Three.js renderer implementation for the 3D Tiles format. The renderer supports most of the 3D Tiles spec features with a few exceptions. See Issue #15 for information on which features are not yet implemented.
If a tile set or geometry does not load or render properly please make an issue! Example data is needed for adding and testing features.
Examples
Dingo Gap Mars dataset with multiple tile sets!
Kitchen sink example with all options here!
Rendering shadows from offscreen tiles example here!
Loading 3D tiles from Cesium Ion!
Debug Pages
npm install 3d-tiles-renderer --save
Setting up a basic application with a 3D Tile Set.
import { TilesRenderer } from '3d-tiles-renderer';
// ... initialize three scene ...
const tilesRenderer = new TilesRenderer( './path/to/tileset.json' );
tilesRenderer.setCamera( camera );
tilesRenderer.setResolutionFromRenderer( camera, renderer );
scene.add( tilesRenderer.group );
renderLoop();
function renderLoop() {
requestAnimationFrame( renderLoop );
// The camera matrix is expected to be up to date
// before calling tilesRenderer.update
camera.updateMatrixWorld();
tilesRenderer.update();
renderer.render( scene, camera );
}
Setting up a 3D Tile Set using a custom material.
const tilesRenderer = new TilesRenderer( './path/to/tileset.json' );
tilesRenderer.setCamera( camera );
tilesRenderer.setResolutionFromRenderer( camera, renderer );
tilesRenderer.onLoadModel = function ( scene ) {
// create a custom material for the tile
scene.traverse( c => {
if ( c.material ) {
c.originalMaterial = c.material;
c.material = new MeshBasicMaterial();
}
} );
};
tilesRenderer.onDisposeModel = function ( scene ) {
// dispose of any manually created materials
scene.traverse( c => {
if ( c.material ) {
c.material.dispose();
}
} );
};
scene.add( tilesRenderer.group );
Using multiple tiles renderers that share LRUCache and PriorityQueue instances to cut down on memory and correctly prioritize downloads.
// create multiple tiles renderers
const tilesRenderer = new TilesRenderer( './path/to/tileset.json' );
tilesRenderer.setCamera( camera );
tilesRenderer.setResolutionFromRenderer( camera, renderer );
const tilesRenderer2 = new TilesRenderer( './path/to/tileset2.json' );
tilesRenderer2.setCamera( camera );
tilesRenderer2.setResolutionFromRenderer( camera, renderer );
// set the second renderer to share the cache and queues from the first
tilesRenderer2.lruCache = tilesRenderer.lruCache;
tilesRenderer2.downloadQueue = tilesRenderer.downloadQueue;
tilesRenderer2.parseQueue = tilesRenderer.parseQueue;
// add them to the scene
scene.add( tilesRenderer.group );
scene.add( tilesRenderer2.group );
Adding support for DRACO decompression within the GLTF files that are transported in B3DM and I3DM formats. The same approach can be used to add support for KTX2 and DDS textures.
// Note the DRACO compression files need to be supplied via an explicit source.
// We use unpkg here but in practice should be provided by the application.
const dracoLoader = new DRACOLoader();
dracoLoader.setDecoderPath( 'https://unpkg.com/three@0.123.0/examples/js/libs/draco/gltf/' );
const loader = new GLTFLoader( tiles.manager );
loader.setDRACOLoader( dracoLoader );
const tilesRenderer = new TilesRenderer( './path/to/tileset.json' );
tilesRenderer.manager.addHandler( /\.gltf$/, loader );
Adding support for DRACO decompression within the PNTS files.
// Note the DRACO compression files need to be supplied via an explicit source.
// We use unpkg here but in practice should be provided by the application.
const dracoLoader = new DRACOLoader();
dracoLoader.setDecoderPath( 'https://unpkg.com/three@0.123.0/examples/js/libs/draco/gltf/' );
const tilesRenderer = new TilesRenderer( './path/to/tileset.json' );
tilesRenderer.manager.addHandler( /\.drc$/, loader );
Loading from Cesium Ion requires some extra fetching of the ion url endpoint, as well as a temporary bearer access token. A full example is found in the ionExample.js file in the examples folder.
Set the desired assetId as well as your Ion AccessToken. More reading is provided by the Cesium REST API documentation.
// fetch a temporary token for the Cesium Ion asset
const url = new URL( `https://api.cesium.com/v1/assets/${ assetId }/endpoint` );
url.searchParams.append( 'access_token', accessToken );
fetch( url, { mode: 'cors' } )
.then( res => res.json() )
.then( json => {
url = new URL( json.url );
const version = url.searchParams.get( 'v' );
tiles = new TilesRenderer( url );
tiles.fetchOptions.headers = {};
tiles.fetchOptions.headers.Authorization = `Bearer ${json.accessToken}`;
// Prefilter each model fetch by setting the cesium Ion version to the search
// parameters of the url.
tiles.onPreprocessURL = uri => {
uri = new URL( uri );
uri.searchParams.append( 'v', version );
return uri;
};
} );
The tile set and model load callbacks can be used to detect when the data has changed and a new render is necessary.
let needsRerender = true;
const tilesRenderer = new TilesRenderer( './path/to/tileset.json' );
tilesRenderer.onLoadTileSet = () => needsRerender = true;
tilesRenderer.onLoadModel = () => needsRerender = true;
function renderLoop() {
requestAnimationFrame( renderLoop );
if ( needsRerender ) {
needsRerender = false;
camera.updateMatrixWorld();
tilesRenderer.update();
renderer.render( scene, camera );
}
}
renderLoop();
How to find the batch id and batch table associated with a mesh and read the data.
const tilesRenderer = new TilesRenderer( './path/to/tileset.json' );
// ...checking intersections...
const intersects = raycaster.intersectObject( scene, true );
if ( intersects.length ) {
const { face, object } = intersects[ 0 ];
const batchidAttr = object.geometry.getAttribute( '_batchid' );
if ( batchidAttr ) {
// Traverse the parents to find the batch table.
let batchTableObject = object;
while ( ! batchTableObject.batchTable ) {
batchTableObject = batchTableObject.parent;
}
// Log the batch data
const batchTable = batchTableObject.batchTable;
const hoveredBatchid = batchidAttr.getX( face.a );
const batchData = batchTable.getData( 'BatchTableKey' );
if ( batchData ) {
console.log( batchData[ hoveredBatchid ] );
}
}
}
extends TilesRendererBase, which can be used to implement a 3d tiles renderer in other engines
fetchOptions = {} : Object
Options passed to fetch
when loading tile set and model data.
errorTarget = 6 : Number
The target screenspace error in pixels to target when updating the geometry. Tiles will not render if they have below this level of screenspace error. See the "geometric error" section in the 3d tiles specification for more information.
errorThreshold = Infinity : Number
Value used to compute the threshold errorTarget * errorThreshold
above which tiles will not load or render. This is used to enable traversal to skip loading and rendering parent tiles far from the cameras current screenspace error requirement. If errorThreshold
is set to Infinity
then all parent tiles will be loaded and rendered. If it's set to 0
then no parent tiles will render and only the tiles that are being rendered will be loaded.
Note that if the camera position zooms in or out dramatically setting this to a value other than Infinity
could result in tiles flickering if the renderer updates to display tiles that were previously outside the error threshold. As such this setting is best suited for when camera movement is limited smaller movement scales such as real world movement speeds.
maxDepth = Infinity : Number
The max depth to which tiles will be loaded and rendered. Setting it to 1
will only render the root tile. If the tile at depth maxDepth
is an empty tile then the next set of visible children will be rendered.
loadSiblings = true : Boolean
If true then all sibling tiles will be loaded, as well, to ensure coherence when moving the camera. If false then only currently viewed tiles will be loaded.
displayActiveTiles = false : Boolean
"Active tiles" are those that are loaded and available but not necessarily visible. If loadSiblings is true then the tiles loaded up to the extents of the tile set will be considered active even outside the camera view. These tiles are useful for raycasting off camera or for casting shadows.
Active tiles not currently visible in a camera frustum are removed from the scene as an optimization. Setting displayActiveTiles
to true will keep them in the scene to be rendered from an outside camera view not accounted for by the tiles renderer.
autoDisableRendererCulling = true : Boolean
If true then all tile meshes automatically have their frustumCulled field set to false. This is useful particularly when using one camera because the tiles renderer automatically performs it's own frustum culling on visible tiles. If displayActiveTiles is true or multiple cameras are being used then you may consider setting this to false.
optimizeRaycast = true : Boolean
If true then the raycast
functions of the loaded tile objects are overriden to disable raycasting and the TilesRenderer.group
raycast function is used to perform a raycast over all visible tiles. This enables an optimized traversal for raycasting against tiles. If raycaster.firstHitOnly = true
then as well as a more optimal traversal of tiles the raycast will end early as soon as the closest intersction is found.
If you would like to manage raycasting against tiles yourself this behavior can be disabled if needed by setting optizeRaycast
to false.
onPreprocessURL = null : ( uri : string | URL ) => string | URL;
Function to preprocess the url for each individual tile geometry or child tile set to be loaded. If null then the url is used directly.
lruCache = new LRUCache() : LRUCache
NOTE: This cannot be set once update is called for the first time.
downloadQueue = new PriorityQueue : PriorityQueue
NOTE: This cannot be set once update is called for the first time.
parseQueue = new PriorityQueue : PriorityQueue
NOTE: This cannot be modified once update is called for the first time.
group : Group
The container group for the 3d tiles. Add this to the three.js scene in order to render it.
When raycasting a higher performance traversal approach is used (see optimizeRaycast).
manager : LoadingManager
The manager used when loading tile geometry.
constructor( url : String )
Takes the url of the tileset.json
for the tile set to be rendered.
update() : void
Updates the tiles to render and kicks off loads for the appropriate tiles in the 3d tile set.
Both group.matrixWorld
and all cameras world matrices are expected to be up to date before this is called.
resetFailedTiles() : void
If any tiles failed to load due to server or network issues then they will not be retried by automatically. This function clears all failed tile states so unloaded tiles can be retried again.
getBounds( box : Box3 ) : boolean
Sets box
to the axis aligned root bounding box of the tile set in the group frame. Returns false
if the tile root was not loaded.
getOrientedBounds( box : Box3, boxTransform : Matrix4 ) : boolean;
Sets box
and boxTransform
to the bounds and matrix that describe the oriented bounding box that encapsulates the root of the tile set. Returns false
if the tile root was not loaded.
getBoundingSphere( sphere : Sphere ) : boolean;
Sets sphere
to the bounding sphere that encapsulates the root of the tile set. Returns false
if the tile root was not loaded.
hasCamera( camera : Camera ) : boolean
Returns true
if the camera has already been set on the renderer.
setCamera( camera : Camera ) : boolean
Adds the camera to the camera to be accounted for when traversing the tile set. Returns false
if the camera is already being tracked. Returns true
otherwise.
deleteCamera( camera : Camera ) : boolean
Removes the given camera from being accounted for when traversing the tile set. Returns false
if the camera was not tracked.
setResolution( camera : Camera, resolution : Vector2 ) : boolean
setResolution( camera : Camera, x : number, y : number ) : boolean
Sets the resolution being rendered to for the given camera. Returns false
if the camera is not being tracked.
setResolutionFromRenderer( camera : Camera, renderer : WebGLRenderer ) : boolean
Sets the resolution being rendered to for the given camera via renderer which accounts for canvas size and current pixel ratio. Returns false
if the camera is not being tracked.
forEachLoadedModel( callback : ( scene : Object3D, tile : object ) => void ) : void
Fires the callback for every loaded scene in the hierarchy with the associatd tile as the second argument. This can be used to update the materials of all loaded meshes in the tile set.
onLoadTileSet = null : ( tileSet : Tileset ) => void
Callback that is called whenever a tile set is loaded.
onLoadModel = null : ( scene : Object3D, tile : Tile ) => void
Callback that is called every time a model is loaded. This can be used in conjunction with .forEachLoadedModel to set the material of all load and still yet to load meshes in the tile set.
onDisposeModel = null : ( scene : Object3D, tile : Tile ) => void
Callback that is called every time a model is disposed of. This should be used in conjunction with .onLoadModel to dispose of any custom materials created for a tile. Note that the textures, materials, and geometries that a tile loaded in with are all automatically disposed of even if they have been removed from the tile meshes.
onTileVisibilityChange = null : ( scene : Object3D, tile : Tile, visible : boolean ) => void
Callback that is called when a tile's visibility changed. The parameter visible
is true
when the tile is visible
dispose() : void
Disposes of all the tiles in the renderer. Calls dispose on all materials, textures, and geometries that were loaded by the renderer and subsequently calls onDisposeModel for any loaded tile model.
extends TilesRenderer
Special variant of TilesRenderer that includes helpers for debugging and visualizing the various tiles in the tile set. Material overrides will not work as expected with this renderer.
colorMode = NONE : ColorMode
Which color mode to use when rendering the tile set. The following exported enumerations can be used:
// No special color mode. Uses the default materials.
NONE
// Render the screenspace error from black to white with errorTarget
// being the maximum value.
SCREEN_ERROR
// Render the geometric error from black to white with maxDebugError
// being the maximum value.
GEOMETRIC_ERROR
// Render the distance from the camera to the tile as black to white
// with maxDebugDistance being the maximum value.
DISTANCE
// Render the depth of the tile relative to the root as black to white
// with maxDebugDepth being the maximum value.
DEPTH
// Render the depth of the tile relative to the nearest rendered parent
// as black to white with maxDebugDepth being the maximum value.
RELATIVE_DEPTH
// Render leaf nodes as white and parent nodes as black.
IS_LEAF
// Render the tiles with a random color to show tile edges clearly.
RANDOM_COLOR
// Render every individual mesh in the scene with a random color.
RANDOM_NODE_COLOR
// Sets a custom color using the customColorCallback call back.
CUSTOM_COLOR
customColorCallback: (tile: Tile, child: Object3D) => void
The callback used if debugColor
is set to CUSTOM_COLOR
. Value defaults to null
and must be set explicitly.
displayBoxBounds = false : Boolean
Display wireframe bounding boxes from the tiles boundingVolume.box
(or derived from the region bounds) for every visible tile.
displaySphereBounds = false : Boolean
Display wireframe bounding boxes from the tiles boundingVolume.sphere
(or derived from the bounding box / region bounds) for every visible tile.
displayRegionBounds = false : Boolean
Display wireframe bounding rgions from the tiles boundingVolume.region
for every visible tile if it exists.
maxDebugDepth = - 1 : Number
The depth value that represents white when rendering with DEPTH
or RELATIVE_DEPTH
colorMode. If maxDebugDepth
is -1
then the maximum depth of the tile set is used.
maxDebugError = - 1 : Number
The error value that represents white when rendering with GEOMETRIC_ERROR
colorMode. If maxDebugError
is -1
then the maximum geometric error in the tile set is used.
maxDebugDistance = - 1 : Number
The distance value that represents white when rendering with DISTANCE
colorMode. If maxDebugDistance
is -1
then the radius of the tile set is used.
getDebugColor : ( val : Number, target : Color ) => void
The function used to map a [0, 1] value to a color for debug visualizations. By default the color is mapped from black to white.
Piority-sorted queue to prioritize file downloads and parsing.
maxJobs = 6 : number
The maximum number of jobs to be processing at once.
priorityCallback = null : ( itemA, itemB ) => Number
Function to derive the job priority of the given item. Higher priority values get processed first.
schedulingCallback = requestAnimationFrame : ( cb : Function ) => void
A function used for scheduling when to run jobs next so more work doesn't happen in a single frame than there is time for -- defaults to the next frame. This should be overriden in scenarios where requestAnimationFrame is not reliable, such as when running in WebXR. See the VR demo for one example on how to handle this with WebXR.
Utility class for the TilesRenderer to keep track of currently used items so rendered items will not be unloaded.
maxSize = 800 : number
The maximum cached size. If that current amount of cached items is equal to this value then no more items can be cached.
minSize = 600 : number
The minimum cache size. Above this cached data will be unloaded if it's unused.
unloadPercent = 0.05 : number
The maximum percentage of minSize to unload during a given frame.
unloadPriorityCallback = null : ( item ) => Number
Function to derive the unload priority of the given item. Higher priority values get unloaded first.
getKeys() : Array<String>
Returns the keys of all the data in the batch table.
getData(
key : String,
defaultComponentType = null : String | null,
defaultType = null : String | null,
) : Array | TypedArray | null
Returns the data associated with the key
passed into the function. If the component and type are specified in the batch table contents then those values are used otherwise the values in defaultComponentType
and defaultType
are used. Returns null if the key is not in the table.
defaultComponentType
can be set to BYTE
, UNSIGNED_BYTE
, SHORT
, UNSIGNED_SHORT
, INT
, UNSIGNED_INT
, FLOAT
, or DOUBLE
. defaultType
can be set to SCALAR
, VEC2
, VEC3
, or VEC4
.
The software is available under the Apache V2.0 license.
Copyright © 2020 California Institute of Technology. ALL RIGHTS RESERVED. United States Government Sponsorship Acknowledged. Neither the name of Caltech nor its operating division, the Jet Propulsion Laboratory, nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission.