javascript
/
three.js
mirror of https://github.com/tazdij/three.js.git


			
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							import * as THREE from '../../resources/threejs/r119/build/three.module.js';
import {OrbitControls} from '../../resources/threejs/r119/examples/jsm/controls/OrbitControls.js';

export const threejsLessonUtils = {
  _afterPrettifyFuncs: [],
  init() {
    if (this.renderer) {
      return;
    }

    const canvas = document.createElement('canvas');
    canvas.id = 'c';
    document.body.appendChild(canvas);
    const renderer = new THREE.WebGLRenderer({
      canvas,
      alpha: true,
      powerPreference: 'low-power',
    });
    this.pixelRatio = Math.max(2, window.devicePixelRatio);

    this.renderer = renderer;
    this.elemToRenderFuncMap = new Map();

    const resizeRendererToDisplaySize = (renderer) => {
      const canvas = renderer.domElement;
      const width = canvas.clientWidth * this.pixelRatio | 0;
      const height = canvas.clientHeight * this.pixelRatio | 0;
      const needResize = canvas.width !== width || canvas.height !== height;
      if (needResize) {
        renderer.setSize(width, height, false);
      }
      return needResize;
    };

    const clearColor = new THREE.Color('#000');
    let needsUpdate = true;
    let rafRequestId;
    let rafRunning;

    const render = (time) => {
      rafRequestId = undefined;
      time *= 0.001;

      const resized = resizeRendererToDisplaySize(renderer);

      // only update if we drew last time
      // so the browser will not recomposite the page
      // of nothing is being drawn.
      if (needsUpdate) {
        needsUpdate = false;

        renderer.setScissorTest(false);
        renderer.setClearColor(clearColor, 0);
        renderer.clear(true, true);
        renderer.setScissorTest(true);
      }

      this.elementsOnScreen.forEach(elem => {
        const fn = this.elemToRenderFuncMap.get(elem);
        const wasRendered = fn(renderer, time, resized);
        needsUpdate = needsUpdate || wasRendered;
      });

      if (needsUpdate) {
        // maybe there is another way. Originally I used `position: fixed`
        // but the problem is if we can't render as fast as the browser
        // scrolls then our shapes lag. 1 or 2 frames of lag isn't too
        // horrible but iOS would often been 1/2 a second or worse.
        // By doing it this way the canvas will scroll which means the
        // worse that happens is part of the shapes scrolling on don't
        // get drawn for a few frames but the shapes that are on the screen
        // scroll perfectly.
        //
        // I'm using `transform` on the voodoo that it doesn't affect
        // layout as much as `top` since AFAIK setting `top` is in
        // the flow but `transform` is not though thinking about it
        // the given we're `position: absolute` maybe there's no difference?
        const transform = `translateY(${window.scrollY}px)`;
        renderer.domElement.style.transform = transform;
      }

      if (rafRunning) {
        startRAFLoop();
      }
    };

    function startRAFLoop() {
      rafRunning = true;
      if (!rafRequestId) {
        rafRequestId = requestAnimationFrame(render);
      }
    }

    this.elementsOnScreen = new Set();
    this.intersectionObserver = new IntersectionObserver((entries) => {
      entries.forEach(entry => {
        if (entry.isIntersecting) {
          this.elementsOnScreen.add(entry.target);
        } else {
          this.elementsOnScreen.delete(entry.target);
        }
        // Each entry describes an intersection change for one observed
        // target element:
        //   entry.boundingClientRect
        //   entry.intersectionRatio
        //   entry.intersectionRect
        //   entry.isIntersecting
        //   entry.rootBounds
        //   entry.target
        //   entry.time
      });
      if (this.elementsOnScreen.size > 0) {
        startRAFLoop();
      } else {
        rafRunning = false;
      }
    });


  },
  addDiagrams(diagrams) {
    [...document.querySelectorAll('[data-diagram]')].forEach((elem) => {
      const name = elem.dataset.diagram;
      const info = diagrams[name];
      if (!info) {
        throw new Error(`no diagram: ${name}`);
      }
      this.addDiagram(elem, info);
    });
  },
  addDiagram(elem, info) {
    this.init();

    const scene = new THREE.Scene();
    let targetFOVDeg = 60;
    const aspect = 1;
    const near = 0.1;
    const far = 50;
    let camera = new THREE.PerspectiveCamera(targetFOVDeg, aspect, near, far);
    camera.position.z = 15;
    scene.add(camera);

    const root = new THREE.Object3D();
    scene.add(root);

    const renderInfo = {
      pixelRatio: this.pixelRatio,
      camera,
      scene,
      root,
      renderer: this.renderer,
      elem,
    };

    const obj3D = info.create({scene, camera, renderInfo});
    const promise = (obj3D instanceof Promise) ? obj3D : Promise.resolve(obj3D);

    const updateFunctions = [];
    const resizeFunctions = [];

    const settings = {
      lights: true,
      trackball: true,
      // resize(renderInfo) {
      // },
      // update(time, renderInfo) {
      // },
      render(renderInfo) {
        renderInfo.renderer.render(renderInfo.scene, renderInfo.camera);
      },
    };

    promise.then((result) => {
      const info = result instanceof THREE.Object3D ? {
        obj3D: result,
      } : result;
      if (info.obj3D) {
        root.add(info.obj3D);
      }
      if (info.update) {
        updateFunctions.push(info.update);
      }
      if (info.resize) {
        resizeFunctions.push(info.resize);
      }
      if (info.camera) {
        camera = info.camera;
        renderInfo.camera = camera;
      }

      Object.assign(settings, info);
      targetFOVDeg = camera.fov;

      if (settings.trackball !== false) {
        const controls = new OrbitControls(camera, elem);
        controls.rotateSpeed = 1 / 6;
        controls.enableZoom = false;
        controls.enablePan = false;
        controls.enableKeys = false;
        elem.removeAttribute('tabIndex');
        //resizeFunctions.push(controls.handleResize.bind(controls));
        updateFunctions.push(controls.update.bind(controls));
      }

      // add the lights as children of the camera.
      // this is because TrackballControls move the camera.
      // We really want to rotate the object itself but there's no
      // controls for that so we fake it by putting all the lights
      // on the camera so they move with it.
      if (settings.lights !== false) {
        camera.add(new THREE.HemisphereLight(0xaaaaaa, 0x444444, .5));
        const light = new THREE.DirectionalLight(0xffffff, 1);
        light.position.set(-1, 2, 4 - 15);
        camera.add(light);
      }
    });

    let oldWidth = -1;
    let oldHeight = -1;

    const render = (renderer, time) => {
      root.rotation.x = time * .1;
      root.rotation.y = time * .11;

      const rect = elem.getBoundingClientRect();
      if (rect.bottom < 0 || rect.top  > renderer.domElement.clientHeight ||
          rect.right  < 0 || rect.left > renderer.domElement.clientWidth) {
        return false;
      }

      renderInfo.width = rect.width * this.pixelRatio;
      renderInfo.height = rect.height * this.pixelRatio;
      renderInfo.left = rect.left * this.pixelRatio;
      renderInfo.bottom = (renderer.domElement.clientHeight - rect.bottom) * this.pixelRatio;

      if (renderInfo.width !== oldWidth || renderInfo.height !== oldHeight) {
        oldWidth = renderInfo.width;
        oldHeight = renderInfo.height;
        resizeFunctions.forEach(fn => fn(renderInfo));
      }

      updateFunctions.forEach(fn => fn(time, renderInfo));

      const aspect = renderInfo.width / renderInfo.height;
      const fovDeg = aspect >= 1
        ? targetFOVDeg
        : THREE.MathUtils.radToDeg(2 * Math.atan(Math.tan(THREE.MathUtils.degToRad(targetFOVDeg) * .5) / aspect));

      camera.fov = fovDeg;
      camera.aspect = aspect;
      camera.updateProjectionMatrix();

      renderer.setViewport(renderInfo.left, renderInfo.bottom, renderInfo.width, renderInfo.height);
      renderer.setScissor(renderInfo.left, renderInfo.bottom, renderInfo.width, renderInfo.height);

      settings.render(renderInfo);

      return true;
    };

    this.intersectionObserver.observe(elem);
    this.elemToRenderFuncMap.set(elem, render);
  },
  onAfterPrettify(fn) {
    this._afterPrettifyFuncs.push(fn);
  },
  afterPrettify() {
    this._afterPrettifyFuncs.forEach((fn) => {
      fn();
    });
  },
};

window.threejsLessonUtils = threejsLessonUtils;