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import {
NoColorSpace,
DoubleSide,
} from 'three';
import {
strToU8,
zipSync,
} from '../libs/fflate.module.js';
import { decompress } from './../utils/TextureUtils.js';
class USDZExporter {
async parse( scene, options = {} ) {
options = Object.assign( {
ar: {
anchoring: { type: 'plane' },
planeAnchoring: { alignment: 'horizontal' }
},
quickLookCompatible: false,
maxTextureSize: 1024,
}, options );
const files = {};
const modelFileName = 'model.usda';
// model file should be first in USDZ archive so we init it here
files[ modelFileName ] = null;
let output = buildHeader();
output += buildSceneStart( options );
const materials = {};
const textures = {};
scene.traverseVisible( ( object ) => {
if ( object.isMesh ) {
const geometry = object.geometry;
const material = object.material;
if ( material.isMeshStandardMaterial ) {
const geometryFileName = 'geometries/Geometry_' + geometry.id + '.usda';
if ( ! ( geometryFileName in files ) ) {
const meshObject = buildMeshObject( geometry );
files[ geometryFileName ] = buildUSDFileAsString( meshObject );
}
if ( ! ( material.uuid in materials ) ) {
materials[ material.uuid ] = material;
}
output += buildXform( object, geometry, material );
} else {
console.warn( 'THREE.USDZExporter: Unsupported material type (USDZ only supports MeshStandardMaterial)', object );
}
} else if ( object.isCamera ) {
output += buildCamera( object );
}
} );
output += buildSceneEnd();
output += buildMaterials( materials, textures, options.quickLookCompatible );
files[ modelFileName ] = strToU8( output );
output = null;
for ( const id in textures ) {
let texture = textures[ id ];
if ( texture.isCompressedTexture === true ) {
texture = decompress( texture );
}
const canvas = imageToCanvas( texture.image, texture.flipY, options.maxTextureSize );
const blob = await new Promise( resolve => canvas.toBlob( resolve, 'image/png', 1 ) );
files[ `textures/Texture_${ id }.png` ] = new Uint8Array( await blob.arrayBuffer() );
}
// 64 byte alignment
// https://github.com/101arrowz/fflate/issues/39#issuecomment-777263109
let offset = 0;
for ( const filename in files ) {
const file = files[ filename ];
const headerSize = 34 + filename.length;
offset += headerSize;
const offsetMod64 = offset & 63;
if ( offsetMod64 !== 4 ) {
const padLength = 64 - offsetMod64;
const padding = new Uint8Array( padLength );
files[ filename ] = [ file, { extra: { 12345: padding } } ];
}
offset = file.length;
}
return zipSync( files, { level: 0 } );
}
}
function imageToCanvas( image, flipY, maxTextureSize ) {
if ( ( typeof HTMLImageElement !== 'undefined' && image instanceof HTMLImageElement ) ||
( typeof HTMLCanvasElement !== 'undefined' && image instanceof HTMLCanvasElement ) ||
( typeof OffscreenCanvas !== 'undefined' && image instanceof OffscreenCanvas ) ||
( typeof ImageBitmap !== 'undefined' && image instanceof ImageBitmap ) ) {
const scale = maxTextureSize / Math.max( image.width, image.height );
const canvas = document.createElement( 'canvas' );
canvas.width = image.width * Math.min( 1, scale );
canvas.height = image.height * Math.min( 1, scale );
const context = canvas.getContext( '2d' );
// TODO: We should be able to do this in the UsdTransform2d?
if ( flipY === true ) {
context.translate( 0, canvas.height );
context.scale( 1, - 1 );
}
context.drawImage( image, 0, 0, canvas.width, canvas.height );
return canvas;
} else {
throw new Error( 'THREE.USDZExporter: No valid image data found. Unable to process texture.' );
}
}
//
const PRECISION = 7;
function buildHeader() {
return `#usda 1.0
(
customLayerData = {
string creator = "Three.js USDZExporter"
}
defaultPrim = "Root"
metersPerUnit = 1
upAxis = "Y"
)
`;
}
function buildSceneStart( options ) {
return `def Xform "Root"
{
def Scope "Scenes" (
kind = "sceneLibrary"
)
{
def Xform "Scene" (
customData = {
bool preliminary_collidesWithEnvironment = 0
string sceneName = "Scene"
}
sceneName = "Scene"
)
{
token preliminary:anchoring:type = "${options.ar.anchoring.type}"
token preliminary:planeAnchoring:alignment = "${options.ar.planeAnchoring.alignment}"
`;
}
function buildSceneEnd() {
return `
}
}
}
`;
}
function buildUSDFileAsString( dataToInsert ) {
let output = buildHeader();
output += dataToInsert;
return strToU8( output );
}
// Xform
function buildXform( object, geometry, material ) {
const name = 'Object_' + object.id;
const transform = buildMatrix( object.matrixWorld );
if ( object.matrixWorld.determinant() < 0 ) {
console.warn( 'THREE.USDZExporter: USDZ does not support negative scales', object );
}
return `def Xform "${ name }" (
prepend references = @./geometries/Geometry_${ geometry.id }.usda@</Geometry>
prepend apiSchemas = ["MaterialBindingAPI"]
)
{
matrix4d xformOp:transform = ${ transform }
uniform token[] xformOpOrder = ["xformOp:transform"]
rel material:binding = </Materials/Material_${ material.id }>
}
`;
}
function buildMatrix( matrix ) {
const array = matrix.elements;
return `( ${ buildMatrixRow( array, 0 ) }, ${ buildMatrixRow( array, 4 ) }, ${ buildMatrixRow( array, 8 ) }, ${ buildMatrixRow( array, 12 ) } )`;
}
function buildMatrixRow( array, offset ) {
return `(${ array[ offset + 0 ] }, ${ array[ offset + 1 ] }, ${ array[ offset + 2 ] }, ${ array[ offset + 3 ] })`;
}
// Mesh
function buildMeshObject( geometry ) {
const mesh = buildMesh( geometry );
return `
def "Geometry"
{
${mesh}
}
`;
}
function buildMesh( geometry ) {
const name = 'Geometry';
const attributes = geometry.attributes;
const count = attributes.position.count;
return `
def Mesh "${ name }"
{
int[] faceVertexCounts = [${ buildMeshVertexCount( geometry ) }]
int[] faceVertexIndices = [${ buildMeshVertexIndices( geometry ) }]
normal3f[] normals = [${ buildVector3Array( attributes.normal, count )}] (
interpolation = "vertex"
)
point3f[] points = [${ buildVector3Array( attributes.position, count )}]
${ buildPrimvars( attributes ) }
uniform token subdivisionScheme = "none"
}
`;
}
function buildMeshVertexCount( geometry ) {
const count = geometry.index !== null ? geometry.index.count : geometry.attributes.position.count;
return Array( count / 3 ).fill( 3 ).join( ', ' );
}
function buildMeshVertexIndices( geometry ) {
const index = geometry.index;
const array = [];
if ( index !== null ) {
for ( let i = 0; i < index.count; i ++ ) {
array.push( index.getX( i ) );
}
} else {
const length = geometry.attributes.position.count;
for ( let i = 0; i < length; i ++ ) {
array.push( i );
}
}
return array.join( ', ' );
}
function buildVector3Array( attribute, count ) {
if ( attribute === undefined ) {
console.warn( 'USDZExporter: Normals missing.' );
return Array( count ).fill( '(0, 0, 0)' ).join( ', ' );
}
const array = [];
for ( let i = 0; i < attribute.count; i ++ ) {
const x = attribute.getX( i );
const y = attribute.getY( i );
const z = attribute.getZ( i );
array.push( `(${ x.toPrecision( PRECISION ) }, ${ y.toPrecision( PRECISION ) }, ${ z.toPrecision( PRECISION ) })` );
}
return array.join( ', ' );
}
function buildVector2Array( attribute ) {
const array = [];
for ( let i = 0; i < attribute.count; i ++ ) {
const x = attribute.getX( i );
const y = attribute.getY( i );
array.push( `(${ x.toPrecision( PRECISION ) }, ${ 1 - y.toPrecision( PRECISION ) })` );
}
return array.join( ', ' );
}
function buildPrimvars( attributes ) {
let string = '';
for ( let i = 0; i < 4; i ++ ) {
const id = ( i > 0 ? i : '' );
const attribute = attributes[ 'uv' + id ];
if ( attribute !== undefined ) {
string += `
texCoord2f[] primvars:st${ id } = [${ buildVector2Array( attribute )}] (
interpolation = "vertex"
)`;
}
}
// vertex colors
const colorAttribute = attributes.color;
if ( colorAttribute !== undefined ) {
const count = colorAttribute.count;
string += `
color3f[] primvars:displayColor = [${buildVector3Array( colorAttribute, count )}] (
interpolation = "vertex"
)`;
}
return string;
}
// Materials
function buildMaterials( materials, textures, quickLookCompatible = false ) {
const array = [];
for ( const uuid in materials ) {
const material = materials[ uuid ];
array.push( buildMaterial( material, textures, quickLookCompatible ) );
}
return `def "Materials"
{
${ array.join( '' ) }
}
`;
}
function buildMaterial( material, textures, quickLookCompatible = false ) {
// https://graphics.pixar.com/usd/docs/UsdPreviewSurface-Proposal.html
const pad = ' ';
const inputs = [];
const samplers = [];
function buildTexture( texture, mapType, color ) {
const id = texture.source.id + '_' + texture.flipY;
textures[ id ] = texture;
const uv = texture.channel > 0 ? 'st' + texture.channel : 'st';
const WRAPPINGS = {
1000: 'repeat', // RepeatWrapping
1001: 'clamp', // ClampToEdgeWrapping
1002: 'mirror' // MirroredRepeatWrapping
};
const repeat = texture.repeat.clone();
const offset = texture.offset.clone();
const rotation = texture.rotation;
// rotation is around the wrong point. after rotation we need to shift offset again so that we're rotating around the right spot
const xRotationOffset = Math.sin( rotation );
const yRotationOffset = Math.cos( rotation );
// texture coordinates start in the opposite corner, need to correct
offset.y = 1 - offset.y - repeat.y;
// turns out QuickLook is buggy and interprets texture repeat inverted/applies operations in a different order.
// Apple Feedback: FB10036297 and FB11442287
if ( quickLookCompatible ) {
// This is NOT correct yet in QuickLook, but comes close for a range of models.
// It becomes more incorrect the bigger the offset is
offset.x = offset.x / repeat.x;
offset.y = offset.y / repeat.y;
offset.x += xRotationOffset / repeat.x;
offset.y += yRotationOffset - 1;
} else {
// results match glTF results exactly. verified correct in usdview.
offset.x += xRotationOffset * repeat.x;
offset.y += ( 1 - yRotationOffset ) * repeat.y;
}
return `
def Shader "PrimvarReader_${ mapType }"
{
uniform token info:id = "UsdPrimvarReader_float2"
float2 inputs:fallback = (0.0, 0.0)
token inputs:varname = "${ uv }"
float2 outputs:result
}
def Shader "Transform2d_${ mapType }"
{
uniform token info:id = "UsdTransform2d"
token inputs:in.connect = </Materials/Material_${ material.id }/PrimvarReader_${ mapType }.outputs:result>
float inputs:rotation = ${ ( rotation * ( 180 / Math.PI ) ).toFixed( PRECISION ) }
float2 inputs:scale = ${ buildVector2( repeat ) }
float2 inputs:translation = ${ buildVector2( offset ) }
float2 outputs:result
}
def Shader "Texture_${ texture.id }_${ mapType }"
{
uniform token info:id = "UsdUVTexture"
asset inputs:file = @textures/Texture_${ id }.png@
float2 inputs:st.connect = </Materials/Material_${ material.id }/Transform2d_${ mapType }.outputs:result>
${ color !== undefined ? 'float4 inputs:scale = ' + buildColor4( color ) : '' }
token inputs:sourceColorSpace = "${ texture.colorSpace === NoColorSpace ? 'raw' : 'sRGB' }"
token inputs:wrapS = "${ WRAPPINGS[ texture.wrapS ] }"
token inputs:wrapT = "${ WRAPPINGS[ texture.wrapT ] }"
float outputs:r
float outputs:g
float outputs:b
float3 outputs:rgb
${ material.transparent || material.alphaTest > 0.0 ? 'float outputs:a' : '' }
}`;
}
if ( material.side === DoubleSide ) {
console.warn( 'THREE.USDZExporter: USDZ does not support double sided materials', material );
}
if ( material.map !== null ) {
inputs.push( `${ pad }color3f inputs:diffuseColor.connect = </Materials/Material_${ material.id }/Texture_${ material.map.id }_diffuse.outputs:rgb>` );
if ( material.transparent ) {
inputs.push( `${ pad }float inputs:opacity.connect = </Materials/Material_${ material.id }/Texture_${ material.map.id }_diffuse.outputs:a>` );
} else if ( material.alphaTest > 0.0 ) {
inputs.push( `${ pad }float inputs:opacity.connect = </Materials/Material_${ material.id }/Texture_${ material.map.id }_diffuse.outputs:a>` );
inputs.push( `${ pad }float inputs:opacityThreshold = ${material.alphaTest}` );
}
samplers.push( buildTexture( material.map, 'diffuse', material.color ) );
} else {
inputs.push( `${ pad }color3f inputs:diffuseColor = ${ buildColor( material.color ) }` );
}
if ( material.emissiveMap !== null ) {
inputs.push( `${ pad }color3f inputs:emissiveColor.connect = </Materials/Material_${ material.id }/Texture_${ material.emissiveMap.id }_emissive.outputs:rgb>` );
samplers.push( buildTexture( material.emissiveMap, 'emissive' ) );
} else if ( material.emissive.getHex() > 0 ) {
inputs.push( `${ pad }color3f inputs:emissiveColor = ${ buildColor( material.emissive ) }` );
}
if ( material.normalMap !== null ) {
inputs.push( `${ pad }normal3f inputs:normal.connect = </Materials/Material_${ material.id }/Texture_${ material.normalMap.id }_normal.outputs:rgb>` );
samplers.push( buildTexture( material.normalMap, 'normal' ) );
}
if ( material.aoMap !== null ) {
inputs.push( `${ pad }float inputs:occlusion.connect = </Materials/Material_${ material.id }/Texture_${ material.aoMap.id }_occlusion.outputs:r>` );
samplers.push( buildTexture( material.aoMap, 'occlusion' ) );
}
if ( material.roughnessMap !== null && material.roughness === 1 ) {
inputs.push( `${ pad }float inputs:roughness.connect = </Materials/Material_${ material.id }/Texture_${ material.roughnessMap.id }_roughness.outputs:g>` );
samplers.push( buildTexture( material.roughnessMap, 'roughness' ) );
} else {
inputs.push( `${ pad }float inputs:roughness = ${ material.roughness }` );
}
if ( material.metalnessMap !== null && material.metalness === 1 ) {
inputs.push( `${ pad }float inputs:metallic.connect = </Materials/Material_${ material.id }/Texture_${ material.metalnessMap.id }_metallic.outputs:b>` );
samplers.push( buildTexture( material.metalnessMap, 'metallic' ) );
} else {
inputs.push( `${ pad }float inputs:metallic = ${ material.metalness }` );
}
if ( material.alphaMap !== null ) {
inputs.push( `${pad}float inputs:opacity.connect = </Materials/Material_${material.id}/Texture_${material.alphaMap.id}_opacity.outputs:r>` );
inputs.push( `${pad}float inputs:opacityThreshold = 0.0001` );
samplers.push( buildTexture( material.alphaMap, 'opacity' ) );
} else {
inputs.push( `${pad}float inputs:opacity = ${material.opacity}` );
}
if ( material.isMeshPhysicalMaterial ) {
inputs.push( `${ pad }float inputs:clearcoat = ${ material.clearcoat }` );
inputs.push( `${ pad }float inputs:clearcoatRoughness = ${ material.clearcoatRoughness }` );
inputs.push( `${ pad }float inputs:ior = ${ material.ior }` );
}
return `
def Material "Material_${ material.id }"
{
def Shader "PreviewSurface"
{
uniform token info:id = "UsdPreviewSurface"
${ inputs.join( '\n' ) }
int inputs:useSpecularWorkflow = 0
token outputs:surface
}
token outputs:surface.connect = </Materials/Material_${ material.id }/PreviewSurface.outputs:surface>
${ samplers.join( '\n' ) }
}
`;
}
function buildColor( color ) {
return `(${ color.r }, ${ color.g }, ${ color.b })`;
}
function buildColor4( color ) {
return `(${ color.r }, ${ color.g }, ${ color.b }, 1.0)`;
}
function buildVector2( vector ) {
return `(${ vector.x }, ${ vector.y })`;
}
function buildCamera( camera ) {
const name = camera.name ? camera.name : 'Camera_' + camera.id;
const transform = buildMatrix( camera.matrixWorld );
if ( camera.matrixWorld.determinant() < 0 ) {
console.warn( 'THREE.USDZExporter: USDZ does not support negative scales', camera );
}
if ( camera.isOrthographicCamera ) {
return `def Camera "${name}"
{
matrix4d xformOp:transform = ${ transform }
uniform token[] xformOpOrder = ["xformOp:transform"]
float2 clippingRange = (${ camera.near.toPrecision( PRECISION ) }, ${ camera.far.toPrecision( PRECISION ) })
float horizontalAperture = ${ ( ( Math.abs( camera.left ) + Math.abs( camera.right ) ) * 10 ).toPrecision( PRECISION ) }
float verticalAperture = ${ ( ( Math.abs( camera.top ) + Math.abs( camera.bottom ) ) * 10 ).toPrecision( PRECISION ) }
token projection = "orthographic"
}
`;
} else {
return `def Camera "${name}"
{
matrix4d xformOp:transform = ${ transform }
uniform token[] xformOpOrder = ["xformOp:transform"]
float2 clippingRange = (${ camera.near.toPrecision( PRECISION ) }, ${ camera.far.toPrecision( PRECISION ) })
float focalLength = ${ camera.getFocalLength().toPrecision( PRECISION ) }
float focusDistance = ${ camera.focus.toPrecision( PRECISION ) }
float horizontalAperture = ${ camera.getFilmWidth().toPrecision( PRECISION ) }
token projection = "perspective"
float verticalAperture = ${ camera.getFilmHeight().toPrecision( PRECISION ) }
}
`;
}
}
export { USDZExporter };