I’m trying to implement GPU picking with Points using code I modified from the latter half of this article https://threejsfundamentals.org/threejs/lessons/threejs-picking.html

It’s been working fine for me on desktop, but I started testing different browsers and devices and it doesn’t work consistently. I made a Codepen to illustrate https://codepen.io/deklanw/pen/OJVVmEd?editors=1111

body {
  margin: 0;
#c {
  width: 100vw;
  height: 100vh;
  display: block;
<canvas id="c"></canvas>
<script type="module">
// Three.js - Picking - RayCaster w/Transparency
// from https://threejsfundamentals.org/threejs/threejs-picking-gpu.html

import * as THREE from "https://threejsfundamentals.org/threejs/resources/threejs/r113/build/three.module.js";

function main() {
  const canvas = document.querySelector("#c");
  const renderer = new THREE.WebGLRenderer({ canvas });

  const fov = 60;
  const aspect = 2; // the canvas default
  const near = 0.1;
  const far = 200;
  const camera = new THREE.PerspectiveCamera(fov, aspect, near, far);
  camera.position.z = 30;

  const scene = new THREE.Scene();
  scene.background = new THREE.Color(0);
  const pickingScene = new THREE.Scene();
  pickingScene.background = new THREE.Color(0);

  // put the camera on a pole (parent it to an object)
  // so we can spin the pole to move the camera around the scene
  const cameraPole = new THREE.Object3D();

  function randomNormalizedColor() {
    return Math.random();

  function getRandomInt(n) {
    return Math.floor(Math.random() * n);

  function getCanvasRelativePosition(e) {
    const rect = canvas.getBoundingClientRect();
    return {
      x: e.clientX - rect.left,
      y: e.clientY - rect.top

  const textureLoader = new THREE.TextureLoader();
  const particleTexture =

  const vertexShader = `
    attribute float size;
    attribute vec3 customColor;

    varying vec3 vColor;

    void main() {
        vColor = customColor;
        vec4 mvPosition = modelViewMatrix * vec4( position, 1.0 );
        gl_PointSize = size * ( 100.0 / length( mvPosition.xyz ) );
        gl_Position = projectionMatrix * mvPosition;

  const fragmentShader = `
    uniform sampler2D texture;
    varying vec3 vColor;

    void main() {
        vec4 tColor = texture2D( texture, gl_PointCoord );
        if (tColor.a < 0.5) discard;
        gl_FragColor = mix( vec4( vColor.rgb, 1.0 ), tColor, 0.1 );

  const pickFragmentShader = `
    uniform sampler2D texture;
    varying vec3 vColor;

    void main() {
      vec4 tColor = texture2D( texture, gl_PointCoord );
      if (tColor.a < 0.25) discard;
      gl_FragColor = vec4( vColor.rgb, 1.0);

  const materialSettings = {
    uniforms: {
      texture: {
        type: "t",
        value: textureLoader.load(particleTexture)
    vertexShader: vertexShader,
    fragmentShader: fragmentShader,
    blending: THREE.NormalBlending,
    depthTest: true,
    transparent: false

  const createParticleMaterial = () => {
    const material = new THREE.ShaderMaterial(materialSettings);
    return material;

  const createPickingMaterial = () => {
    const material = new THREE.ShaderMaterial({
      fragmentShader: pickFragmentShader,
      blending: THREE.NormalBlending
    return material;

  const geometry = new THREE.BufferGeometry();
  const pickingGeometry = new THREE.BufferGeometry();
  const colors = [];
  const sizes = [];
  const pickingColors = [];
  const pickingColor = new THREE.Color();
  const positions = [];

  for (let i = 0; i < 30; i++) {
    colors[3 * i] = randomNormalizedColor();
    colors[3 * i + 1] = randomNormalizedColor();
    colors[3 * i + 2] = randomNormalizedColor();

    const rgbPickingColor = pickingColor.setHex(i + 1);
    pickingColors[3 * i] = rgbPickingColor.r;
    pickingColors[3 * i + 1] = rgbPickingColor.g;
    pickingColors[3 * i + 2] = rgbPickingColor.b;

    sizes[i] = getRandomInt(20);

    positions[3 * i] = getRandomInt(20);
    positions[3 * i + 1] = getRandomInt(20);
    positions[3 * i + 2] = getRandomInt(20);

    new THREE.Float32BufferAttribute(positions, 3)
    new THREE.Float32BufferAttribute(colors, 3)
  geometry.setAttribute("size", new THREE.Float32BufferAttribute(sizes, 1));


  const material = createParticleMaterial();
  const points = new THREE.Points(geometry, material);

  // setup geometry and material for GPU picking
    new THREE.Float32BufferAttribute(positions, 3)
    new THREE.Float32BufferAttribute(pickingColors, 3)
    new THREE.Float32BufferAttribute(sizes, 1)


  const pickingMaterial = createPickingMaterial();
  const pickingPoints = new THREE.Points(pickingGeometry, pickingMaterial);


  function resizeRendererToDisplaySize(renderer) {
    const canvas = renderer.domElement;
    const width = canvas.clientWidth;
    const height = canvas.clientHeight;
    const needResize = canvas.width !== width || canvas.height !== height;
    if (needResize) {
      renderer.setSize(width, height, false);
    return needResize;

  class GPUPickHelper {
    constructor() {
      // create a 1x1 pixel render target
      this.pickingTexture = new THREE.WebGLRenderTarget(1, 1);
      this.pixelBuffer = new Uint8Array(4);
    pick(cssPosition, pickingScene, camera) {
      const { pickingTexture, pixelBuffer } = this;

      // set the view offset to represent just a single pixel under the mouse
      const pixelRatio = renderer.getPixelRatio();
        renderer.getContext().drawingBufferWidth, // full width
        renderer.getContext().drawingBufferHeight, // full top
        (cssPosition.x * pixelRatio) | 0, // rect x
        (cssPosition.y * pixelRatio) | 0, // rect y
        1, // rect width
        1 // rect height
      // render the scene
      renderer.render(pickingScene, camera);
      // clear the view offset so rendering returns to normal
      //read the pixel
        0, // x
        0, // y
        1, // width
        1, // height

      const id =
        (pixelBuffer[0] << 16) | (pixelBuffer[1] << 8) | pixelBuffer[2];
      console.log(`You clicked sphere number ${id}`);
      return id;

  const pickHelper = new GPUPickHelper();

  function render(time) {
    time *= 0.001; // convert to seconds;

    if (resizeRendererToDisplaySize(renderer)) {
      const canvas = renderer.domElement;
      camera.aspect = canvas.clientWidth / canvas.clientHeight;

    cameraPole.rotation.y = time * 0.1;

    renderer.render(scene, camera);


  function onClick(e) {
    const pickPosition = getCanvasRelativePosition(e);
    const pickedID = pickHelper.pick(pickPosition, pickingScene, camera);

  function onTouch(e) {
    const touch = e.touches[0];
    const pickPosition = getCanvasRelativePosition(touch);
    const pickedID = pickHelper.pick(pickPosition, pickingScene, camera);

  window.addEventListener("mousedown", onClick);
  window.addEventListener("touchstart", onTouch);


If you click (or tap) on the nodes their IDs should pop up in the console. On some devices I’m just getting 0, as in picking the background.

Anyone know why?

Also, if there’s a way to do picking in this case (Point mesh with variable size points via ShaderMaterial) with an easier method that’s still performant, I’m curious about how


I removed the 1x1 render target optimization and it seems to have fixed it. Now I'd like to know what about that optimization causes the problem..

1 Answer 1


the problem is you can't use Points this way across devices.

Whether a point is drawn when its center is offscreen or not is device independent (the OpenGL ES / WebGL spec says it's still supposed to be drawn, the OpenGL spec says it's not. There are no tests for it so each driver is different) and it would be too much work for WebGL implentations to work around so they don't. AFAIK Intel and NVidia do draw them. AMD and PowerVR based (iPhone) do not draw them.

You can see this problem if you make the circles large and you make sure they go offscreen (and you may need to make your canvas small). On some devices they will smoothly go offscreen, on other devices as soon as their center goes offscreen they will disappear (often depending on the size of the point and the size of the viewport)

This means your example does not really work in either case, with or without the 1x1 pixel render target it's just that with the 1x1 pixel render target pretty much all of the circles have their center outside that 1x1 pixel area so they don't get drawn on some devices. When you make the render target match the size of the canvas then most of the circles' centers are inside but you'll still get picking errors at the edges.

To solve this you'll need to draw your points using quads instead of points. There are many ways to do that. Draw each quad as a separate mesh or sprite, or merge all the quads into another mesh, or use InstancedMesh where you'll need a matrix per point, or write custom shaders to do points (see the last example on this article)

Note that points have other issues too. By default they don't scale relative to the canvas size (of course you can fix this in your shader and three.js has this option as well). They also have a device independent maximum size which according to the spec can be as low as 1 pixel. They don't respond well to device pixel ratio settings (though you could fix that in code as well). For all those reasons points have a limited uses. The large circles the code is drawing is arguably beyond that limit.

  • Thanks so much! I honestly would have never figured this out. Looks like I have to read up on WebGL. Going to start reading your WebGL Fundamentals site... I want to ask, though: of those alternative possibilities you mention, which would be most performant? Currently I'm rendering about 30k~ of these points, but I have ambitions for more. Feb 19, 2020 at 18:59
  • Drawing them all in one draw call is faster than drawing them separately. Drawing them as a mesh of quads is can be faster or slower than InstancedMesh depending on GPU/Driver and the data. I think for quads a single mesh is faster but maybe not by much.
    – gman
    Feb 19, 2020 at 19:09
  • To emulate POINTS you'd want 6 vertices for a quad and then you need to move the positions in view space (for 3d) or screen space (for 2d) around some center point in the vertex shader. I don't have a simple example to show how to do that but this old example does it. Or you can ask a new question though maybe there is already an answer.
    – gman
    Feb 19, 2020 at 19:10
  • I did some reading and thought about it. Made a new thread because it's rightfully a different topic stackoverflow.com/questions/60313368/… But, for this topic, you said "you'll still get picking errors at the edges". If on some devices the points just disappear from view when the center leaves the viewport, why would I get picking errors? Spheres disappearing might be janky but I don't see how it would cause picking problems Feb 20, 2020 at 5:22
  • I suppose if you're using the non 1x1 pixel solution then you're correct, a sphere with its center slighted outside the canvas will disappear early from both the visible view (the canvas) and the picking view (the render target) at the same time so there won't be a picking error. I just assumed you didn't want the spheres to suddenly disappear as soon as their centers are out of the view.
    – gman
    Feb 20, 2020 at 8:43

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