run this workflow manually from the Actions tab
  workflow_dispatch:

# Sets the GITHUB_TOKEN permissions to allow deployment to GitHub Pages
permissions:
  contents: read
  pages: write
  id-token: write

# Allow one concurrent deployment
concurrency:
  group: 'pages'
  cancel-in-progress: true

jobs:
  # Single deploy job since we're just deploying
  deploy:
    environment:
      name: github-pages
      url: ${{ steps.deployment.outputs.page_url }}
    runs-on: ubuntu-latest
    steps:
      - name: Checkout
        uses: actions/checkout@v4
      - name: Set up Node
        uses: actions/setup-node@v4
        with:
          node-version: 20
          cache: 'npm'
      - name: Install dependencies
        run: npm ci
      - name: Build
        run: npm run build
      - name: Setup Pages
        uses: actions/configure-pages@v4
      - name: Upload artifact
        uses: actions/upload-pages-artifact@v3
        with:
          # Upload dist folder
          path: './dist'
      - name: Deploy to GitHub Pages
        id: deployment
        uses: actions/deploy-pages@v4

That is it. If your deployment has not started automatically you can always start it manually in Actions tab in your repo. Link with deployed project can be found below.


Conclusion

That’s it for today! You can find the link to the entire project below. I hope you found this entertaining and don’t still believe the Earth is flat.
See ya!

Repository link

Deployment link

以上是使用 Three.js 的太阳能系统的详细内容。更多信息请关注PHP中文网其他相关文章!

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