Find out here about the changes. TLDR: bugfixes, new features, react-native, better types, very few breaking changes (mostly just useRender -> useFrame and apply -> extend).
These demos are real, you can click them! They contain the full code, too.
npm install three react-three-fiber
This is a renderer for Threejs on the web and react-native. Building a dynamic scene graph becomes so much easier when you can break it up into declarative, re-usable components that react to state changes.
This is less of an abstraction and more of a pure reconciler (like react-dom in relation to HTML). It does not target a specific Threejs version nor does it need updates when Threejs alters, adds or removes features. It won't change any specifics or rules. There are zero limitations.
No. But it could potentially outperform it. Rendering performance is fully up to Threejs and the GPU, react-three-fiber drives a renderloop outside of React with zero overhead. But React is very efficent in building and updating component-trees, this can make a major difference.
Copy the following into a project to get going. Here's the same running in a code sandbox.
import { Canvas, useFrame } from 'react-three-fiber'
function Thing() {
const ref = useRef()
useFrame(() => (ref.current.rotation.z += 0.01))
return (
<mesh
ref={ref}
onClick={e => console.log('click')}
onPointerOver={e => console.log('hover')}
onPointerOut={e => console.log('unhover')}>
<planeBufferGeometry attach="geometry" args={[1, 1]} />
<meshBasicMaterial attach="material" color="hotpink" opacity={0.5} transparent />
</mesh>
)
}
<Canvas>
<Thing />
</Canvas>
The Canvas
object is your portal into Threejs. It renders Threejs elements, not DOM elements!
<Canvas
children // Either a function child (which receives state) or regular children
gl // Props that go into the default webGL-renderer
camera // Props that go into the default camera
raycaster // Props that go into the default raycaster
shadowMap // Props that go into gl.shadowMap, can also be set true for PCFsoft
vr = false // Switches renderer to VR mode, then uses gl.setAnimationLoop
orthographic = false // Creates an orthographic camera if true
noEvents = false // Switch off raytracing and event support
pixelRatio = undefined // You could provide window.devicePixelRatio if you like
invalidateFrameloop = false // When true it only renders on changes, when false it's a game loop
updateDefaultCamera = true // Adjusts default camera on size changes
onCreated // Callback when vdom is ready (you can block first render via promise)
onPointerMissed /> // Response for pointer clicks that have missed a target
You can give it additional properties like style and className, which will be added to the container (a div) that holds the dom-canvas element.
Canvas will create a translucent WebGL-renderer with the following properties: antialias, alpha, setClearAlpha(0)
A default perspective camera: fov: 75, near: 0.1, far: 1000, position.z: 5
A default orthographic camera if Canvas.orthographic is true: near: 0.1, far: 1000, position.z: 5
A default shadowMap if Canvas.shadowMap is true: type: PCFSoftShadowMap
A default scene (into which all the JSX is rendered) and a raycaster.
You do not have to use any of these objects, look under "receipes" down below if you want to bring your own.
You can use Threejs's entire object catalogue and all properties. When in doubt, always consult the docs.
You could lay out an object like this:
<mesh
visible
userData={{ test: 'hello' }}
position={new THREE.Vector3(1, 2, 3)}
rotation={new THREE.Euler(0, 0, 0)}
geometry={new THREE.SphereGeometry(1, 16, 16)}
material={new THREE.MeshBasicMaterial({ color: new THREE.Color('hotpink'), transparent: true })}
/>
The problem is that all of these properties will always be re-created. Instead, you should define properties declaratively.
<mesh visible userData={{ test: 'hello' }} position={[1, 2, 3]} rotation={[0, 0, 0]}>
<sphereGeometry attach="geometry" args={[1, 16, 16]} />
<meshStandardMaterial attach="material" color="hotpink" transparent />
</mesh>
All properties that have a .set()
method can be given a shortcut. For example THREE.Color.set can take a color string, hence instead of color={new THREE.Color('hotpink')}
you can do color="hotpink"
. Some set
methods take multiple arguments (THREE.Vector3.set), so you can pass an array position={[100, 0, 0]}
.
Stow away non-Object3D primitives (geometries, materials, etc) into the render tree so that they become managed and reactive. They take the same properties they normally would, constructor arguments are passed with args
. Using the attach
property objects bind automatically to their parent and are taken off it once they unmount.
You can nest primitive objects, too, which is good for awaiting async textures and such. You could use React-suspense if you wanted!
<meshBasicMaterial attach="material">
<texture attach="map" image={img} onUpdate={self => img && (self.needsUpdate = true)} />
Sometimes attaching isn't enough. For example, this code attaches effects to an array called "passes" of the parent effectComposer
. Note the use of attachArray
which adds the object to the target array and takes it out on unmount:
<effectComposer>
<renderPass attachArray="passes" scene={scene} camera={camera} />
<glitchPass attachArray="passes" renderToScreen />
You can also attach to named parent properties using attachObject={[target, name]}
, which adds the object and takes it out on unmount. The following adds a buffer-attribute to parent.attributes.position.
<bufferGeometry attach="geometry">
<bufferAttribute attachObject={['attributes', 'position']} count={v.length / 3} array={v} itemSize={3} />
If you want to reach into nested attributes (for instance: mesh.rotation.x
), just use dash-case:
<mesh rotation-x={1} material-uniforms-resolution-value={[1 / size.width, 1 / size.height]} />
You can use the primitive
placeholder for that. You can still give it properties or attach nodes to it.
const mesh = new THREE.Mesh()
return <primitive object={mesh} position={[0, 0, 0]} />
The extend
function extends three-fibers catalogue of known native JSX elements.
import { extend } from 'react-three-fiber'
import { EffectComposer } from 'three/examples/jsm/postprocessing/EffectComposer'
import { RenderPass } from 'three/examples/jsm/postprocessing/RenderPass'
extend({ EffectComposer, RenderPass })
<effectComposer>
<renderPass />
Threejs objects that implement their own raycast
method (meshes, lines, etc) can be interacted with by declaring events on the object. We support pointer events (you need to polyfill them yourself), clicks and wheel-scroll. Events contain the browser event as well as the Threejs event data (object, point, distance, etc).
Additionally there's a special onUpdate
that is called every time the object gets fresh props, which is good for things like self => (self.verticesNeedUpdate = true)
.
<mesh
onClick={e => console.log('click')}
onWheel={e => console.log('wheel spins')}
onPointerUp={e => console.log('up')}
onPointerDown={e => console.log('down')}
onPointerOver={e => console.log('hover')}
onPointerOut={e => console.log('unhover')}
onPointerMove={e => console.log('move')}
onUpdate={self => console.log('props have been updated')}
/>
({
...DomEvent // All the original event data
...ThreeEvent // All of Three's intersection data
object: Object3D // The object that was actually hit
eventObject: Object3D // The object that registered the event
unprojectedPoint: Vector3 // Camera-unprojected point
ray: Ray // The ray that was used to strike the object
sourceEvent: DomEvent // A reference to the host event
delta: number // Initial-click delta
}) => ...
onPointerDown={e => {
// Only the mesh closest to the camera will be processed
e.stopPropagation()
// You may optionally capture the target
e.target.setPointerCapture(e.pointerId)
}}
onPointerUp={e => {
e.stopPropagation()
// Optionally release capture
e.target.releasePointerCapture(e.pointerId)
}}
Hooks can only be used inside the Canvas element because they rely on context! You cannot expect something like this to work:
function App() {
const { size } = useThree() // This will just crash
return (
<Canvas>
<mesh>
Do this instead:
function SomeComponent() {
const { size } = useThree()
return <mesh />
}
function App() {
return (
<Canvas>
<SomeComponent />
This hooks gives you access to all the basic objects that are kept internally, like the default renderer, scene, camera. It also gives you the current size of the canvas in screen and viewport coordinates.
import { useThree } from 'react-three-fiber'
const {
gl, // WebGL renderer
scene, // Default scene
camera, // Default camera
size, // Bounds of the view (which stretches 100% and auto-adjusts)
viewport, // Bounds of the viewport in 3d units + factor (size/viewport)
aspect, // Aspect ratio (size.width / size.height)
mouse, // Current 2D mouse coordinates
clock, // THREE.Clock (usefull for useFrame deltas)
invalidate, // Invalidates a single frame (for <Canvas invalidateFrameloop />)
intersect, // Calls onMouseMove handlers for objects underneath the cursor
setDefaultCamera, // Sets the default camera
} = useThree()
This hooks calls you back every frame, which is good for running effects, updating controls, etc. You receive the state (same as useThree) and a clock delta. If you supply a render priority greater than zero it will switch off automatic rendering entirely, you can then control rendering yourself. If you have multiple frames with a render priority then they are ordered highest priority last, similar to the web's z-index. Frames are managed, three-fiber will remove them automatically when the component that holds them is unmounted.
Updating controls:
import { useFrame } from 'react-three-fiber'
const controls = useRef()
useFrame(state => controls.current.update())
return <orbitControls ref={controls} />
Taking over the render-loop:
useFrame(({ gl, scene, camera }) => gl.render(scene, camera), 1)
When you want to share and re-use resources. useResource
creates a ref and re-renders the component when it becomes available next frame.
import { useResource } from 'react-three-fiber'
const [ref, material] = useResource()
return (
<meshBasicMaterial ref={ref} />
{material && (
<mesh material={material} />
<mesh material={material} />
<mesh material={material} />
When objects need to be updated imperatively.
import { useUpdate } from 'react-three-fiber'
const ref = useUpdate(
geometry => {
geometry.addAttribute('position', getVertices(x, y, z))
geometry.attributes.position.needsUpdate = true
},
[x, y, z] // execute only if these properties change
)
return <bufferGeometry ref={ref} />
This hooks loads assets and suspends for easier fallback- and error-handling. If you need to lay out GLTF's declaratively check out gltfjsx.
import React, { Suspense } from 'react'
import { useLoader } from 'react-three-fiber'
import { GLTFLoader } from 'three/examples/jsm/loaders/GLTFLoader'
function Asset({ url }) {
const gltf = useLoader(GLTFLoader, url)
return <primitive object={gltf.scene} />
}
<Suspense fallback={<Cube />}>
<Asset url="/spaceship.gltf" />
</Suspense>
You can provide a callback if you need to configure your loader:
import { DRACOLoader } from 'three/examples/jsm/loaders/DRACOLoader'
useLoader(GLTFLoader, url, loader => {
const dracoLoader = new DRACOLoader()
dracoLoader.setDecoderPath('/draco-gltf/')
loader.setDRACOLoader(dracoLoader)
})
It can also make multiple requests in parallel:
const [bumpMap, specMap, normalMap] = useLoader(TextureLoader, [url1, url2, url2])
import {
addEffect, // Adds a global callback which is called each frame
invalidate, // Forces view global invalidation
apply, // Extends the native-object catalogue
createPortal, // Creates a portal (it's a React feature for re-parenting)
render, // Internal: Renders three jsx into a scene
unmountComponentAtNode, // Internal: Unmounts root scene
applyProps, // Internal: Sets element properties
} from 'react-three-fiber'
Recipes and FAQ: /react-three-fiber/recipes.md
GLTF-to-JSX converter: https://github.com/react-spring/gltfjsx
Learn-with-jason: https://www.youtube.com/watch?v=1rP3nNY2hTo
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