three#FrontSide JavaScript Examples
The following examples show how to use
three#FrontSide.
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Example #1
Source File: Map.js From BlueMapWeb with MIT License | 6 votes |
/**
* Creates a lowres Material
* @param vertexShader {string}
* @param fragmentShader {string}
* @param uniforms {object}
* @returns {ShaderMaterial} the hires Material
*/
createLowresMaterial(vertexShader, fragmentShader, uniforms) {
return new ShaderMaterial({
uniforms: uniforms,
vertexShader: vertexShader,
fragmentShader: fragmentShader,
transparent: false,
depthWrite: true,
depthTest: true,
vertexColors: VertexColors,
side: FrontSide,
wireframe: false
});
}
Example #2
Source File: floor.js From architect3d with MIT License | 6 votes |
buildRoofVaryingHeight()
{
// setup texture
var roofMaterial = new MeshBasicMaterial({side: FrontSide,color: 0xe5e5e5});
var geometry = new Geometry();
this.room.corners.forEach((corner) => {
var vertex = new Vector3(corner.x,corner.elevation, corner.y);
geometry.vertices.push(vertex);
});
for (var i=2;i<geometry.vertices.length;i++)
{
var face = new Face3(0, i-1, i);
geometry.faces.push(face);
}
var roof = new Mesh(geometry, roofMaterial);
// roof.rotation.set(Math.PI / 2, 0, 0);
// roof.position.y = Configuration.getNumericValue(configWallHeight);
return roof;
}
Example #3
Source File: floor.js From architect3d with MIT License | 6 votes |
buildRoofUniformHeight()
{
// setup texture
var roofMaterial = new MeshBasicMaterial({side: FrontSide,color: 0xe5e5e5});
var points = [];
this.room.interiorCorners.forEach((corner) => {
points.push(new Vector2(corner.x,corner.y));
});
var shape = new Shape(points);
var geometry = new ShapeGeometry(shape);
var roof = new Mesh(geometry, roofMaterial);
roof.rotation.set(Math.PI / 2, 0, 0);
roof.position.y = Configuration.getNumericValue(configWallHeight);
return roof;
}
Example #4
Source File: Map.js From BlueMapWeb with MIT License | 5 votes |
/**
* Creates a hires Material with the given textures
* @param vertexShader {string}
* @param fragmentShader {string}
* @param uniforms {object}
* @param textures {{
* resourcePath: string,
* color: number[],
* halfTransparent: boolean,
* texture: string
* }[]} the textures-data
* @returns {ShaderMaterial[]} the hires Material (array because its a multi-material)
*/
createHiresMaterial(vertexShader, fragmentShader, uniforms, textures) {
let materials = [];
if (!Array.isArray(textures)) throw new Error("Invalid texture.json: 'textures' is not an array!")
for (let i = 0; i < textures.length; i++) {
let textureSettings = textures[i];
let color = textureSettings.color;
if (!Array.isArray(color) || color.length < 4){
color = [0, 0, 0, 0];
}
let opaque = color[3] === 1;
let transparent = !!textureSettings.halfTransparent;
let texture = new Texture();
texture.image = stringToImage(textureSettings.texture);
texture.anisotropy = 1;
texture.generateMipmaps = opaque || transparent;
texture.magFilter = NearestFilter;
texture.minFilter = texture.generateMipmaps ? NearestMipMapLinearFilter : NearestFilter;
texture.wrapS = ClampToEdgeWrapping;
texture.wrapT = ClampToEdgeWrapping;
texture.flipY = false;
texture.flatShading = true;
texture.image.addEventListener("load", () => texture.needsUpdate = true);
this.loadedTextures.push(texture);
let material = new ShaderMaterial({
uniforms: {
...uniforms,
textureImage: {
type: 't',
value: texture
},
transparent: { value: transparent }
},
vertexShader: vertexShader,
fragmentShader: fragmentShader,
transparent: transparent,
depthWrite: true,
depthTest: true,
vertexColors: VertexColors,
side: FrontSide,
wireframe: false,
});
material.needsUpdate = true;
materials[i] = material;
}
return materials;
}
Example #5
Source File: edge.js From architect3d with MIT License | 5 votes |
updatePlanes()
{
// var extStartCorner = this.wall.getClosestCorner(this.edge.exteriorStart());
// var extEndCorner = this.wall.getClosestCorner(this.edge.exteriorEnd());
var extStartCorner = this.edge.getStart();
var extEndCorner = this.edge.getEnd();
if(extStartCorner == null || extEndCorner == null)
{
return;
}
var color = 0xFFFFFF;
var wallMaterial = new MeshBasicMaterial({
color: color,
side: FrontSide,
map: this.texture,
transparent: true,
lightMap: this.lightMap,
opacity: 1.0,
wireframe: false,
});
var fillerMaterial = new MeshBasicMaterial({
color: this.fillerColor,
side: DoubleSide,
map: this.texture,
transparent: true,
opacity: 1.0,
wireframe: false,
});
// exterior plane for real exterior walls
//If the walls have corners that have more than one room attached
//Then there is no need to construct an exterior wall
if(this.edge.wall.start.getAttachedRooms().length < 2 || this.edge.wall.end.getAttachedRooms().length < 2)
{
this.planes.push(this.makeWall(this.edge.exteriorStart(), this.edge.exteriorEnd(), this.edge.exteriorTransform, this.edge.invExteriorTransform, fillerMaterial));
}
// interior plane
this.planes.push(this.makeWall(this.edge.interiorStart(), this.edge.interiorEnd(), this.edge.interiorTransform, this.edge.invInteriorTransform, wallMaterial));
// bottom
// put into basePlanes since this is always visible
this.basePlanes.push(this.buildFillerUniformHeight(this.edge, 0, BackSide, this.baseColor));
if(this.edge.wall.start.getAttachedRooms().length < 2 || this.edge.wall.end.getAttachedRooms().length < 2)
{
this.planes.push(this.buildFillerVaryingHeights(this.edge, DoubleSide, this.fillerColor));
}
// sides
this.planes.push(this.buildSideFillter(this.edge.interiorStart(), this.edge.exteriorStart(), extStartCorner.elevation, this.sideColor));
this.planes.push(this.buildSideFillter(this.edge.interiorEnd(), this.edge.exteriorEnd(), extEndCorner.elevation, this.sideColor));
// this.planes.push(this.buildSideFillter(this.edge.interiorStart(), this.edge.exteriorStart(), this.wall.startElevation, this.sideColor));
// this.planes.push(this.buildSideFillter(this.edge.interiorEnd(), this.edge.exteriorEnd(), extEndCorner.endElevation, this.sideColor));
}
Example #6
Source File: GLTFLoader.js From canvas with Apache License 2.0 | 4 votes |
GLTFLoader = ( function () {
function GLTFLoader( manager ) {
Loader.call( this, manager );
this.dracoLoader = null;
this.ddsLoader = null;
}
GLTFLoader.prototype = Object.assign( Object.create( Loader.prototype ), {
constructor: GLTFLoader,
load: function ( url, onLoad, onProgress, onError ) {
var scope = this;
var resourcePath;
if ( this.resourcePath !== '' ) {
resourcePath = this.resourcePath;
} else if ( this.path !== '' ) {
resourcePath = this.path;
} else {
resourcePath = LoaderUtils.extractUrlBase( url );
}
// Tells the LoadingManager to track an extra item, which resolves after
// the model is fully loaded. This means the count of items loaded will
// be incorrect, but ensures manager.onLoad() does not fire early.
scope.manager.itemStart( url );
var _onError = function ( e ) {
if ( onError ) {
onError( e );
} else {
console.error( e );
}
scope.manager.itemError( url );
scope.manager.itemEnd( url );
};
var loader = new FileLoader( scope.manager );
loader.setPath( this.path );
loader.setResponseType( 'arraybuffer' );
if ( scope.crossOrigin === 'use-credentials' ) {
loader.setWithCredentials( true );
}
loader.load( url, function ( data ) {
try {
scope.parse( data, resourcePath, function ( gltf ) {
onLoad( gltf );
scope.manager.itemEnd( url );
}, _onError );
} catch ( e ) {
_onError( e );
}
}, onProgress, _onError );
},
setDRACOLoader: function ( dracoLoader ) {
this.dracoLoader = dracoLoader;
return this;
},
setDDSLoader: function ( ddsLoader ) {
this.ddsLoader = ddsLoader;
return this;
},
parse: function ( data, path, onLoad, onError ) {
var content;
var extensions = {};
if ( typeof data === 'string' ) {
content = data;
} else {
var magic = LoaderUtils.decodeText( new Uint8Array( data, 0, 4 ) );
if ( magic === BINARY_EXTENSION_HEADER_MAGIC ) {
try {
extensions[ EXTENSIONS.KHR_BINARY_GLTF ] = new GLTFBinaryExtension( data );
} catch ( error ) {
if ( onError ) onError( error );
return;
}
content = extensions[ EXTENSIONS.KHR_BINARY_GLTF ].content;
} else {
content = LoaderUtils.decodeText( new Uint8Array( data ) );
}
}
var json = JSON.parse( content );
if ( json.asset === undefined || json.asset.version[ 0 ] < 2 ) {
if ( onError ) onError( new Error( 'THREE.GLTFLoader: Unsupported asset. glTF versions >=2.0 are supported.' ) );
return;
}
if ( json.extensionsUsed ) {
for ( var i = 0; i < json.extensionsUsed.length; ++ i ) {
var extensionName = json.extensionsUsed[ i ];
var extensionsRequired = json.extensionsRequired || [];
switch ( extensionName ) {
case EXTENSIONS.KHR_LIGHTS_PUNCTUAL:
extensions[ extensionName ] = new GLTFLightsExtension( json );
break;
case EXTENSIONS.KHR_MATERIALS_CLEARCOAT:
extensions[ extensionName ] = new GLTFMaterialsClearcoatExtension();
break;
case EXTENSIONS.KHR_MATERIALS_UNLIT:
extensions[ extensionName ] = new GLTFMaterialsUnlitExtension();
break;
case EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS:
extensions[ extensionName ] = new GLTFMaterialsPbrSpecularGlossinessExtension();
break;
case EXTENSIONS.KHR_DRACO_MESH_COMPRESSION:
extensions[ extensionName ] = new GLTFDracoMeshCompressionExtension( json, this.dracoLoader );
break;
case EXTENSIONS.MSFT_TEXTURE_DDS:
extensions[ extensionName ] = new GLTFTextureDDSExtension( this.ddsLoader );
break;
case EXTENSIONS.KHR_TEXTURE_TRANSFORM:
extensions[ extensionName ] = new GLTFTextureTransformExtension();
break;
case EXTENSIONS.KHR_MESH_QUANTIZATION:
extensions[ extensionName ] = new GLTFMeshQuantizationExtension();
break;
default:
if ( extensionsRequired.indexOf( extensionName ) >= 0 ) {
console.warn( 'THREE.GLTFLoader: Unknown extension "' + extensionName + '".' );
}
}
}
}
var parser = new GLTFParser( json, extensions, {
path: path || this.resourcePath || '',
crossOrigin: this.crossOrigin,
manager: this.manager
} );
parser.parse( onLoad, onError );
}
} );
/* GLTFREGISTRY */
function GLTFRegistry() {
var objects = {};
return {
get: function ( key ) {
return objects[ key ];
},
add: function ( key, object ) {
objects[ key ] = object;
},
remove: function ( key ) {
delete objects[ key ];
},
removeAll: function () {
objects = {};
}
};
}
/*********************************/
/********** EXTENSIONS ***********/
/*********************************/
var EXTENSIONS = {
KHR_BINARY_GLTF: 'KHR_binary_glTF',
KHR_DRACO_MESH_COMPRESSION: 'KHR_draco_mesh_compression',
KHR_LIGHTS_PUNCTUAL: 'KHR_lights_punctual',
KHR_MATERIALS_CLEARCOAT: 'KHR_materials_clearcoat',
KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS: 'KHR_materials_pbrSpecularGlossiness',
KHR_MATERIALS_UNLIT: 'KHR_materials_unlit',
KHR_TEXTURE_TRANSFORM: 'KHR_texture_transform',
KHR_MESH_QUANTIZATION: 'KHR_mesh_quantization',
MSFT_TEXTURE_DDS: 'MSFT_texture_dds'
};
/**
* DDS Texture Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Vendor/MSFT_texture_dds
*
*/
function GLTFTextureDDSExtension( ddsLoader ) {
if ( ! ddsLoader ) {
throw new Error( 'THREE.GLTFLoader: Attempting to load .dds texture without importing DDSLoader' );
}
this.name = EXTENSIONS.MSFT_TEXTURE_DDS;
this.ddsLoader = ddsLoader;
}
/**
* Punctual Lights Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_lights_punctual
*/
function GLTFLightsExtension( json ) {
this.name = EXTENSIONS.KHR_LIGHTS_PUNCTUAL;
var extension = ( json.extensions && json.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ] ) || {};
this.lightDefs = extension.lights || [];
}
GLTFLightsExtension.prototype.loadLight = function ( lightIndex ) {
var lightDef = this.lightDefs[ lightIndex ];
var lightNode;
var color = new Color( 0xffffff );
if ( lightDef.color !== undefined ) color.fromArray( lightDef.color );
var range = lightDef.range !== undefined ? lightDef.range : 0;
switch ( lightDef.type ) {
case 'directional':
lightNode = new DirectionalLight( color );
lightNode.target.position.set( 0, 0, - 1 );
lightNode.add( lightNode.target );
break;
case 'point':
lightNode = new PointLight( color );
lightNode.distance = range;
break;
case 'spot':
lightNode = new SpotLight( color );
lightNode.distance = range;
// Handle spotlight properties.
lightDef.spot = lightDef.spot || {};
lightDef.spot.innerConeAngle = lightDef.spot.innerConeAngle !== undefined ? lightDef.spot.innerConeAngle : 0;
lightDef.spot.outerConeAngle = lightDef.spot.outerConeAngle !== undefined ? lightDef.spot.outerConeAngle : Math.PI / 4.0;
lightNode.angle = lightDef.spot.outerConeAngle;
lightNode.penumbra = 1.0 - lightDef.spot.innerConeAngle / lightDef.spot.outerConeAngle;
lightNode.target.position.set( 0, 0, - 1 );
lightNode.add( lightNode.target );
break;
default:
throw new Error( 'THREE.GLTFLoader: Unexpected light type, "' + lightDef.type + '".' );
}
// Some lights (e.g. spot) default to a position other than the origin. Reset the position
// here, because node-level parsing will only override position if explicitly specified.
lightNode.position.set( 0, 0, 0 );
lightNode.decay = 2;
if ( lightDef.intensity !== undefined ) lightNode.intensity = lightDef.intensity;
lightNode.name = lightDef.name || ( 'light_' + lightIndex );
return Promise.resolve( lightNode );
};
/**
* Unlit Materials Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_materials_unlit
*/
function GLTFMaterialsUnlitExtension() {
this.name = EXTENSIONS.KHR_MATERIALS_UNLIT;
}
GLTFMaterialsUnlitExtension.prototype.getMaterialType = function () {
return MeshBasicMaterial;
};
GLTFMaterialsUnlitExtension.prototype.extendParams = function ( materialParams, materialDef, parser ) {
var pending = [];
materialParams.color = new Color( 1.0, 1.0, 1.0 );
materialParams.opacity = 1.0;
var metallicRoughness = materialDef.pbrMetallicRoughness;
if ( metallicRoughness ) {
if ( Array.isArray( metallicRoughness.baseColorFactor ) ) {
var array = metallicRoughness.baseColorFactor;
materialParams.color.fromArray( array );
materialParams.opacity = array[ 3 ];
}
if ( metallicRoughness.baseColorTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'map', metallicRoughness.baseColorTexture ) );
}
}
return Promise.all( pending );
};
/**
* Clearcoat Materials Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_materials_clearcoat
*/
function GLTFMaterialsClearcoatExtension() {
this.name = EXTENSIONS.KHR_MATERIALS_CLEARCOAT;
}
GLTFMaterialsClearcoatExtension.prototype.getMaterialType = function () {
return MeshPhysicalMaterial;
};
GLTFMaterialsClearcoatExtension.prototype.extendParams = function ( materialParams, materialDef, parser ) {
var pending = [];
var extension = materialDef.extensions[ this.name ];
if ( extension.clearcoatFactor !== undefined ) {
materialParams.clearcoat = extension.clearcoatFactor;
}
if ( extension.clearcoatTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'clearcoatMap', extension.clearcoatTexture ) );
}
if ( extension.clearcoatRoughnessFactor !== undefined ) {
materialParams.clearcoatRoughness = extension.clearcoatRoughnessFactor;
}
if ( extension.clearcoatRoughnessTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'clearcoatRoughnessMap', extension.clearcoatRoughnessTexture ) );
}
if ( extension.clearcoatNormalTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'clearcoatNormalMap', extension.clearcoatNormalTexture ) );
if ( extension.clearcoatNormalTexture.scale !== undefined ) {
var scale = extension.clearcoatNormalTexture.scale;
materialParams.clearcoatNormalScale = new Vector2( scale, scale );
}
}
return Promise.all( pending );
};
/* BINARY EXTENSION */
var BINARY_EXTENSION_HEADER_MAGIC = 'glTF';
var BINARY_EXTENSION_HEADER_LENGTH = 12;
var BINARY_EXTENSION_CHUNK_TYPES = { JSON: 0x4E4F534A, BIN: 0x004E4942 };
function GLTFBinaryExtension( data ) {
this.name = EXTENSIONS.KHR_BINARY_GLTF;
this.content = null;
this.body = null;
var headerView = new DataView( data, 0, BINARY_EXTENSION_HEADER_LENGTH );
this.header = {
magic: LoaderUtils.decodeText( new Uint8Array( data.slice( 0, 4 ) ) ),
version: headerView.getUint32( 4, true ),
length: headerView.getUint32( 8, true )
};
if ( this.header.magic !== BINARY_EXTENSION_HEADER_MAGIC ) {
throw new Error( 'THREE.GLTFLoader: Unsupported glTF-Binary header.' );
} else if ( this.header.version < 2.0 ) {
throw new Error( 'THREE.GLTFLoader: Legacy binary file detected.' );
}
var chunkView = new DataView( data, BINARY_EXTENSION_HEADER_LENGTH );
var chunkIndex = 0;
while ( chunkIndex < chunkView.byteLength ) {
var chunkLength = chunkView.getUint32( chunkIndex, true );
chunkIndex += 4;
var chunkType = chunkView.getUint32( chunkIndex, true );
chunkIndex += 4;
if ( chunkType === BINARY_EXTENSION_CHUNK_TYPES.JSON ) {
var contentArray = new Uint8Array( data, BINARY_EXTENSION_HEADER_LENGTH + chunkIndex, chunkLength );
this.content = LoaderUtils.decodeText( contentArray );
} else if ( chunkType === BINARY_EXTENSION_CHUNK_TYPES.BIN ) {
var byteOffset = BINARY_EXTENSION_HEADER_LENGTH + chunkIndex;
this.body = data.slice( byteOffset, byteOffset + chunkLength );
}
// Clients must ignore chunks with unknown types.
chunkIndex += chunkLength;
}
if ( this.content === null ) {
throw new Error( 'THREE.GLTFLoader: JSON content not found.' );
}
}
/**
* DRACO Mesh Compression Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_draco_mesh_compression
*/
function GLTFDracoMeshCompressionExtension( json, dracoLoader ) {
if ( ! dracoLoader ) {
throw new Error( 'THREE.GLTFLoader: No DRACOLoader instance provided.' );
}
this.name = EXTENSIONS.KHR_DRACO_MESH_COMPRESSION;
this.json = json;
this.dracoLoader = dracoLoader;
this.dracoLoader.preload();
}
GLTFDracoMeshCompressionExtension.prototype.decodePrimitive = function ( primitive, parser ) {
var json = this.json;
var dracoLoader = this.dracoLoader;
var bufferViewIndex = primitive.extensions[ this.name ].bufferView;
var gltfAttributeMap = primitive.extensions[ this.name ].attributes;
var threeAttributeMap = {};
var attributeNormalizedMap = {};
var attributeTypeMap = {};
for ( var attributeName in gltfAttributeMap ) {
var threeAttributeName = ATTRIBUTES[ attributeName ] || attributeName.toLowerCase();
threeAttributeMap[ threeAttributeName ] = gltfAttributeMap[ attributeName ];
}
for ( attributeName in primitive.attributes ) {
var threeAttributeName = ATTRIBUTES[ attributeName ] || attributeName.toLowerCase();
if ( gltfAttributeMap[ attributeName ] !== undefined ) {
var accessorDef = json.accessors[ primitive.attributes[ attributeName ] ];
var componentType = WEBGL_COMPONENT_TYPES[ accessorDef.componentType ];
attributeTypeMap[ threeAttributeName ] = componentType;
attributeNormalizedMap[ threeAttributeName ] = accessorDef.normalized === true;
}
}
return parser.getDependency( 'bufferView', bufferViewIndex ).then( function ( bufferView ) {
return new Promise( function ( resolve ) {
dracoLoader.decodeDracoFile( bufferView, function ( geometry ) {
for ( var attributeName in geometry.attributes ) {
var attribute = geometry.attributes[ attributeName ];
var normalized = attributeNormalizedMap[ attributeName ];
if ( normalized !== undefined ) attribute.normalized = normalized;
}
resolve( geometry );
}, threeAttributeMap, attributeTypeMap );
} );
} );
};
/**
* Texture Transform Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_texture_transform
*/
function GLTFTextureTransformExtension() {
this.name = EXTENSIONS.KHR_TEXTURE_TRANSFORM;
}
GLTFTextureTransformExtension.prototype.extendTexture = function ( texture, transform ) {
texture = texture.clone();
if ( transform.offset !== undefined ) {
texture.offset.fromArray( transform.offset );
}
if ( transform.rotation !== undefined ) {
texture.rotation = transform.rotation;
}
if ( transform.scale !== undefined ) {
texture.repeat.fromArray( transform.scale );
}
if ( transform.texCoord !== undefined ) {
console.warn( 'THREE.GLTFLoader: Custom UV sets in "' + this.name + '" extension not yet supported.' );
}
texture.needsUpdate = true;
return texture;
};
/**
* Specular-Glossiness Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_materials_pbrSpecularGlossiness
*/
/**
* A sub class of StandardMaterial with some of the functionality
* changed via the `onBeforeCompile` callback
* @pailhead
*/
function GLTFMeshStandardSGMaterial( params ) {
MeshStandardMaterial.call( this );
this.isGLTFSpecularGlossinessMaterial = true;
//various chunks that need replacing
var specularMapParsFragmentChunk = [
'#ifdef USE_SPECULARMAP',
' uniform sampler2D specularMap;',
'#endif'
].join( '\n' );
var glossinessMapParsFragmentChunk = [
'#ifdef USE_GLOSSINESSMAP',
' uniform sampler2D glossinessMap;',
'#endif'
].join( '\n' );
var specularMapFragmentChunk = [
'vec3 specularFactor = specular;',
'#ifdef USE_SPECULARMAP',
' vec4 texelSpecular = texture2D( specularMap, vUv );',
' texelSpecular = sRGBToLinear( texelSpecular );',
' // reads channel RGB, compatible with a glTF Specular-Glossiness (RGBA) texture',
' specularFactor *= texelSpecular.rgb;',
'#endif'
].join( '\n' );
var glossinessMapFragmentChunk = [
'float glossinessFactor = glossiness;',
'#ifdef USE_GLOSSINESSMAP',
' vec4 texelGlossiness = texture2D( glossinessMap, vUv );',
' // reads channel A, compatible with a glTF Specular-Glossiness (RGBA) texture',
' glossinessFactor *= texelGlossiness.a;',
'#endif'
].join( '\n' );
var lightPhysicalFragmentChunk = [
'PhysicalMaterial material;',
'material.diffuseColor = diffuseColor.rgb;',
'vec3 dxy = max( abs( dFdx( geometryNormal ) ), abs( dFdy( geometryNormal ) ) );',
'float geometryRoughness = max( max( dxy.x, dxy.y ), dxy.z );',
'material.specularRoughness = max( 1.0 - glossinessFactor, 0.0525 );// 0.0525 corresponds to the base mip of a 256 cubemap.',
'material.specularRoughness += geometryRoughness;',
'material.specularRoughness = min( material.specularRoughness, 1.0 );',
'material.specularColor = specularFactor.rgb;',
].join( '\n' );
var uniforms = {
specular: { value: new Color().setHex( 0xffffff ) },
glossiness: { value: 1 },
specularMap: { value: null },
glossinessMap: { value: null }
};
this._extraUniforms = uniforms;
// please see #14031 or #13198 for an alternate approach
this.onBeforeCompile = function ( shader ) {
for ( var uniformName in uniforms ) {
shader.uniforms[ uniformName ] = uniforms[ uniformName ];
}
shader.fragmentShader = shader.fragmentShader.replace( 'uniform float roughness;', 'uniform vec3 specular;' );
shader.fragmentShader = shader.fragmentShader.replace( 'uniform float metalness;', 'uniform float glossiness;' );
shader.fragmentShader = shader.fragmentShader.replace( '#include <roughnessmap_pars_fragment>', specularMapParsFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <metalnessmap_pars_fragment>', glossinessMapParsFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <roughnessmap_fragment>', specularMapFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <metalnessmap_fragment>', glossinessMapFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <lights_physical_fragment>', lightPhysicalFragmentChunk );
};
/*eslint-disable*/
Object.defineProperties(
this,
{
specular: {
get: function () { return uniforms.specular.value; },
set: function ( v ) { uniforms.specular.value = v; }
},
specularMap: {
get: function () { return uniforms.specularMap.value; },
set: function ( v ) { uniforms.specularMap.value = v; }
},
glossiness: {
get: function () { return uniforms.glossiness.value; },
set: function ( v ) { uniforms.glossiness.value = v; }
},
glossinessMap: {
get: function () { return uniforms.glossinessMap.value; },
set: function ( v ) {
uniforms.glossinessMap.value = v;
//how about something like this - @pailhead
if ( v ) {
this.defines.USE_GLOSSINESSMAP = '';
// set USE_ROUGHNESSMAP to enable vUv
this.defines.USE_ROUGHNESSMAP = '';
} else {
delete this.defines.USE_ROUGHNESSMAP;
delete this.defines.USE_GLOSSINESSMAP;
}
}
}
}
);
/*eslint-enable*/
delete this.metalness;
delete this.roughness;
delete this.metalnessMap;
delete this.roughnessMap;
this.setValues( params );
}
GLTFMeshStandardSGMaterial.prototype = Object.create( MeshStandardMaterial.prototype );
GLTFMeshStandardSGMaterial.prototype.constructor = GLTFMeshStandardSGMaterial;
GLTFMeshStandardSGMaterial.prototype.copy = function ( source ) {
MeshStandardMaterial.prototype.copy.call( this, source );
this.specularMap = source.specularMap;
this.specular.copy( source.specular );
this.glossinessMap = source.glossinessMap;
this.glossiness = source.glossiness;
delete this.metalness;
delete this.roughness;
delete this.metalnessMap;
delete this.roughnessMap;
return this;
};
function GLTFMaterialsPbrSpecularGlossinessExtension() {
return {
name: EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS,
specularGlossinessParams: [
'color',
'map',
'lightMap',
'lightMapIntensity',
'aoMap',
'aoMapIntensity',
'emissive',
'emissiveIntensity',
'emissiveMap',
'bumpMap',
'bumpScale',
'normalMap',
'normalMapType',
'displacementMap',
'displacementScale',
'displacementBias',
'specularMap',
'specular',
'glossinessMap',
'glossiness',
'alphaMap',
'envMap',
'envMapIntensity',
'refractionRatio',
],
getMaterialType: function () {
return GLTFMeshStandardSGMaterial;
},
extendParams: function ( materialParams, materialDef, parser ) {
var pbrSpecularGlossiness = materialDef.extensions[ this.name ];
materialParams.color = new Color( 1.0, 1.0, 1.0 );
materialParams.opacity = 1.0;
var pending = [];
if ( Array.isArray( pbrSpecularGlossiness.diffuseFactor ) ) {
var array = pbrSpecularGlossiness.diffuseFactor;
materialParams.color.fromArray( array );
materialParams.opacity = array[ 3 ];
}
if ( pbrSpecularGlossiness.diffuseTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'map', pbrSpecularGlossiness.diffuseTexture ) );
}
materialParams.emissive = new Color( 0.0, 0.0, 0.0 );
materialParams.glossiness = pbrSpecularGlossiness.glossinessFactor !== undefined ? pbrSpecularGlossiness.glossinessFactor : 1.0;
materialParams.specular = new Color( 1.0, 1.0, 1.0 );
if ( Array.isArray( pbrSpecularGlossiness.specularFactor ) ) {
materialParams.specular.fromArray( pbrSpecularGlossiness.specularFactor );
}
if ( pbrSpecularGlossiness.specularGlossinessTexture !== undefined ) {
var specGlossMapDef = pbrSpecularGlossiness.specularGlossinessTexture;
pending.push( parser.assignTexture( materialParams, 'glossinessMap', specGlossMapDef ) );
pending.push( parser.assignTexture( materialParams, 'specularMap', specGlossMapDef ) );
}
return Promise.all( pending );
},
createMaterial: function ( materialParams ) {
var material = new GLTFMeshStandardSGMaterial( materialParams );
material.fog = true;
material.color = materialParams.color;
material.map = materialParams.map === undefined ? null : materialParams.map;
material.lightMap = null;
material.lightMapIntensity = 1.0;
material.aoMap = materialParams.aoMap === undefined ? null : materialParams.aoMap;
material.aoMapIntensity = 1.0;
material.emissive = materialParams.emissive;
material.emissiveIntensity = 1.0;
material.emissiveMap = materialParams.emissiveMap === undefined ? null : materialParams.emissiveMap;
material.bumpMap = materialParams.bumpMap === undefined ? null : materialParams.bumpMap;
material.bumpScale = 1;
material.normalMap = materialParams.normalMap === undefined ? null : materialParams.normalMap;
material.normalMapType = TangentSpaceNormalMap;
if ( materialParams.normalScale ) material.normalScale = materialParams.normalScale;
material.displacementMap = null;
material.displacementScale = 1;
material.displacementBias = 0;
material.specularMap = materialParams.specularMap === undefined ? null : materialParams.specularMap;
material.specular = materialParams.specular;
material.glossinessMap = materialParams.glossinessMap === undefined ? null : materialParams.glossinessMap;
material.glossiness = materialParams.glossiness;
material.alphaMap = null;
material.envMap = materialParams.envMap === undefined ? null : materialParams.envMap;
material.envMapIntensity = 1.0;
material.refractionRatio = 0.98;
return material;
},
};
}
/**
* Mesh Quantization Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_mesh_quantization
*/
function GLTFMeshQuantizationExtension() {
this.name = EXTENSIONS.KHR_MESH_QUANTIZATION;
}
/*********************************/
/********** INTERPOLATION ********/
/*********************************/
// Spline Interpolation
// Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#appendix-c-spline-interpolation
function GLTFCubicSplineInterpolant( parameterPositions, sampleValues, sampleSize, resultBuffer ) {
Interpolant.call( this, parameterPositions, sampleValues, sampleSize, resultBuffer );
}
GLTFCubicSplineInterpolant.prototype = Object.create( Interpolant.prototype );
GLTFCubicSplineInterpolant.prototype.constructor = GLTFCubicSplineInterpolant;
GLTFCubicSplineInterpolant.prototype.copySampleValue_ = function ( index ) {
// Copies a sample value to the result buffer. See description of glTF
// CUBICSPLINE values layout in interpolate_() function below.
var result = this.resultBuffer,
values = this.sampleValues,
valueSize = this.valueSize,
offset = index * valueSize * 3 + valueSize;
for ( var i = 0; i !== valueSize; i ++ ) {
result[ i ] = values[ offset + i ];
}
return result;
};
GLTFCubicSplineInterpolant.prototype.beforeStart_ = GLTFCubicSplineInterpolant.prototype.copySampleValue_;
GLTFCubicSplineInterpolant.prototype.afterEnd_ = GLTFCubicSplineInterpolant.prototype.copySampleValue_;
GLTFCubicSplineInterpolant.prototype.interpolate_ = function ( i1, t0, t, t1 ) {
var result = this.resultBuffer;
var values = this.sampleValues;
var stride = this.valueSize;
var stride2 = stride * 2;
var stride3 = stride * 3;
var td = t1 - t0;
var p = ( t - t0 ) / td;
var pp = p * p;
var ppp = pp * p;
var offset1 = i1 * stride3;
var offset0 = offset1 - stride3;
var s2 = - 2 * ppp + 3 * pp;
var s3 = ppp - pp;
var s0 = 1 - s2;
var s1 = s3 - pp + p;
// Layout of keyframe output values for CUBICSPLINE animations:
// [ inTangent_1, splineVertex_1, outTangent_1, inTangent_2, splineVertex_2, ... ]
for ( var i = 0; i !== stride; i ++ ) {
var p0 = values[ offset0 + i + stride ]; // splineVertex_k
var m0 = values[ offset0 + i + stride2 ] * td; // outTangent_k * (t_k+1 - t_k)
var p1 = values[ offset1 + i + stride ]; // splineVertex_k+1
var m1 = values[ offset1 + i ] * td; // inTangent_k+1 * (t_k+1 - t_k)
result[ i ] = s0 * p0 + s1 * m0 + s2 * p1 + s3 * m1;
}
return result;
};
/*********************************/
/********** INTERNALS ************/
/*********************************/
/* CONSTANTS */
var WEBGL_CONSTANTS = {
FLOAT: 5126,
//FLOAT_MAT2: 35674,
FLOAT_MAT3: 35675,
FLOAT_MAT4: 35676,
FLOAT_VEC2: 35664,
FLOAT_VEC3: 35665,
FLOAT_VEC4: 35666,
LINEAR: 9729,
REPEAT: 10497,
SAMPLER_2D: 35678,
POINTS: 0,
LINES: 1,
LINE_LOOP: 2,
LINE_STRIP: 3,
TRIANGLES: 4,
TRIANGLE_STRIP: 5,
TRIANGLE_FAN: 6,
UNSIGNED_BYTE: 5121,
UNSIGNED_SHORT: 5123
};
var WEBGL_COMPONENT_TYPES = {
5120: Int8Array,
5121: Uint8Array,
5122: Int16Array,
5123: Uint16Array,
5125: Uint32Array,
5126: Float32Array
};
var WEBGL_FILTERS = {
9728: NearestFilter,
9729: LinearFilter,
9984: NearestMipmapNearestFilter,
9985: LinearMipmapNearestFilter,
9986: NearestMipmapLinearFilter,
9987: LinearMipmapLinearFilter
};
var WEBGL_WRAPPINGS = {
33071: ClampToEdgeWrapping,
33648: MirroredRepeatWrapping,
10497: RepeatWrapping
};
var WEBGL_TYPE_SIZES = {
'SCALAR': 1,
'VEC2': 2,
'VEC3': 3,
'VEC4': 4,
'MAT2': 4,
'MAT3': 9,
'MAT4': 16
};
var ATTRIBUTES = {
POSITION: 'position',
NORMAL: 'normal',
TANGENT: 'tangent',
TEXCOORD_0: 'uv',
TEXCOORD_1: 'uv2',
COLOR_0: 'color',
WEIGHTS_0: 'skinWeight',
JOINTS_0: 'skinIndex',
};
var PATH_PROPERTIES = {
scale: 'scale',
translation: 'position',
rotation: 'quaternion',
weights: 'morphTargetInfluences'
};
var INTERPOLATION = {
CUBICSPLINE: undefined, // We use a custom interpolant (GLTFCubicSplineInterpolation) for CUBICSPLINE tracks. Each
// keyframe track will be initialized with a default interpolation type, then modified.
LINEAR: InterpolateLinear,
STEP: InterpolateDiscrete
};
var ALPHA_MODES = {
OPAQUE: 'OPAQUE',
MASK: 'MASK',
BLEND: 'BLEND'
};
var MIME_TYPE_FORMATS = {
'image/png': RGBAFormat,
'image/jpeg': RGBFormat
};
/* UTILITY FUNCTIONS */
function resolveURL( url, path ) {
// Invalid URL
if ( typeof url !== 'string' || url === '' ) return '';
// Host Relative URL
if ( /^https?:\/\//i.test( path ) && /^\//.test( url ) ) {
path = path.replace( /(^https?:\/\/[^\/]+).*/i, '$1' );
}
// Absolute URL http://,https://,//
if ( /^(https?:)?\/\//i.test( url ) ) return url;
// Data URI
if ( /^data:.*,.*$/i.test( url ) ) return url;
// Blob URL
if ( /^blob:.*$/i.test( url ) ) return url;
// Relative URL
return path + url;
}
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#default-material
*/
function createDefaultMaterial( cache ) {
if ( cache[ 'DefaultMaterial' ] === undefined ) {
cache[ 'DefaultMaterial' ] = new MeshStandardMaterial( {
color: 0xFFFFFF,
emissive: 0x000000,
metalness: 1,
roughness: 1,
transparent: false,
depthTest: true,
side: FrontSide
} );
}
return cache[ 'DefaultMaterial' ];
}
function addUnknownExtensionsToUserData( knownExtensions, object, objectDef ) {
// Add unknown glTF extensions to an object's userData.
for ( var name in objectDef.extensions ) {
if ( knownExtensions[ name ] === undefined ) {
object.userData.gltfExtensions = object.userData.gltfExtensions || {};
object.userData.gltfExtensions[ name ] = objectDef.extensions[ name ];
}
}
}
/**
* @param {Object3D|Material|BufferGeometry} object
* @param {GLTF.definition} gltfDef
*/
function assignExtrasToUserData( object, gltfDef ) {
if ( gltfDef.extras !== undefined ) {
if ( typeof gltfDef.extras === 'object' ) {
Object.assign( object.userData, gltfDef.extras );
} else {
console.warn( 'THREE.GLTFLoader: Ignoring primitive type .extras, ' + gltfDef.extras );
}
}
}
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#morph-targets
*
* @param {BufferGeometry} geometry
* @param {Array<GLTF.Target>} targets
* @param {GLTFParser} parser
* @return {Promise<BufferGeometry>}
*/
function addMorphTargets( geometry, targets, parser ) {
var hasMorphPosition = false;
var hasMorphNormal = false;
for ( var i = 0, il = targets.length; i < il; i ++ ) {
var target = targets[ i ];
if ( target.POSITION !== undefined ) hasMorphPosition = true;
if ( target.NORMAL !== undefined ) hasMorphNormal = true;
if ( hasMorphPosition && hasMorphNormal ) break;
}
if ( ! hasMorphPosition && ! hasMorphNormal ) return Promise.resolve( geometry );
var pendingPositionAccessors = [];
var pendingNormalAccessors = [];
for ( var i = 0, il = targets.length; i < il; i ++ ) {
var target = targets[ i ];
if ( hasMorphPosition ) {
var pendingAccessor = target.POSITION !== undefined
? parser.getDependency( 'accessor', target.POSITION )
: geometry.attributes.position;
pendingPositionAccessors.push( pendingAccessor );
}
if ( hasMorphNormal ) {
var pendingAccessor = target.NORMAL !== undefined
? parser.getDependency( 'accessor', target.NORMAL )
: geometry.attributes.normal;
pendingNormalAccessors.push( pendingAccessor );
}
}
return Promise.all( [
Promise.all( pendingPositionAccessors ),
Promise.all( pendingNormalAccessors )
] ).then( function ( accessors ) {
var morphPositions = accessors[ 0 ];
var morphNormals = accessors[ 1 ];
if ( hasMorphPosition ) geometry.morphAttributes.position = morphPositions;
if ( hasMorphNormal ) geometry.morphAttributes.normal = morphNormals;
geometry.morphTargetsRelative = true;
return geometry;
} );
}
/**
* @param {Mesh} mesh
* @param {GLTF.Mesh} meshDef
*/
function updateMorphTargets( mesh, meshDef ) {
mesh.updateMorphTargets();
if ( meshDef.weights !== undefined ) {
for ( var i = 0, il = meshDef.weights.length; i < il; i ++ ) {
mesh.morphTargetInfluences[ i ] = meshDef.weights[ i ];
}
}
// .extras has user-defined data, so check that .extras.targetNames is an array.
if ( meshDef.extras && Array.isArray( meshDef.extras.targetNames ) ) {
var targetNames = meshDef.extras.targetNames;
if ( mesh.morphTargetInfluences.length === targetNames.length ) {
mesh.morphTargetDictionary = {};
for ( var i = 0, il = targetNames.length; i < il; i ++ ) {
mesh.morphTargetDictionary[ targetNames[ i ] ] = i;
}
} else {
console.warn( 'THREE.GLTFLoader: Invalid extras.targetNames length. Ignoring names.' );
}
}
}
function createPrimitiveKey( primitiveDef ) {
var dracoExtension = primitiveDef.extensions && primitiveDef.extensions[ EXTENSIONS.KHR_DRACO_MESH_COMPRESSION ];
var geometryKey;
if ( dracoExtension ) {
geometryKey = 'draco:' + dracoExtension.bufferView
+ ':' + dracoExtension.indices
+ ':' + createAttributesKey( dracoExtension.attributes );
} else {
geometryKey = primitiveDef.indices + ':' + createAttributesKey( primitiveDef.attributes ) + ':' + primitiveDef.mode;
}
return geometryKey;
}
function createAttributesKey( attributes ) {
var attributesKey = '';
var keys = Object.keys( attributes ).sort();
for ( var i = 0, il = keys.length; i < il; i ++ ) {
attributesKey += keys[ i ] + ':' + attributes[ keys[ i ] ] + ';';
}
return attributesKey;
}
/* GLTF PARSER */
function GLTFParser( json, extensions, options ) {
this.json = json || {};
this.extensions = extensions || {};
this.options = options || {};
// loader object cache
this.cache = new GLTFRegistry();
// BufferGeometry caching
this.primitiveCache = {};
this.textureLoader = new TextureLoader( this.options.manager );
this.textureLoader.setCrossOrigin( this.options.crossOrigin );
this.fileLoader = new FileLoader( this.options.manager );
this.fileLoader.setResponseType( 'arraybuffer' );
if ( this.options.crossOrigin === 'use-credentials' ) {
this.fileLoader.setWithCredentials( true );
}
}
GLTFParser.prototype.parse = function ( onLoad, onError ) {
var parser = this;
var json = this.json;
var extensions = this.extensions;
// Clear the loader cache
this.cache.removeAll();
// Mark the special nodes/meshes in json for efficient parse
this.markDefs();
Promise.all( [
this.getDependencies( 'scene' ),
this.getDependencies( 'animation' ),
this.getDependencies( 'camera' ),
] ).then( function ( dependencies ) {
var result = {
scene: dependencies[ 0 ][ json.scene || 0 ],
scenes: dependencies[ 0 ],
animations: dependencies[ 1 ],
cameras: dependencies[ 2 ],
asset: json.asset,
parser: parser,
userData: {}
};
addUnknownExtensionsToUserData( extensions, result, json );
assignExtrasToUserData( result, json );
onLoad( result );
} ).catch( onError );
};
/**
* Marks the special nodes/meshes in json for efficient parse.
*/
GLTFParser.prototype.markDefs = function () {
var nodeDefs = this.json.nodes || [];
var skinDefs = this.json.skins || [];
var meshDefs = this.json.meshes || [];
var meshReferences = {};
var meshUses = {};
// Nothing in the node definition indicates whether it is a Bone or an
// Object3D. Use the skins' joint references to mark bones.
for ( var skinIndex = 0, skinLength = skinDefs.length; skinIndex < skinLength; skinIndex ++ ) {
var joints = skinDefs[ skinIndex ].joints;
for ( var i = 0, il = joints.length; i < il; i ++ ) {
nodeDefs[ joints[ i ] ].isBone = true;
}
}
// Meshes can (and should) be reused by multiple nodes in a glTF asset. To
// avoid having more than one Mesh with the same name, count
// references and rename instances below.
//
// Example: CesiumMilkTruck sample model reuses "Wheel" meshes.
for ( var nodeIndex = 0, nodeLength = nodeDefs.length; nodeIndex < nodeLength; nodeIndex ++ ) {
var nodeDef = nodeDefs[ nodeIndex ];
if ( nodeDef.mesh !== undefined ) {
if ( meshReferences[ nodeDef.mesh ] === undefined ) {
meshReferences[ nodeDef.mesh ] = meshUses[ nodeDef.mesh ] = 0;
}
meshReferences[ nodeDef.mesh ] ++;
// Nothing in the mesh definition indicates whether it is
// a SkinnedMesh or Mesh. Use the node's mesh reference
// to mark SkinnedMesh if node has skin.
if ( nodeDef.skin !== undefined ) {
meshDefs[ nodeDef.mesh ].isSkinnedMesh = true;
}
}
}
this.json.meshReferences = meshReferences;
this.json.meshUses = meshUses;
};
/**
* Requests the specified dependency asynchronously, with caching.
* @param {string} type
* @param {number} index
* @return {Promise<Object3D|Material|THREE.Texture|AnimationClip|ArrayBuffer|Object>}
*/
GLTFParser.prototype.getDependency = function ( type, index ) {
var cacheKey = type + ':' + index;
var dependency = this.cache.get( cacheKey );
if ( ! dependency ) {
switch ( type ) {
case 'scene':
dependency = this.loadScene( index );
break;
case 'node':
dependency = this.loadNode( index );
break;
case 'mesh':
dependency = this.loadMesh( index );
break;
case 'accessor':
dependency = this.loadAccessor( index );
break;
case 'bufferView':
dependency = this.loadBufferView( index );
break;
case 'buffer':
dependency = this.loadBuffer( index );
break;
case 'material':
dependency = this.loadMaterial( index );
break;
case 'texture':
dependency = this.loadTexture( index );
break;
case 'skin':
dependency = this.loadSkin( index );
break;
case 'animation':
dependency = this.loadAnimation( index );
break;
case 'camera':
dependency = this.loadCamera( index );
break;
case 'light':
dependency = this.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ].loadLight( index );
break;
default:
throw new Error( 'Unknown type: ' + type );
}
this.cache.add( cacheKey, dependency );
}
return dependency;
};
/**
* Requests all dependencies of the specified type asynchronously, with caching.
* @param {string} type
* @return {Promise<Array<Object>>}
*/
GLTFParser.prototype.getDependencies = function ( type ) {
var dependencies = this.cache.get( type );
if ( ! dependencies ) {
var parser = this;
var defs = this.json[ type + ( type === 'mesh' ? 'es' : 's' ) ] || [];
dependencies = Promise.all( defs.map( function ( def, index ) {
return parser.getDependency( type, index );
} ) );
this.cache.add( type, dependencies );
}
return dependencies;
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#buffers-and-buffer-views
* @param {number} bufferIndex
* @return {Promise<ArrayBuffer>}
*/
GLTFParser.prototype.loadBuffer = function ( bufferIndex ) {
var bufferDef = this.json.buffers[ bufferIndex ];
var loader = this.fileLoader;
if ( bufferDef.type && bufferDef.type !== 'arraybuffer' ) {
throw new Error( 'THREE.GLTFLoader: ' + bufferDef.type + ' buffer type is not supported.' );
}
// If present, GLB container is required to be the first buffer.
if ( bufferDef.uri === undefined && bufferIndex === 0 ) {
return Promise.resolve( this.extensions[ EXTENSIONS.KHR_BINARY_GLTF ].body );
}
var options = this.options;
return new Promise( function ( resolve, reject ) {
loader.load( resolveURL( bufferDef.uri, options.path ), resolve, undefined, function () {
reject( new Error( 'THREE.GLTFLoader: Failed to load buffer "' + bufferDef.uri + '".' ) );
} );
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#buffers-and-buffer-views
* @param {number} bufferViewIndex
* @return {Promise<ArrayBuffer>}
*/
GLTFParser.prototype.loadBufferView = function ( bufferViewIndex ) {
var bufferViewDef = this.json.bufferViews[ bufferViewIndex ];
return this.getDependency( 'buffer', bufferViewDef.buffer ).then( function ( buffer ) {
var byteLength = bufferViewDef.byteLength || 0;
var byteOffset = bufferViewDef.byteOffset || 0;
return buffer.slice( byteOffset, byteOffset + byteLength );
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#accessors
* @param {number} accessorIndex
* @return {Promise<BufferAttribute|InterleavedBufferAttribute>}
*/
GLTFParser.prototype.loadAccessor = function ( accessorIndex ) {
var parser = this;
var json = this.json;
var accessorDef = this.json.accessors[ accessorIndex ];
if ( accessorDef.bufferView === undefined && accessorDef.sparse === undefined ) {
// Ignore empty accessors, which may be used to declare runtime
// information about attributes coming from another source (e.g. Draco
// compression extension).
return Promise.resolve( null );
}
var pendingBufferViews = [];
if ( accessorDef.bufferView !== undefined ) {
pendingBufferViews.push( this.getDependency( 'bufferView', accessorDef.bufferView ) );
} else {
pendingBufferViews.push( null );
}
if ( accessorDef.sparse !== undefined ) {
pendingBufferViews.push( this.getDependency( 'bufferView', accessorDef.sparse.indices.bufferView ) );
pendingBufferViews.push( this.getDependency( 'bufferView', accessorDef.sparse.values.bufferView ) );
}
return Promise.all( pendingBufferViews ).then( function ( bufferViews ) {
var bufferView = bufferViews[ 0 ];
var itemSize = WEBGL_TYPE_SIZES[ accessorDef.type ];
var TypedArray = WEBGL_COMPONENT_TYPES[ accessorDef.componentType ];
// For VEC3: itemSize is 3, elementBytes is 4, itemBytes is 12.
var elementBytes = TypedArray.BYTES_PER_ELEMENT;
var itemBytes = elementBytes * itemSize;
var byteOffset = accessorDef.byteOffset || 0;
var byteStride = accessorDef.bufferView !== undefined ? json.bufferViews[ accessorDef.bufferView ].byteStride : undefined;
var normalized = accessorDef.normalized === true;
var array, bufferAttribute;
// The buffer is not interleaved if the stride is the item size in bytes.
if ( byteStride && byteStride !== itemBytes ) {
// Each "slice" of the buffer, as defined by 'count' elements of 'byteStride' bytes, gets its own InterleavedBuffer
// This makes sure that IBA.count reflects accessor.count properly
var ibSlice = Math.floor( byteOffset / byteStride );
var ibCacheKey = 'InterleavedBuffer:' + accessorDef.bufferView + ':' + accessorDef.componentType + ':' + ibSlice + ':' + accessorDef.count;
var ib = parser.cache.get( ibCacheKey );
if ( ! ib ) {
array = new TypedArray( bufferView, ibSlice * byteStride, accessorDef.count * byteStride / elementBytes );
// Integer parameters to IB/IBA are in array elements, not bytes.
ib = new InterleavedBuffer( array, byteStride / elementBytes );
parser.cache.add( ibCacheKey, ib );
}
bufferAttribute = new InterleavedBufferAttribute( ib, itemSize, ( byteOffset % byteStride ) / elementBytes, normalized );
} else {
if ( bufferView === null ) {
array = new TypedArray( accessorDef.count * itemSize );
} else {
array = new TypedArray( bufferView, byteOffset, accessorDef.count * itemSize );
}
bufferAttribute = new BufferAttribute( array, itemSize, normalized );
}
// https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#sparse-accessors
if ( accessorDef.sparse !== undefined ) {
var itemSizeIndices = WEBGL_TYPE_SIZES.SCALAR;
var TypedArrayIndices = WEBGL_COMPONENT_TYPES[ accessorDef.sparse.indices.componentType ];
var byteOffsetIndices = accessorDef.sparse.indices.byteOffset || 0;
var byteOffsetValues = accessorDef.sparse.values.byteOffset || 0;
var sparseIndices = new TypedArrayIndices( bufferViews[ 1 ], byteOffsetIndices, accessorDef.sparse.count * itemSizeIndices );
var sparseValues = new TypedArray( bufferViews[ 2 ], byteOffsetValues, accessorDef.sparse.count * itemSize );
if ( bufferView !== null ) {
// Avoid modifying the original ArrayBuffer, if the bufferView wasn't initialized with zeroes.
bufferAttribute = new BufferAttribute( bufferAttribute.array.slice(), bufferAttribute.itemSize, bufferAttribute.normalized );
}
for ( var i = 0, il = sparseIndices.length; i < il; i ++ ) {
var index = sparseIndices[ i ];
bufferAttribute.setX( index, sparseValues[ i * itemSize ] );
if ( itemSize >= 2 ) bufferAttribute.setY( index, sparseValues[ i * itemSize + 1 ] );
if ( itemSize >= 3 ) bufferAttribute.setZ( index, sparseValues[ i * itemSize + 2 ] );
if ( itemSize >= 4 ) bufferAttribute.setW( index, sparseValues[ i * itemSize + 3 ] );
if ( itemSize >= 5 ) throw new Error( 'THREE.GLTFLoader: Unsupported itemSize in sparse BufferAttribute.' );
}
}
return bufferAttribute;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#textures
* @param {number} textureIndex
* @return {Promise<THREE.Texture>}
*/
GLTFParser.prototype.loadTexture = function ( textureIndex ) {
var parser = this;
var json = this.json;
var options = this.options;
var textureLoader = this.textureLoader;
var URL = self.URL || self.webkitURL;
var textureDef = json.textures[ textureIndex ];
var textureExtensions = textureDef.extensions || {};
var source;
if ( textureExtensions[ EXTENSIONS.MSFT_TEXTURE_DDS ] ) {
source = json.images[ textureExtensions[ EXTENSIONS.MSFT_TEXTURE_DDS ].source ];
} else {
source = json.images[ textureDef.source ];
}
var sourceURI = source.uri;
var isObjectURL = false;
if ( source.bufferView !== undefined ) {
// Load binary image data from bufferView, if provided.
sourceURI = parser.getDependency( 'bufferView', source.bufferView ).then( function ( bufferView ) {
isObjectURL = true;
var blob = new Blob( [ bufferView ], { type: source.mimeType } );
sourceURI = URL.createObjectURL( blob );
return sourceURI;
} );
}
return Promise.resolve( sourceURI ).then( function ( sourceURI ) {
// Load Texture resource.
var loader = options.manager.getHandler( sourceURI );
if ( ! loader ) {
loader = textureExtensions[ EXTENSIONS.MSFT_TEXTURE_DDS ]
? parser.extensions[ EXTENSIONS.MSFT_TEXTURE_DDS ].ddsLoader
: textureLoader;
}
return new Promise( function ( resolve, reject ) {
loader.load( resolveURL( sourceURI, options.path ), resolve, undefined, reject );
} );
} ).then( function ( texture ) {
// Clean up resources and configure Texture.
if ( isObjectURL === true ) {
URL.revokeObjectURL( sourceURI );
}
texture.flipY = false;
if ( textureDef.name ) texture.name = textureDef.name;
// Ignore unknown mime types, like DDS files.
if ( source.mimeType in MIME_TYPE_FORMATS ) {
texture.format = MIME_TYPE_FORMATS[ source.mimeType ];
}
var samplers = json.samplers || {};
var sampler = samplers[ textureDef.sampler ] || {};
texture.magFilter = WEBGL_FILTERS[ sampler.magFilter ] || LinearFilter;
texture.minFilter = WEBGL_FILTERS[ sampler.minFilter ] || LinearMipmapLinearFilter;
texture.wrapS = WEBGL_WRAPPINGS[ sampler.wrapS ] || RepeatWrapping;
texture.wrapT = WEBGL_WRAPPINGS[ sampler.wrapT ] || RepeatWrapping;
return texture;
} );
};
/**
* Asynchronously assigns a texture to the given material parameters.
* @param {Object} materialParams
* @param {string} mapName
* @param {Object} mapDef
* @return {Promise}
*/
GLTFParser.prototype.assignTexture = function ( materialParams, mapName, mapDef ) {
var parser = this;
return this.getDependency( 'texture', mapDef.index ).then( function ( texture ) {
if ( ! texture.isCompressedTexture ) {
switch ( mapName ) {
case 'aoMap':
case 'emissiveMap':
case 'metalnessMap':
case 'normalMap':
case 'roughnessMap':
texture.format = RGBFormat;
break;
}
}
// Materials sample aoMap from UV set 1 and other maps from UV set 0 - this can't be configured
// However, we will copy UV set 0 to UV set 1 on demand for aoMap
if ( mapDef.texCoord !== undefined && mapDef.texCoord != 0 && ! ( mapName === 'aoMap' && mapDef.texCoord == 1 ) ) {
console.warn( 'THREE.GLTFLoader: Custom UV set ' + mapDef.texCoord + ' for texture ' + mapName + ' not yet supported.' );
}
if ( parser.extensions[ EXTENSIONS.KHR_TEXTURE_TRANSFORM ] ) {
var transform = mapDef.extensions !== undefined ? mapDef.extensions[ EXTENSIONS.KHR_TEXTURE_TRANSFORM ] : undefined;
if ( transform ) {
texture = parser.extensions[ EXTENSIONS.KHR_TEXTURE_TRANSFORM ].extendTexture( texture, transform );
}
}
materialParams[ mapName ] = texture;
} );
};
/**
* Assigns final material to a Mesh, Line, or Points instance. The instance
* already has a material (generated from the glTF material options alone)
* but reuse of the same glTF material may require multiple threejs materials
* to accomodate different primitive types, defines, etc. New materials will
* be created if necessary, and reused from a cache.
* @param {Object3D} mesh Mesh, Line, or Points instance.
*/
GLTFParser.prototype.assignFinalMaterial = function ( mesh ) {
var geometry = mesh.geometry;
var material = mesh.material;
var useVertexTangents = geometry.attributes.tangent !== undefined;
var useVertexColors = geometry.attributes.color !== undefined;
var useFlatShading = geometry.attributes.normal === undefined;
var useSkinning = mesh.isSkinnedMesh === true;
var useMorphTargets = Object.keys( geometry.morphAttributes ).length > 0;
var useMorphNormals = useMorphTargets && geometry.morphAttributes.normal !== undefined;
if ( mesh.isPoints ) {
var cacheKey = 'PointsMaterial:' + material.uuid;
var pointsMaterial = this.cache.get( cacheKey );
if ( ! pointsMaterial ) {
pointsMaterial = new PointsMaterial();
Material.prototype.copy.call( pointsMaterial, material );
pointsMaterial.color.copy( material.color );
pointsMaterial.map = material.map;
pointsMaterial.sizeAttenuation = false; // glTF spec says points should be 1px
this.cache.add( cacheKey, pointsMaterial );
}
material = pointsMaterial;
} else if ( mesh.isLine ) {
var cacheKey = 'LineBasicMaterial:' + material.uuid;
var lineMaterial = this.cache.get( cacheKey );
if ( ! lineMaterial ) {
lineMaterial = new LineBasicMaterial();
Material.prototype.copy.call( lineMaterial, material );
lineMaterial.color.copy( material.color );
this.cache.add( cacheKey, lineMaterial );
}
material = lineMaterial;
}
// Clone the material if it will be modified
if ( useVertexTangents || useVertexColors || useFlatShading || useSkinning || useMorphTargets ) {
var cacheKey = 'ClonedMaterial:' + material.uuid + ':';
if ( material.isGLTFSpecularGlossinessMaterial ) cacheKey += 'specular-glossiness:';
if ( useSkinning ) cacheKey += 'skinning:';
if ( useVertexTangents ) cacheKey += 'vertex-tangents:';
if ( useVertexColors ) cacheKey += 'vertex-colors:';
if ( useFlatShading ) cacheKey += 'flat-shading:';
if ( useMorphTargets ) cacheKey += 'morph-targets:';
if ( useMorphNormals ) cacheKey += 'morph-normals:';
var cachedMaterial = this.cache.get( cacheKey );
if ( ! cachedMaterial ) {
cachedMaterial = material.clone();
if ( useSkinning ) cachedMaterial.skinning = true;
if ( useVertexTangents ) cachedMaterial.vertexTangents = true;
if ( useVertexColors ) cachedMaterial.vertexColors = true;
if ( useFlatShading ) cachedMaterial.flatShading = true;
if ( useMorphTargets ) cachedMaterial.morphTargets = true;
if ( useMorphNormals ) cachedMaterial.morphNormals = true;
this.cache.add( cacheKey, cachedMaterial );
}
material = cachedMaterial;
}
// workarounds for mesh and geometry
if ( material.aoMap && geometry.attributes.uv2 === undefined && geometry.attributes.uv !== undefined ) {
geometry.setAttribute( 'uv2', geometry.attributes.uv );
}
// https://github.com/mrdoob/three.js/issues/11438#issuecomment-507003995
if ( material.normalScale && ! useVertexTangents ) {
material.normalScale.y = - material.normalScale.y;
}
if ( material.clearcoatNormalScale && ! useVertexTangents ) {
material.clearcoatNormalScale.y = - material.clearcoatNormalScale.y;
}
mesh.material = material;
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#materials
* @param {number} materialIndex
* @return {Promise<Material>}
*/
GLTFParser.prototype.loadMaterial = function ( materialIndex ) {
var parser = this;
var json = this.json;
var extensions = this.extensions;
var materialDef = json.materials[ materialIndex ];
var materialType;
var materialParams = {};
var materialExtensions = materialDef.extensions || {};
var pending = [];
if ( materialExtensions[ EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS ] ) {
var sgExtension = extensions[ EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS ];
materialType = sgExtension.getMaterialType();
pending.push( sgExtension.extendParams( materialParams, materialDef, parser ) );
} else if ( materialExtensions[ EXTENSIONS.KHR_MATERIALS_UNLIT ] ) {
var kmuExtension = extensions[ EXTENSIONS.KHR_MATERIALS_UNLIT ];
materialType = kmuExtension.getMaterialType();
pending.push( kmuExtension.extendParams( materialParams, materialDef, parser ) );
} else {
// Specification:
// https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#metallic-roughness-material
materialType = MeshStandardMaterial;
var metallicRoughness = materialDef.pbrMetallicRoughness || {};
materialParams.color = new Color( 1.0, 1.0, 1.0 );
materialParams.opacity = 1.0;
if ( Array.isArray( metallicRoughness.baseColorFactor ) ) {
var array = metallicRoughness.baseColorFactor;
materialParams.color.fromArray( array );
materialParams.opacity = array[ 3 ];
}
if ( metallicRoughness.baseColorTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'map', metallicRoughness.baseColorTexture ) );
}
materialParams.metalness = metallicRoughness.metallicFactor !== undefined ? metallicRoughness.metallicFactor : 1.0;
materialParams.roughness = metallicRoughness.roughnessFactor !== undefined ? metallicRoughness.roughnessFactor : 1.0;
if ( metallicRoughness.metallicRoughnessTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'metalnessMap', metallicRoughness.metallicRoughnessTexture ) );
pending.push( parser.assignTexture( materialParams, 'roughnessMap', metallicRoughness.metallicRoughnessTexture ) );
}
}
if ( materialDef.doubleSided === true ) {
materialParams.side = DoubleSide;
}
var alphaMode = materialDef.alphaMode || ALPHA_MODES.OPAQUE;
if ( alphaMode === ALPHA_MODES.BLEND ) {
materialParams.transparent = true;
// See: https://github.com/mrdoob/three.js/issues/17706
materialParams.depthWrite = false;
} else {
materialParams.transparent = false;
if ( alphaMode === ALPHA_MODES.MASK ) {
materialParams.alphaTest = materialDef.alphaCutoff !== undefined ? materialDef.alphaCutoff : 0.5;
}
}
if ( materialDef.normalTexture !== undefined && materialType !== MeshBasicMaterial ) {
pending.push( parser.assignTexture( materialParams, 'normalMap', materialDef.normalTexture ) );
materialParams.normalScale = new Vector2( 1, 1 );
if ( materialDef.normalTexture.scale !== undefined ) {
materialParams.normalScale.set( materialDef.normalTexture.scale, materialDef.normalTexture.scale );
}
}
if ( materialDef.occlusionTexture !== undefined && materialType !== MeshBasicMaterial ) {
pending.push( parser.assignTexture( materialParams, 'aoMap', materialDef.occlusionTexture ) );
if ( materialDef.occlusionTexture.strength !== undefined ) {
materialParams.aoMapIntensity = materialDef.occlusionTexture.strength;
}
}
if ( materialDef.emissiveFactor !== undefined && materialType !== MeshBasicMaterial ) {
materialParams.emissive = new Color().fromArray( materialDef.emissiveFactor );
}
if ( materialDef.emissiveTexture !== undefined && materialType !== MeshBasicMaterial ) {
pending.push( parser.assignTexture( materialParams, 'emissiveMap', materialDef.emissiveTexture ) );
}
if ( materialExtensions[ EXTENSIONS.KHR_MATERIALS_CLEARCOAT ] ) {
var clearcoatExtension = extensions[ EXTENSIONS.KHR_MATERIALS_CLEARCOAT ];
materialType = clearcoatExtension.getMaterialType();
pending.push( clearcoatExtension.extendParams( materialParams, { extensions: materialExtensions }, parser ) );
}
return Promise.all( pending ).then( function () {
var material;
if ( materialType === GLTFMeshStandardSGMaterial ) {
material = extensions[ EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS ].createMaterial( materialParams );
} else {
material = new materialType( materialParams );
}
if ( materialDef.name ) material.name = materialDef.name;
// baseColorTexture, emissiveTexture, and specularGlossinessTexture use sRGB encoding.
if ( material.map ) material.map.encoding = sRGBEncoding;
if ( material.emissiveMap ) material.emissiveMap.encoding = sRGBEncoding;
assignExtrasToUserData( material, materialDef );
if ( materialDef.extensions ) addUnknownExtensionsToUserData( extensions, material, materialDef );
return material;
} );
};
/**
* @param {BufferGeometry} geometry
* @param {GLTF.Primitive} primitiveDef
* @param {GLTFParser} parser
*/
function computeBounds( geometry, primitiveDef, parser ) {
var attributes = primitiveDef.attributes;
var box = new Box3();
if ( attributes.POSITION !== undefined ) {
var accessor = parser.json.accessors[ attributes.POSITION ];
var min = accessor.min;
var max = accessor.max;
// glTF requires 'min' and 'max', but VRM (which extends glTF) currently ignores that requirement.
if ( min !== undefined && max !== undefined ) {
box.set(
new Vector3( min[ 0 ], min[ 1 ], min[ 2 ] ),
new Vector3( max[ 0 ], max[ 1 ], max[ 2 ] ) );
} else {
console.warn( 'THREE.GLTFLoader: Missing min/max properties for accessor POSITION.' );
return;
}
} else {
return;
}
var targets = primitiveDef.targets;
if ( targets !== undefined ) {
var maxDisplacement = new Vector3();
var vector = new Vector3();
for ( var i = 0, il = targets.length; i < il; i ++ ) {
var target = targets[ i ];
if ( target.POSITION !== undefined ) {
var accessor = parser.json.accessors[ target.POSITION ];
var min = accessor.min;
var max = accessor.max;
// glTF requires 'min' and 'max', but VRM (which extends glTF) currently ignores that requirement.
if ( min !== undefined && max !== undefined ) {
// we need to get max of absolute components because target weight is [-1,1]
vector.setX( Math.max( Math.abs( min[ 0 ] ), Math.abs( max[ 0 ] ) ) );
vector.setY( Math.max( Math.abs( min[ 1 ] ), Math.abs( max[ 1 ] ) ) );
vector.setZ( Math.max( Math.abs( min[ 2 ] ), Math.abs( max[ 2 ] ) ) );
// Note: this assumes that the sum of all weights is at most 1. This isn't quite correct - it's more conservative
// to assume that each target can have a max weight of 1. However, for some use cases - notably, when morph targets
// are used to implement key-frame animations and as such only two are active at a time - this results in very large
// boxes. So for now we make a box that's sometimes a touch too small but is hopefully mostly of reasonable size.
maxDisplacement.max( vector );
} else {
console.warn( 'THREE.GLTFLoader: Missing min/max properties for accessor POSITION.' );
}
}
}
// As per comment above this box isn't conservative, but has a reasonable size for a very large number of morph targets.
box.expandByVector( maxDisplacement );
}
geometry.boundingBox = box;
var sphere = new Sphere();
box.getCenter( sphere.center );
sphere.radius = box.min.distanceTo( box.max ) / 2;
geometry.boundingSphere = sphere;
}
/**
* @param {BufferGeometry} geometry
* @param {GLTF.Primitive} primitiveDef
* @param {GLTFParser} parser
* @return {Promise<BufferGeometry>}
*/
function addPrimitiveAttributes( geometry, primitiveDef, parser ) {
var attributes = primitiveDef.attributes;
var pending = [];
function assignAttributeAccessor( accessorIndex, attributeName ) {
return parser.getDependency( 'accessor', accessorIndex )
.then( function ( accessor ) {
geometry.setAttribute( attributeName, accessor );
} );
}
for ( var gltfAttributeName in attributes ) {
var threeAttributeName = ATTRIBUTES[ gltfAttributeName ] || gltfAttributeName.toLowerCase();
// Skip attributes already provided by e.g. Draco extension.
if ( threeAttributeName in geometry.attributes ) continue;
pending.push( assignAttributeAccessor( attributes[ gltfAttributeName ], threeAttributeName ) );
}
if ( primitiveDef.indices !== undefined && ! geometry.index ) {
var accessor = parser.getDependency( 'accessor', primitiveDef.indices ).then( function ( accessor ) {
geometry.setIndex( accessor );
} );
pending.push( accessor );
}
assignExtrasToUserData( geometry, primitiveDef );
computeBounds( geometry, primitiveDef, parser );
return Promise.all( pending ).then( function () {
return primitiveDef.targets !== undefined
? addMorphTargets( geometry, primitiveDef.targets, parser )
: geometry;
} );
}
/**
* @param {BufferGeometry} geometry
* @param {Number} drawMode
* @return {BufferGeometry}
*/
function toTrianglesDrawMode( geometry, drawMode ) {
var index = geometry.getIndex();
// generate index if not present
if ( index === null ) {
var indices = [];
var position = geometry.getAttribute( 'position' );
if ( position !== undefined ) {
for ( var i = 0; i < position.count; i ++ ) {
indices.push( i );
}
geometry.setIndex( indices );
index = geometry.getIndex();
} else {
console.error( 'THREE.GLTFLoader.toTrianglesDrawMode(): Undefined position attribute. Processing not possible.' );
return geometry;
}
}
//
var numberOfTriangles = index.count - 2;
var newIndices = [];
if ( drawMode === TriangleFanDrawMode ) {
// gl.TRIANGLE_FAN
for ( var i = 1; i <= numberOfTriangles; i ++ ) {
newIndices.push( index.getX( 0 ) );
newIndices.push( index.getX( i ) );
newIndices.push( index.getX( i + 1 ) );
}
} else {
// gl.TRIANGLE_STRIP
for ( var i = 0; i < numberOfTriangles; i ++ ) {
if ( i % 2 === 0 ) {
newIndices.push( index.getX( i ) );
newIndices.push( index.getX( i + 1 ) );
newIndices.push( index.getX( i + 2 ) );
} else {
newIndices.push( index.getX( i + 2 ) );
newIndices.push( index.getX( i + 1 ) );
newIndices.push( index.getX( i ) );
}
}
}
if ( ( newIndices.length / 3 ) !== numberOfTriangles ) {
console.error( 'THREE.GLTFLoader.toTrianglesDrawMode(): Unable to generate correct amount of triangles.' );
}
// build final geometry
var newGeometry = geometry.clone();
newGeometry.setIndex( newIndices );
return newGeometry;
}
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#geometry
*
* Creates BufferGeometries from primitives.
*
* @param {Array<GLTF.Primitive>} primitives
* @return {Promise<Array<BufferGeometry>>}
*/
GLTFParser.prototype.loadGeometries = function ( primitives ) {
var parser = this;
var extensions = this.extensions;
var cache = this.primitiveCache;
function createDracoPrimitive( primitive ) {
return extensions[ EXTENSIONS.KHR_DRACO_MESH_COMPRESSION ]
.decodePrimitive( primitive, parser )
.then( function ( geometry ) {
return addPrimitiveAttributes( geometry, primitive, parser );
} );
}
var pending = [];
for ( var i = 0, il = primitives.length; i < il; i ++ ) {
var primitive = primitives[ i ];
var cacheKey = createPrimitiveKey( primitive );
// See if we've already created this geometry
var cached = cache[ cacheKey ];
if ( cached ) {
// Use the cached geometry if it exists
pending.push( cached.promise );
} else {
var geometryPromise;
if ( primitive.extensions && primitive.extensions[ EXTENSIONS.KHR_DRACO_MESH_COMPRESSION ] ) {
// Use DRACO geometry if available
geometryPromise = createDracoPrimitive( primitive );
} else {
// Otherwise create a new geometry
geometryPromise = addPrimitiveAttributes( new BufferGeometry(), primitive, parser );
}
// Cache this geometry
cache[ cacheKey ] = { primitive: primitive, promise: geometryPromise };
pending.push( geometryPromise );
}
}
return Promise.all( pending );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#meshes
* @param {number} meshIndex
* @return {Promise<Group|Mesh|SkinnedMesh>}
*/
GLTFParser.prototype.loadMesh = function ( meshIndex ) {
var parser = this;
var json = this.json;
var meshDef = json.meshes[ meshIndex ];
var primitives = meshDef.primitives;
var pending = [];
for ( var i = 0, il = primitives.length; i < il; i ++ ) {
var material = primitives[ i ].material === undefined
? createDefaultMaterial( this.cache )
: this.getDependency( 'material', primitives[ i ].material );
pending.push( material );
}
pending.push( parser.loadGeometries( primitives ) );
return Promise.all( pending ).then( function ( results ) {
var materials = results.slice( 0, results.length - 1 );
var geometries = results[ results.length - 1 ];
var meshes = [];
for ( var i = 0, il = geometries.length; i < il; i ++ ) {
var geometry = geometries[ i ];
var primitive = primitives[ i ];
// 1. create Mesh
var mesh;
var material = materials[ i ];
if ( primitive.mode === WEBGL_CONSTANTS.TRIANGLES ||
primitive.mode === WEBGL_CONSTANTS.TRIANGLE_STRIP ||
primitive.mode === WEBGL_CONSTANTS.TRIANGLE_FAN ||
primitive.mode === undefined ) {
// .isSkinnedMesh isn't in glTF spec. See .markDefs()
mesh = meshDef.isSkinnedMesh === true
? new SkinnedMesh( geometry, material )
: new Mesh( geometry, material );
if ( mesh.isSkinnedMesh === true && ! mesh.geometry.attributes.skinWeight.normalized ) {
// we normalize floating point skin weight array to fix malformed assets (see #15319)
// it's important to skip this for non-float32 data since normalizeSkinWeights assumes non-normalized inputs
mesh.normalizeSkinWeights();
}
if ( primitive.mode === WEBGL_CONSTANTS.TRIANGLE_STRIP ) {
mesh.geometry = toTrianglesDrawMode( mesh.geometry, TriangleStripDrawMode );
} else if ( primitive.mode === WEBGL_CONSTANTS.TRIANGLE_FAN ) {
mesh.geometry = toTrianglesDrawMode( mesh.geometry, TriangleFanDrawMode );
}
} else if ( primitive.mode === WEBGL_CONSTANTS.LINES ) {
mesh = new LineSegments( geometry, material );
} else if ( primitive.mode === WEBGL_CONSTANTS.LINE_STRIP ) {
mesh = new Line( geometry, material );
} else if ( primitive.mode === WEBGL_CONSTANTS.LINE_LOOP ) {
mesh = new LineLoop( geometry, material );
} else if ( primitive.mode === WEBGL_CONSTANTS.POINTS ) {
mesh = new Points( geometry, material );
} else {
throw new Error( 'THREE.GLTFLoader: Primitive mode unsupported: ' + primitive.mode );
}
if ( Object.keys( mesh.geometry.morphAttributes ).length > 0 ) {
updateMorphTargets( mesh, meshDef );
}
mesh.name = meshDef.name || ( 'mesh_' + meshIndex );
if ( geometries.length > 1 ) mesh.name += '_' + i;
assignExtrasToUserData( mesh, meshDef );
parser.assignFinalMaterial( mesh );
meshes.push( mesh );
}
if ( meshes.length === 1 ) {
return meshes[ 0 ];
}
var group = new Group();
for ( var i = 0, il = meshes.length; i < il; i ++ ) {
group.add( meshes[ i ] );
}
return group;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#cameras
* @param {number} cameraIndex
* @return {Promise<THREE.Camera>}
*/
GLTFParser.prototype.loadCamera = function ( cameraIndex ) {
var camera;
var cameraDef = this.json.cameras[ cameraIndex ];
var params = cameraDef[ cameraDef.type ];
if ( ! params ) {
console.warn( 'THREE.GLTFLoader: Missing camera parameters.' );
return;
}
if ( cameraDef.type === 'perspective' ) {
camera = new PerspectiveCamera( MathUtils.radToDeg( params.yfov ), params.aspectRatio || 1, params.znear || 1, params.zfar || 2e6 );
} else if ( cameraDef.type === 'orthographic' ) {
camera = new OrthographicCamera( - params.xmag, params.xmag, params.ymag, - params.ymag, params.znear, params.zfar );
}
if ( cameraDef.name ) camera.name = cameraDef.name;
assignExtrasToUserData( camera, cameraDef );
return Promise.resolve( camera );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#skins
* @param {number} skinIndex
* @return {Promise<Object>}
*/
GLTFParser.prototype.loadSkin = function ( skinIndex ) {
var skinDef = this.json.skins[ skinIndex ];
var skinEntry = { joints: skinDef.joints };
if ( skinDef.inverseBindMatrices === undefined ) {
return Promise.resolve( skinEntry );
}
return this.getDependency( 'accessor', skinDef.inverseBindMatrices ).then( function ( accessor ) {
skinEntry.inverseBindMatrices = accessor;
return skinEntry;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#animations
* @param {number} animationIndex
* @return {Promise<AnimationClip>}
*/
GLTFParser.prototype.loadAnimation = function ( animationIndex ) {
var json = this.json;
var animationDef = json.animations[ animationIndex ];
var pendingNodes = [];
var pendingInputAccessors = [];
var pendingOutputAccessors = [];
var pendingSamplers = [];
var pendingTargets = [];
for ( var i = 0, il = animationDef.channels.length; i < il; i ++ ) {
var channel = animationDef.channels[ i ];
var sampler = animationDef.samplers[ channel.sampler ];
var target = channel.target;
var name = target.node !== undefined ? target.node : target.id; // NOTE: target.id is deprecated.
var input = animationDef.parameters !== undefined ? animationDef.parameters[ sampler.input ] : sampler.input;
var output = animationDef.parameters !== undefined ? animationDef.parameters[ sampler.output ] : sampler.output;
pendingNodes.push( this.getDependency( 'node', name ) );
pendingInputAccessors.push( this.getDependency( 'accessor', input ) );
pendingOutputAccessors.push( this.getDependency( 'accessor', output ) );
pendingSamplers.push( sampler );
pendingTargets.push( target );
}
return Promise.all( [
Promise.all( pendingNodes ),
Promise.all( pendingInputAccessors ),
Promise.all( pendingOutputAccessors ),
Promise.all( pendingSamplers ),
Promise.all( pendingTargets )
] ).then( function ( dependencies ) {
var nodes = dependencies[ 0 ];
var inputAccessors = dependencies[ 1 ];
var outputAccessors = dependencies[ 2 ];
var samplers = dependencies[ 3 ];
var targets = dependencies[ 4 ];
var tracks = [];
for ( var i = 0, il = nodes.length; i < il; i ++ ) {
var node = nodes[ i ];
var inputAccessor = inputAccessors[ i ];
var outputAccessor = outputAccessors[ i ];
var sampler = samplers[ i ];
var target = targets[ i ];
if ( node === undefined ) continue;
node.updateMatrix();
node.matrixAutoUpdate = true;
var TypedKeyframeTrack;
switch ( PATH_PROPERTIES[ target.path ] ) {
case PATH_PROPERTIES.weights:
TypedKeyframeTrack = NumberKeyframeTrack;
break;
case PATH_PROPERTIES.rotation:
TypedKeyframeTrack = QuaternionKeyframeTrack;
break;
case PATH_PROPERTIES.position:
case PATH_PROPERTIES.scale:
default:
TypedKeyframeTrack = VectorKeyframeTrack;
break;
}
var targetName = node.name ? node.name : node.uuid;
var interpolation = sampler.interpolation !== undefined ? INTERPOLATION[ sampler.interpolation ] : InterpolateLinear;
var targetNames = [];
if ( PATH_PROPERTIES[ target.path ] === PATH_PROPERTIES.weights ) {
// Node may be a Group (glTF mesh with several primitives) or a Mesh.
node.traverse( function ( object ) {
if ( object.isMesh === true && object.morphTargetInfluences ) {
targetNames.push( object.name ? object.name : object.uuid );
}
} );
} else {
targetNames.push( targetName );
}
var outputArray = outputAccessor.array;
if ( outputAccessor.normalized ) {
var scale;
if ( outputArray.constructor === Int8Array ) {
scale = 1 / 127;
} else if ( outputArray.constructor === Uint8Array ) {
scale = 1 / 255;
} else if ( outputArray.constructor == Int16Array ) {
scale = 1 / 32767;
} else if ( outputArray.constructor === Uint16Array ) {
scale = 1 / 65535;
} else {
throw new Error( 'THREE.GLTFLoader: Unsupported output accessor component type.' );
}
var scaled = new Float32Array( outputArray.length );
for ( var j = 0, jl = outputArray.length; j < jl; j ++ ) {
scaled[ j ] = outputArray[ j ] * scale;
}
outputArray = scaled;
}
for ( var j = 0, jl = targetNames.length; j < jl; j ++ ) {
var track = new TypedKeyframeTrack(
targetNames[ j ] + '.' + PATH_PROPERTIES[ target.path ],
inputAccessor.array,
outputArray,
interpolation
);
// Override interpolation with custom factory method.
if ( sampler.interpolation === 'CUBICSPLINE' ) {
track.createInterpolant = function InterpolantFactoryMethodGLTFCubicSpline( result ) {
// A CUBICSPLINE keyframe in glTF has three output values for each input value,
// representing inTangent, splineVertex, and outTangent. As a result, track.getValueSize()
// must be divided by three to get the interpolant's sampleSize argument.
return new GLTFCubicSplineInterpolant( this.times, this.values, this.getValueSize() / 3, result );
};
// Mark as CUBICSPLINE. `track.getInterpolation()` doesn't support custom interpolants.
track.createInterpolant.isInterpolantFactoryMethodGLTFCubicSpline = true;
}
tracks.push( track );
}
}
var name = animationDef.name ? animationDef.name : 'animation_' + animationIndex;
return new AnimationClip( name, undefined, tracks );
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#nodes-and-hierarchy
* @param {number} nodeIndex
* @return {Promise<Object3D>}
*/
GLTFParser.prototype.loadNode = function ( nodeIndex ) {
var json = this.json;
var extensions = this.extensions;
var parser = this;
var meshReferences = json.meshReferences;
var meshUses = json.meshUses;
var nodeDef = json.nodes[ nodeIndex ];
return ( function () {
var pending = [];
if ( nodeDef.mesh !== undefined ) {
pending.push( parser.getDependency( 'mesh', nodeDef.mesh ).then( function ( mesh ) {
var node;
if ( meshReferences[ nodeDef.mesh ] > 1 ) {
var instanceNum = meshUses[ nodeDef.mesh ] ++;
node = mesh.clone();
node.name += '_instance_' + instanceNum;
} else {
node = mesh;
}
// if weights are provided on the node, override weights on the mesh.
if ( nodeDef.weights !== undefined ) {
node.traverse( function ( o ) {
if ( ! o.isMesh ) return;
for ( var i = 0, il = nodeDef.weights.length; i < il; i ++ ) {
o.morphTargetInfluences[ i ] = nodeDef.weights[ i ];
}
} );
}
return node;
} ) );
}
if ( nodeDef.camera !== undefined ) {
pending.push( parser.getDependency( 'camera', nodeDef.camera ) );
}
if ( nodeDef.extensions
&& nodeDef.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ]
&& nodeDef.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ].light !== undefined ) {
pending.push( parser.getDependency( 'light', nodeDef.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ].light ) );
}
return Promise.all( pending );
}() ).then( function ( objects ) {
var node;
// .isBone isn't in glTF spec. See .markDefs
if ( nodeDef.isBone === true ) {
node = new Bone();
} else if ( objects.length > 1 ) {
node = new Group();
} else if ( objects.length === 1 ) {
node = objects[ 0 ];
} else {
node = new Object3D();
}
if ( node !== objects[ 0 ] ) {
for ( var i = 0, il = objects.length; i < il; i ++ ) {
node.add( objects[ i ] );
}
}
if ( nodeDef.name ) {
node.userData.name = nodeDef.name;
node.name = PropertyBinding.sanitizeNodeName( nodeDef.name );
}
assignExtrasToUserData( node, nodeDef );
if ( nodeDef.extensions ) addUnknownExtensionsToUserData( extensions, node, nodeDef );
if ( nodeDef.matrix !== undefined ) {
var matrix = new Matrix4();
matrix.fromArray( nodeDef.matrix );
node.applyMatrix4( matrix );
} else {
if ( nodeDef.translation !== undefined ) {
node.position.fromArray( nodeDef.translation );
}
if ( nodeDef.rotation !== undefined ) {
node.quaternion.fromArray( nodeDef.rotation );
}
if ( nodeDef.scale !== undefined ) {
node.scale.fromArray( nodeDef.scale );
}
}
return node;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#scenes
* @param {number} sceneIndex
* @return {Promise<Group>}
*/
GLTFParser.prototype.loadScene = function () {
// scene node hierachy builder
function buildNodeHierachy( nodeId, parentObject, json, parser ) {
var nodeDef = json.nodes[ nodeId ];
return parser.getDependency( 'node', nodeId ).then( function ( node ) {
if ( nodeDef.skin === undefined ) return node;
// build skeleton here as well
var skinEntry;
return parser.getDependency( 'skin', nodeDef.skin ).then( function ( skin ) {
skinEntry = skin;
var pendingJoints = [];
for ( var i = 0, il = skinEntry.joints.length; i < il; i ++ ) {
pendingJoints.push( parser.getDependency( 'node', skinEntry.joints[ i ] ) );
}
return Promise.all( pendingJoints );
} ).then( function ( jointNodes ) {
node.traverse( function ( mesh ) {
if ( ! mesh.isMesh ) return;
var bones = [];
var boneInverses = [];
for ( var j = 0, jl = jointNodes.length; j < jl; j ++ ) {
var jointNode = jointNodes[ j ];
if ( jointNode ) {
bones.push( jointNode );
var mat = new Matrix4();
if ( skinEntry.inverseBindMatrices !== undefined ) {
mat.fromArray( skinEntry.inverseBindMatrices.array, j * 16 );
}
boneInverses.push( mat );
} else {
console.warn( 'THREE.GLTFLoader: Joint "%s" could not be found.', skinEntry.joints[ j ] );
}
}
mesh.bind( new Skeleton( bones, boneInverses ), mesh.matrixWorld );
} );
return node;
} );
} ).then( function ( node ) {
// build node hierachy
parentObject.add( node );
var pending = [];
if ( nodeDef.children ) {
var children = nodeDef.children;
for ( var i = 0, il = children.length; i < il; i ++ ) {
var child = children[ i ];
pending.push( buildNodeHierachy( child, node, json, parser ) );
}
}
return Promise.all( pending );
} );
}
return function loadScene( sceneIndex ) {
var json = this.json;
var extensions = this.extensions;
var sceneDef = this.json.scenes[ sceneIndex ];
var parser = this;
// Loader returns Group, not Scene.
// See: https://github.com/mrdoob/three.js/issues/18342#issuecomment-578981172
var scene = new Group();
if ( sceneDef.name ) scene.name = sceneDef.name;
assignExtrasToUserData( scene, sceneDef );
if ( sceneDef.extensions ) addUnknownExtensionsToUserData( extensions, scene, sceneDef );
var nodeIds = sceneDef.nodes || [];
var pending = [];
for ( var i = 0, il = nodeIds.length; i < il; i ++ ) {
pending.push( buildNodeHierachy( nodeIds[ i ], scene, json, parser ) );
}
return Promise.all( pending ).then( function () {
return scene;
} );
};
}();
return GLTFLoader;
} )()
Example #7
Source File: Water.js From canvas with Apache License 2.0 | 4 votes |
Water = function ( geometry, options ) {
Mesh.call( this, geometry );
var scope = this;
options = options || {};
var textureWidth = options.textureWidth !== undefined ? options.textureWidth : 512;
var textureHeight = options.textureHeight !== undefined ? options.textureHeight : 512;
var clipBias = options.clipBias !== undefined ? options.clipBias : 0.0;
var alpha = options.alpha !== undefined ? options.alpha : 1.0;
var time = options.time !== undefined ? options.time : 0.0;
var normalSampler = options.waterNormals !== undefined ? options.waterNormals : null;
var sunDirection = options.sunDirection !== undefined ? options.sunDirection : new Vector3( 0.70707, 0.70707, 0.0 );
var sunColor = new Color( options.sunColor !== undefined ? options.sunColor : 0xffffff );
var waterColor = new Color( options.waterColor !== undefined ? options.waterColor : 0x7F7F7F );
var eye = options.eye !== undefined ? options.eye : new Vector3( 0, 0, 0 );
var distortionScale = options.distortionScale !== undefined ? options.distortionScale : 20.0;
var side = options.side !== undefined ? options.side : FrontSide;
var fog = options.fog !== undefined ? options.fog : false;
//
var mirrorPlane = new Plane();
var normal = new Vector3();
var mirrorWorldPosition = new Vector3();
var cameraWorldPosition = new Vector3();
var rotationMatrix = new Matrix4();
var lookAtPosition = new Vector3( 0, 0, - 1 );
var clipPlane = new Vector4();
var view = new Vector3();
var target = new Vector3();
var q = new Vector4();
var textureMatrix = new Matrix4();
var mirrorCamera = new PerspectiveCamera();
var parameters = {
minFilter: LinearFilter,
magFilter: LinearFilter,
format: RGBFormat,
stencilBuffer: false
};
var renderTarget = new WebGLRenderTarget( textureWidth, textureHeight, parameters );
if ( ! MathUtils.isPowerOfTwo( textureWidth ) || ! MathUtils.isPowerOfTwo( textureHeight ) ) {
renderTarget.texture.generateMipmaps = false;
}
var mirrorShader = {
uniforms: UniformsUtils.merge( [
UniformsLib[ 'fog' ],
UniformsLib[ 'lights' ],
{
"normalSampler": { value: null },
"mirrorSampler": { value: null },
"alpha": { value: 1.0 },
"time": { value: 0.0 },
"size": { value: 1.0 },
"distortionScale": { value: 20.0 },
"textureMatrix": { value: new Matrix4() },
"sunColor": { value: new Color( 0x7F7F7F ) },
"sunDirection": { value: new Vector3( 0.70707, 0.70707, 0 ) },
"eye": { value: new Vector3() },
"waterColor": { value: new Color( 0x555555 ) }
}
] ),
vertexShader: [
'uniform mat4 textureMatrix;',
'uniform float time;',
'varying vec4 mirrorCoord;',
'varying vec4 worldPosition;',
'#include <common>',
'#include <fog_pars_vertex>',
'#include <shadowmap_pars_vertex>',
'#include <logdepthbuf_pars_vertex>',
'void main() {',
' mirrorCoord = modelMatrix * vec4( position, 1.0 );',
' worldPosition = mirrorCoord.xyzw;',
' mirrorCoord = textureMatrix * mirrorCoord;',
' vec4 mvPosition = modelViewMatrix * vec4( position, 1.0 );',
' gl_Position = projectionMatrix * mvPosition;',
'#include <logdepthbuf_vertex>',
'#include <fog_vertex>',
'#include <shadowmap_vertex>',
'}'
].join( '\n' ),
fragmentShader: [
'uniform sampler2D mirrorSampler;',
'uniform float alpha;',
'uniform float time;',
'uniform float size;',
'uniform float distortionScale;',
'uniform sampler2D normalSampler;',
'uniform vec3 sunColor;',
'uniform vec3 sunDirection;',
'uniform vec3 eye;',
'uniform vec3 waterColor;',
'varying vec4 mirrorCoord;',
'varying vec4 worldPosition;',
'vec4 getNoise( vec2 uv ) {',
' vec2 uv0 = ( uv / 103.0 ) + vec2(time / 17.0, time / 29.0);',
' vec2 uv1 = uv / 107.0-vec2( time / -19.0, time / 31.0 );',
' vec2 uv2 = uv / vec2( 8907.0, 9803.0 ) + vec2( time / 101.0, time / 97.0 );',
' vec2 uv3 = uv / vec2( 1091.0, 1027.0 ) - vec2( time / 109.0, time / -113.0 );',
' vec4 noise = texture2D( normalSampler, uv0 ) +',
' texture2D( normalSampler, uv1 ) +',
' texture2D( normalSampler, uv2 ) +',
' texture2D( normalSampler, uv3 );',
' return noise * 0.5 - 1.0;',
'}',
'void sunLight( const vec3 surfaceNormal, const vec3 eyeDirection, float shiny, float spec, float diffuse, inout vec3 diffuseColor, inout vec3 specularColor ) {',
' vec3 reflection = normalize( reflect( -sunDirection, surfaceNormal ) );',
' float direction = max( 0.0, dot( eyeDirection, reflection ) );',
' specularColor += pow( direction, shiny ) * sunColor * spec;',
' diffuseColor += max( dot( sunDirection, surfaceNormal ), 0.0 ) * sunColor * diffuse;',
'}',
'#include <common>',
'#include <packing>',
'#include <bsdfs>',
'#include <fog_pars_fragment>',
'#include <logdepthbuf_pars_fragment>',
'#include <lights_pars_begin>',
'#include <shadowmap_pars_fragment>',
'#include <shadowmask_pars_fragment>',
'void main() {',
'#include <logdepthbuf_fragment>',
' vec4 noise = getNoise( worldPosition.xz * size );',
' vec3 surfaceNormal = normalize( noise.xzy * vec3( 1.5, 1.0, 1.5 ) );',
' vec3 diffuseLight = vec3(0.0);',
' vec3 specularLight = vec3(0.0);',
' vec3 worldToEye = eye-worldPosition.xyz;',
' vec3 eyeDirection = normalize( worldToEye );',
' sunLight( surfaceNormal, eyeDirection, 100.0, 2.0, 0.5, diffuseLight, specularLight );',
' float distance = length(worldToEye);',
' vec2 distortion = surfaceNormal.xz * ( 0.001 + 1.0 / distance ) * distortionScale;',
' vec3 reflectionSample = vec3( texture2D( mirrorSampler, mirrorCoord.xy / mirrorCoord.w + distortion ) );',
' float theta = max( dot( eyeDirection, surfaceNormal ), 0.0 );',
' float rf0 = 0.3;',
' float reflectance = rf0 + ( 1.0 - rf0 ) * pow( ( 1.0 - theta ), 5.0 );',
' vec3 scatter = max( 0.0, dot( surfaceNormal, eyeDirection ) ) * waterColor;',
' vec3 albedo = mix( ( sunColor * diffuseLight * 0.3 + scatter ) * getShadowMask(), ( vec3( 0.1 ) + reflectionSample * 0.9 + reflectionSample * specularLight ), reflectance);',
' vec3 outgoingLight = albedo;',
' gl_FragColor = vec4( outgoingLight, alpha );',
'#include <tonemapping_fragment>',
'#include <fog_fragment>',
'}'
].join( '\n' )
};
var material = new ShaderMaterial( {
fragmentShader: mirrorShader.fragmentShader,
vertexShader: mirrorShader.vertexShader,
uniforms: UniformsUtils.clone( mirrorShader.uniforms ),
lights: true,
side: side,
fog: fog
} );
material.uniforms[ "mirrorSampler" ].value = renderTarget.texture;
material.uniforms[ "textureMatrix" ].value = textureMatrix;
material.uniforms[ "alpha" ].value = alpha;
material.uniforms[ "time" ].value = time;
material.uniforms[ "normalSampler" ].value = normalSampler;
material.uniforms[ "sunColor" ].value = sunColor;
material.uniforms[ "waterColor" ].value = waterColor;
material.uniforms[ "sunDirection" ].value = sunDirection;
material.uniforms[ "distortionScale" ].value = distortionScale;
material.uniforms[ "eye" ].value = eye;
scope.material = material;
scope.onBeforeRender = function ( renderer, scene, camera ) {
mirrorWorldPosition.setFromMatrixPosition( scope.matrixWorld );
cameraWorldPosition.setFromMatrixPosition( camera.matrixWorld );
rotationMatrix.extractRotation( scope.matrixWorld );
normal.set( 0, 0, 1 );
normal.applyMatrix4( rotationMatrix );
view.subVectors( mirrorWorldPosition, cameraWorldPosition );
// Avoid rendering when mirror is facing away
if ( view.dot( normal ) > 0 ) return;
view.reflect( normal ).negate();
view.add( mirrorWorldPosition );
rotationMatrix.extractRotation( camera.matrixWorld );
lookAtPosition.set( 0, 0, - 1 );
lookAtPosition.applyMatrix4( rotationMatrix );
lookAtPosition.add( cameraWorldPosition );
target.subVectors( mirrorWorldPosition, lookAtPosition );
target.reflect( normal ).negate();
target.add( mirrorWorldPosition );
mirrorCamera.position.copy( view );
mirrorCamera.up.set( 0, 1, 0 );
mirrorCamera.up.applyMatrix4( rotationMatrix );
mirrorCamera.up.reflect( normal );
mirrorCamera.lookAt( target );
mirrorCamera.far = camera.far; // Used in WebGLBackground
mirrorCamera.updateMatrixWorld();
mirrorCamera.projectionMatrix.copy( camera.projectionMatrix );
// Update the texture matrix
textureMatrix.set(
0.5, 0.0, 0.0, 0.5,
0.0, 0.5, 0.0, 0.5,
0.0, 0.0, 0.5, 0.5,
0.0, 0.0, 0.0, 1.0
);
textureMatrix.multiply( mirrorCamera.projectionMatrix );
textureMatrix.multiply( mirrorCamera.matrixWorldInverse );
// Now update projection matrix with new clip plane, implementing code from: http://www.terathon.com/code/oblique.html
// Paper explaining this technique: http://www.terathon.com/lengyel/Lengyel-Oblique.pdf
mirrorPlane.setFromNormalAndCoplanarPoint( normal, mirrorWorldPosition );
mirrorPlane.applyMatrix4( mirrorCamera.matrixWorldInverse );
clipPlane.set( mirrorPlane.normal.x, mirrorPlane.normal.y, mirrorPlane.normal.z, mirrorPlane.constant );
var projectionMatrix = mirrorCamera.projectionMatrix;
q.x = ( Math.sign( clipPlane.x ) + projectionMatrix.elements[ 8 ] ) / projectionMatrix.elements[ 0 ];
q.y = ( Math.sign( clipPlane.y ) + projectionMatrix.elements[ 9 ] ) / projectionMatrix.elements[ 5 ];
q.z = - 1.0;
q.w = ( 1.0 + projectionMatrix.elements[ 10 ] ) / projectionMatrix.elements[ 14 ];
// Calculate the scaled plane vector
clipPlane.multiplyScalar( 2.0 / clipPlane.dot( q ) );
// Replacing the third row of the projection matrix
projectionMatrix.elements[ 2 ] = clipPlane.x;
projectionMatrix.elements[ 6 ] = clipPlane.y;
projectionMatrix.elements[ 10 ] = clipPlane.z + 1.0 - clipBias;
projectionMatrix.elements[ 14 ] = clipPlane.w;
eye.setFromMatrixPosition( camera.matrixWorld );
//
var currentRenderTarget = renderer.getRenderTarget();
var currentXrEnabled = renderer.xr.enabled;
var currentShadowAutoUpdate = renderer.shadowMap.autoUpdate;
scope.visible = false;
renderer.xr.enabled = false; // Avoid camera modification and recursion
renderer.shadowMap.autoUpdate = false; // Avoid re-computing shadows
renderer.setRenderTarget( renderTarget );
renderer.state.buffers.depth.setMask( true ); // make sure the depth buffer is writable so it can be properly cleared, see #18897
if ( renderer.autoClear === false ) renderer.clear();
renderer.render( scene, mirrorCamera );
scope.visible = true;
renderer.xr.enabled = currentXrEnabled;
renderer.shadowMap.autoUpdate = currentShadowAutoUpdate;
renderer.setRenderTarget( currentRenderTarget );
// Restore viewport
var viewport = camera.viewport;
if ( viewport !== undefined ) {
renderer.state.viewport( viewport );
}
};
}
Example #8
Source File: GLTFLoader.js From FirstPersonCameraControl with MIT License | 4 votes |
GLTFLoader = ( function () {
function GLTFLoader( manager ) {
Loader.call( this, manager );
this.dracoLoader = null;
this.ddsLoader = null;
}
GLTFLoader.prototype = Object.assign( Object.create( Loader.prototype ), {
constructor: GLTFLoader,
load: function ( url, onLoad, onProgress, onError ) {
var scope = this;
var resourcePath;
if ( this.resourcePath !== '' ) {
resourcePath = this.resourcePath;
} else if ( this.path !== '' ) {
resourcePath = this.path;
} else {
resourcePath = LoaderUtils.extractUrlBase( url );
}
// Tells the LoadingManager to track an extra item, which resolves after
// the model is fully loaded. This means the count of items loaded will
// be incorrect, but ensures manager.onLoad() does not fire early.
scope.manager.itemStart( url );
var _onError = function ( e ) {
if ( onError ) {
onError( e );
} else {
console.error( e );
}
scope.manager.itemError( url );
scope.manager.itemEnd( url );
};
var loader = new FileLoader( scope.manager );
loader.setPath( this.path );
loader.setResponseType( 'arraybuffer' );
if ( scope.crossOrigin === 'use-credentials' ) {
loader.setWithCredentials( true );
}
loader.load( url, function ( data ) {
try {
scope.parse( data, resourcePath, function ( gltf ) {
onLoad( gltf );
scope.manager.itemEnd( url );
}, _onError );
} catch ( e ) {
_onError( e );
}
}, onProgress, _onError );
},
setDRACOLoader: function ( dracoLoader ) {
this.dracoLoader = dracoLoader;
return this;
},
setDDSLoader: function ( ddsLoader ) {
this.ddsLoader = ddsLoader;
return this;
},
parse: function ( data, path, onLoad, onError ) {
var content;
var extensions = {};
if ( typeof data === 'string' ) {
content = data;
} else {
var magic = LoaderUtils.decodeText( new Uint8Array( data, 0, 4 ) );
if ( magic === BINARY_EXTENSION_HEADER_MAGIC ) {
try {
extensions[ EXTENSIONS.KHR_BINARY_GLTF ] = new GLTFBinaryExtension( data );
} catch ( error ) {
if ( onError ) onError( error );
return;
}
content = extensions[ EXTENSIONS.KHR_BINARY_GLTF ].content;
} else {
content = LoaderUtils.decodeText( new Uint8Array( data ) );
}
}
var json = JSON.parse( content );
if ( json.asset === undefined || json.asset.version[ 0 ] < 2 ) {
if ( onError ) onError( new Error( 'THREE.GLTFLoader: Unsupported asset. glTF versions >=2.0 are supported.' ) );
return;
}
if ( json.extensionsUsed ) {
for ( var i = 0; i < json.extensionsUsed.length; ++ i ) {
var extensionName = json.extensionsUsed[ i ];
var extensionsRequired = json.extensionsRequired || [];
switch ( extensionName ) {
case EXTENSIONS.KHR_LIGHTS_PUNCTUAL:
extensions[ extensionName ] = new GLTFLightsExtension( json );
break;
case EXTENSIONS.KHR_MATERIALS_CLEARCOAT:
extensions[ extensionName ] = new GLTFMaterialsClearcoatExtension();
break;
case EXTENSIONS.KHR_MATERIALS_UNLIT:
extensions[ extensionName ] = new GLTFMaterialsUnlitExtension();
break;
case EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS:
extensions[ extensionName ] = new GLTFMaterialsPbrSpecularGlossinessExtension();
break;
case EXTENSIONS.KHR_DRACO_MESH_COMPRESSION:
extensions[ extensionName ] = new GLTFDracoMeshCompressionExtension( json, this.dracoLoader );
break;
case EXTENSIONS.MSFT_TEXTURE_DDS:
extensions[ extensionName ] = new GLTFTextureDDSExtension( this.ddsLoader );
break;
case EXTENSIONS.KHR_TEXTURE_TRANSFORM:
extensions[ extensionName ] = new GLTFTextureTransformExtension();
break;
case EXTENSIONS.KHR_MESH_QUANTIZATION:
extensions[ extensionName ] = new GLTFMeshQuantizationExtension();
break;
default:
if ( extensionsRequired.indexOf( extensionName ) >= 0 ) {
console.warn( 'THREE.GLTFLoader: Unknown extension "' + extensionName + '".' );
}
}
}
}
var parser = new GLTFParser( json, extensions, {
path: path || this.resourcePath || '',
crossOrigin: this.crossOrigin,
manager: this.manager
} );
parser.parse( onLoad, onError );
}
} );
/* GLTFREGISTRY */
function GLTFRegistry() {
var objects = {};
return {
get: function ( key ) {
return objects[ key ];
},
add: function ( key, object ) {
objects[ key ] = object;
},
remove: function ( key ) {
delete objects[ key ];
},
removeAll: function () {
objects = {};
}
};
}
/*********************************/
/********** EXTENSIONS ***********/
/*********************************/
var EXTENSIONS = {
KHR_BINARY_GLTF: 'KHR_binary_glTF',
KHR_DRACO_MESH_COMPRESSION: 'KHR_draco_mesh_compression',
KHR_LIGHTS_PUNCTUAL: 'KHR_lights_punctual',
KHR_MATERIALS_CLEARCOAT: 'KHR_materials_clearcoat',
KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS: 'KHR_materials_pbrSpecularGlossiness',
KHR_MATERIALS_UNLIT: 'KHR_materials_unlit',
KHR_TEXTURE_TRANSFORM: 'KHR_texture_transform',
KHR_MESH_QUANTIZATION: 'KHR_mesh_quantization',
MSFT_TEXTURE_DDS: 'MSFT_texture_dds'
};
/**
* DDS Texture Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Vendor/MSFT_texture_dds
*
*/
function GLTFTextureDDSExtension( ddsLoader ) {
if ( ! ddsLoader ) {
throw new Error( 'THREE.GLTFLoader: Attempting to load .dds texture without importing DDSLoader' );
}
this.name = EXTENSIONS.MSFT_TEXTURE_DDS;
this.ddsLoader = ddsLoader;
}
/**
* Punctual Lights Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_lights_punctual
*/
function GLTFLightsExtension( json ) {
this.name = EXTENSIONS.KHR_LIGHTS_PUNCTUAL;
var extension = ( json.extensions && json.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ] ) || {};
this.lightDefs = extension.lights || [];
}
GLTFLightsExtension.prototype.loadLight = function ( lightIndex ) {
var lightDef = this.lightDefs[ lightIndex ];
var lightNode;
var color = new Color( 0xffffff );
if ( lightDef.color !== undefined ) color.fromArray( lightDef.color );
var range = lightDef.range !== undefined ? lightDef.range : 0;
switch ( lightDef.type ) {
case 'directional':
lightNode = new DirectionalLight( color );
lightNode.target.position.set( 0, 0, - 1 );
lightNode.add( lightNode.target );
break;
case 'point':
lightNode = new PointLight( color );
lightNode.distance = range;
break;
case 'spot':
lightNode = new SpotLight( color );
lightNode.distance = range;
// Handle spotlight properties.
lightDef.spot = lightDef.spot || {};
lightDef.spot.innerConeAngle = lightDef.spot.innerConeAngle !== undefined ? lightDef.spot.innerConeAngle : 0;
lightDef.spot.outerConeAngle = lightDef.spot.outerConeAngle !== undefined ? lightDef.spot.outerConeAngle : Math.PI / 4.0;
lightNode.angle = lightDef.spot.outerConeAngle;
lightNode.penumbra = 1.0 - lightDef.spot.innerConeAngle / lightDef.spot.outerConeAngle;
lightNode.target.position.set( 0, 0, - 1 );
lightNode.add( lightNode.target );
break;
default:
throw new Error( 'THREE.GLTFLoader: Unexpected light type, "' + lightDef.type + '".' );
}
// Some lights (e.g. spot) default to a position other than the origin. Reset the position
// here, because node-level parsing will only override position if explicitly specified.
lightNode.position.set( 0, 0, 0 );
lightNode.decay = 2;
if ( lightDef.intensity !== undefined ) lightNode.intensity = lightDef.intensity;
lightNode.name = lightDef.name || ( 'light_' + lightIndex );
return Promise.resolve( lightNode );
};
/**
* Unlit Materials Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_materials_unlit
*/
function GLTFMaterialsUnlitExtension() {
this.name = EXTENSIONS.KHR_MATERIALS_UNLIT;
}
GLTFMaterialsUnlitExtension.prototype.getMaterialType = function () {
return MeshBasicMaterial;
};
GLTFMaterialsUnlitExtension.prototype.extendParams = function ( materialParams, materialDef, parser ) {
var pending = [];
materialParams.color = new Color( 1.0, 1.0, 1.0 );
materialParams.opacity = 1.0;
var metallicRoughness = materialDef.pbrMetallicRoughness;
if ( metallicRoughness ) {
if ( Array.isArray( metallicRoughness.baseColorFactor ) ) {
var array = metallicRoughness.baseColorFactor;
materialParams.color.fromArray( array );
materialParams.opacity = array[ 3 ];
}
if ( metallicRoughness.baseColorTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'map', metallicRoughness.baseColorTexture ) );
}
}
return Promise.all( pending );
};
/**
* Clearcoat Materials Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_materials_clearcoat
*/
function GLTFMaterialsClearcoatExtension() {
this.name = EXTENSIONS.KHR_MATERIALS_CLEARCOAT;
}
GLTFMaterialsClearcoatExtension.prototype.getMaterialType = function () {
return MeshPhysicalMaterial;
};
GLTFMaterialsClearcoatExtension.prototype.extendParams = function ( materialParams, materialDef, parser ) {
var pending = [];
var extension = materialDef.extensions[ this.name ];
if ( extension.clearcoatFactor !== undefined ) {
materialParams.clearcoat = extension.clearcoatFactor;
}
if ( extension.clearcoatTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'clearcoatMap', extension.clearcoatTexture ) );
}
if ( extension.clearcoatRoughnessFactor !== undefined ) {
materialParams.clearcoatRoughness = extension.clearcoatRoughnessFactor;
}
if ( extension.clearcoatRoughnessTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'clearcoatRoughnessMap', extension.clearcoatRoughnessTexture ) );
}
if ( extension.clearcoatNormalTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'clearcoatNormalMap', extension.clearcoatNormalTexture ) );
if ( extension.clearcoatNormalTexture.scale !== undefined ) {
var scale = extension.clearcoatNormalTexture.scale;
materialParams.clearcoatNormalScale = new Vector2( scale, scale );
}
}
return Promise.all( pending );
};
/* BINARY EXTENSION */
var BINARY_EXTENSION_HEADER_MAGIC = 'glTF';
var BINARY_EXTENSION_HEADER_LENGTH = 12;
var BINARY_EXTENSION_CHUNK_TYPES = { JSON: 0x4E4F534A, BIN: 0x004E4942 };
function GLTFBinaryExtension( data ) {
this.name = EXTENSIONS.KHR_BINARY_GLTF;
this.content = null;
this.body = null;
var headerView = new DataView( data, 0, BINARY_EXTENSION_HEADER_LENGTH );
this.header = {
magic: LoaderUtils.decodeText( new Uint8Array( data.slice( 0, 4 ) ) ),
version: headerView.getUint32( 4, true ),
length: headerView.getUint32( 8, true )
};
if ( this.header.magic !== BINARY_EXTENSION_HEADER_MAGIC ) {
throw new Error( 'THREE.GLTFLoader: Unsupported glTF-Binary header.' );
} else if ( this.header.version < 2.0 ) {
throw new Error( 'THREE.GLTFLoader: Legacy binary file detected.' );
}
var chunkView = new DataView( data, BINARY_EXTENSION_HEADER_LENGTH );
var chunkIndex = 0;
while ( chunkIndex < chunkView.byteLength ) {
var chunkLength = chunkView.getUint32( chunkIndex, true );
chunkIndex += 4;
var chunkType = chunkView.getUint32( chunkIndex, true );
chunkIndex += 4;
if ( chunkType === BINARY_EXTENSION_CHUNK_TYPES.JSON ) {
var contentArray = new Uint8Array( data, BINARY_EXTENSION_HEADER_LENGTH + chunkIndex, chunkLength );
this.content = LoaderUtils.decodeText( contentArray );
} else if ( chunkType === BINARY_EXTENSION_CHUNK_TYPES.BIN ) {
var byteOffset = BINARY_EXTENSION_HEADER_LENGTH + chunkIndex;
this.body = data.slice( byteOffset, byteOffset + chunkLength );
}
// Clients must ignore chunks with unknown types.
chunkIndex += chunkLength;
}
if ( this.content === null ) {
throw new Error( 'THREE.GLTFLoader: JSON content not found.' );
}
}
/**
* DRACO Mesh Compression Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_draco_mesh_compression
*/
function GLTFDracoMeshCompressionExtension( json, dracoLoader ) {
if ( ! dracoLoader ) {
throw new Error( 'THREE.GLTFLoader: No DRACOLoader instance provided.' );
}
this.name = EXTENSIONS.KHR_DRACO_MESH_COMPRESSION;
this.json = json;
this.dracoLoader = dracoLoader;
this.dracoLoader.preload();
}
GLTFDracoMeshCompressionExtension.prototype.decodePrimitive = function ( primitive, parser ) {
var json = this.json;
var dracoLoader = this.dracoLoader;
var bufferViewIndex = primitive.extensions[ this.name ].bufferView;
var gltfAttributeMap = primitive.extensions[ this.name ].attributes;
var threeAttributeMap = {};
var attributeNormalizedMap = {};
var attributeTypeMap = {};
for ( var attributeName in gltfAttributeMap ) {
var threeAttributeName = ATTRIBUTES[ attributeName ] || attributeName.toLowerCase();
threeAttributeMap[ threeAttributeName ] = gltfAttributeMap[ attributeName ];
}
for ( attributeName in primitive.attributes ) {
var threeAttributeName = ATTRIBUTES[ attributeName ] || attributeName.toLowerCase();
if ( gltfAttributeMap[ attributeName ] !== undefined ) {
var accessorDef = json.accessors[ primitive.attributes[ attributeName ] ];
var componentType = WEBGL_COMPONENT_TYPES[ accessorDef.componentType ];
attributeTypeMap[ threeAttributeName ] = componentType;
attributeNormalizedMap[ threeAttributeName ] = accessorDef.normalized === true;
}
}
return parser.getDependency( 'bufferView', bufferViewIndex ).then( function ( bufferView ) {
return new Promise( function ( resolve ) {
dracoLoader.decodeDracoFile( bufferView, function ( geometry ) {
for ( var attributeName in geometry.attributes ) {
var attribute = geometry.attributes[ attributeName ];
var normalized = attributeNormalizedMap[ attributeName ];
if ( normalized !== undefined ) attribute.normalized = normalized;
}
resolve( geometry );
}, threeAttributeMap, attributeTypeMap );
} );
} );
};
/**
* Texture Transform Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_texture_transform
*/
function GLTFTextureTransformExtension() {
this.name = EXTENSIONS.KHR_TEXTURE_TRANSFORM;
}
GLTFTextureTransformExtension.prototype.extendTexture = function ( texture, transform ) {
texture = texture.clone();
if ( transform.offset !== undefined ) {
texture.offset.fromArray( transform.offset );
}
if ( transform.rotation !== undefined ) {
texture.rotation = transform.rotation;
}
if ( transform.scale !== undefined ) {
texture.repeat.fromArray( transform.scale );
}
if ( transform.texCoord !== undefined ) {
console.warn( 'THREE.GLTFLoader: Custom UV sets in "' + this.name + '" extension not yet supported.' );
}
texture.needsUpdate = true;
return texture;
};
/**
* Specular-Glossiness Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_materials_pbrSpecularGlossiness
*/
/**
* A sub class of StandardMaterial with some of the functionality
* changed via the `onBeforeCompile` callback
* @pailhead
*/
function GLTFMeshStandardSGMaterial( params ) {
MeshStandardMaterial.call( this );
this.isGLTFSpecularGlossinessMaterial = true;
//various chunks that need replacing
var specularMapParsFragmentChunk = [
'#ifdef USE_SPECULARMAP',
' uniform sampler2D specularMap;',
'#endif'
].join( '\n' );
var glossinessMapParsFragmentChunk = [
'#ifdef USE_GLOSSINESSMAP',
' uniform sampler2D glossinessMap;',
'#endif'
].join( '\n' );
var specularMapFragmentChunk = [
'vec3 specularFactor = specular;',
'#ifdef USE_SPECULARMAP',
' vec4 texelSpecular = texture2D( specularMap, vUv );',
' texelSpecular = sRGBToLinear( texelSpecular );',
' // reads channel RGB, compatible with a glTF Specular-Glossiness (RGBA) texture',
' specularFactor *= texelSpecular.rgb;',
'#endif'
].join( '\n' );
var glossinessMapFragmentChunk = [
'float glossinessFactor = glossiness;',
'#ifdef USE_GLOSSINESSMAP',
' vec4 texelGlossiness = texture2D( glossinessMap, vUv );',
' // reads channel A, compatible with a glTF Specular-Glossiness (RGBA) texture',
' glossinessFactor *= texelGlossiness.a;',
'#endif'
].join( '\n' );
var lightPhysicalFragmentChunk = [
'PhysicalMaterial material;',
'material.diffuseColor = diffuseColor.rgb;',
'vec3 dxy = max( abs( dFdx( geometryNormal ) ), abs( dFdy( geometryNormal ) ) );',
'float geometryRoughness = max( max( dxy.x, dxy.y ), dxy.z );',
'material.specularRoughness = max( 1.0 - glossinessFactor, 0.0525 );// 0.0525 corresponds to the base mip of a 256 cubemap.',
'material.specularRoughness += geometryRoughness;',
'material.specularRoughness = min( material.specularRoughness, 1.0 );',
'material.specularColor = specularFactor.rgb;',
].join( '\n' );
var uniforms = {
specular: { value: new Color().setHex( 0xffffff ) },
glossiness: { value: 1 },
specularMap: { value: null },
glossinessMap: { value: null }
};
this._extraUniforms = uniforms;
// please see #14031 or #13198 for an alternate approach
this.onBeforeCompile = function ( shader ) {
for ( var uniformName in uniforms ) {
shader.uniforms[ uniformName ] = uniforms[ uniformName ];
}
shader.fragmentShader = shader.fragmentShader.replace( 'uniform float roughness;', 'uniform vec3 specular;' );
shader.fragmentShader = shader.fragmentShader.replace( 'uniform float metalness;', 'uniform float glossiness;' );
shader.fragmentShader = shader.fragmentShader.replace( '#include <roughnessmap_pars_fragment>', specularMapParsFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <metalnessmap_pars_fragment>', glossinessMapParsFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <roughnessmap_fragment>', specularMapFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <metalnessmap_fragment>', glossinessMapFragmentChunk );
shader.fragmentShader = shader.fragmentShader.replace( '#include <lights_physical_fragment>', lightPhysicalFragmentChunk );
};
/*eslint-disable*/
Object.defineProperties(
this,
{
specular: {
get: function () { return uniforms.specular.value; },
set: function ( v ) { uniforms.specular.value = v; }
},
specularMap: {
get: function () { return uniforms.specularMap.value; },
set: function ( v ) { uniforms.specularMap.value = v; }
},
glossiness: {
get: function () { return uniforms.glossiness.value; },
set: function ( v ) { uniforms.glossiness.value = v; }
},
glossinessMap: {
get: function () { return uniforms.glossinessMap.value; },
set: function ( v ) {
uniforms.glossinessMap.value = v;
//how about something like this - @pailhead
if ( v ) {
this.defines.USE_GLOSSINESSMAP = '';
// set USE_ROUGHNESSMAP to enable vUv
this.defines.USE_ROUGHNESSMAP = '';
} else {
delete this.defines.USE_ROUGHNESSMAP;
delete this.defines.USE_GLOSSINESSMAP;
}
}
}
}
);
/*eslint-enable*/
delete this.metalness;
delete this.roughness;
delete this.metalnessMap;
delete this.roughnessMap;
this.setValues( params );
}
GLTFMeshStandardSGMaterial.prototype = Object.create( MeshStandardMaterial.prototype );
GLTFMeshStandardSGMaterial.prototype.constructor = GLTFMeshStandardSGMaterial;
GLTFMeshStandardSGMaterial.prototype.copy = function ( source ) {
MeshStandardMaterial.prototype.copy.call( this, source );
this.specularMap = source.specularMap;
this.specular.copy( source.specular );
this.glossinessMap = source.glossinessMap;
this.glossiness = source.glossiness;
delete this.metalness;
delete this.roughness;
delete this.metalnessMap;
delete this.roughnessMap;
return this;
};
function GLTFMaterialsPbrSpecularGlossinessExtension() {
return {
name: EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS,
specularGlossinessParams: [
'color',
'map',
'lightMap',
'lightMapIntensity',
'aoMap',
'aoMapIntensity',
'emissive',
'emissiveIntensity',
'emissiveMap',
'bumpMap',
'bumpScale',
'normalMap',
'normalMapType',
'displacementMap',
'displacementScale',
'displacementBias',
'specularMap',
'specular',
'glossinessMap',
'glossiness',
'alphaMap',
'envMap',
'envMapIntensity',
'refractionRatio',
],
getMaterialType: function () {
return GLTFMeshStandardSGMaterial;
},
extendParams: function ( materialParams, materialDef, parser ) {
var pbrSpecularGlossiness = materialDef.extensions[ this.name ];
materialParams.color = new Color( 1.0, 1.0, 1.0 );
materialParams.opacity = 1.0;
var pending = [];
if ( Array.isArray( pbrSpecularGlossiness.diffuseFactor ) ) {
var array = pbrSpecularGlossiness.diffuseFactor;
materialParams.color.fromArray( array );
materialParams.opacity = array[ 3 ];
}
if ( pbrSpecularGlossiness.diffuseTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'map', pbrSpecularGlossiness.diffuseTexture ) );
}
materialParams.emissive = new Color( 0.0, 0.0, 0.0 );
materialParams.glossiness = pbrSpecularGlossiness.glossinessFactor !== undefined ? pbrSpecularGlossiness.glossinessFactor : 1.0;
materialParams.specular = new Color( 1.0, 1.0, 1.0 );
if ( Array.isArray( pbrSpecularGlossiness.specularFactor ) ) {
materialParams.specular.fromArray( pbrSpecularGlossiness.specularFactor );
}
if ( pbrSpecularGlossiness.specularGlossinessTexture !== undefined ) {
var specGlossMapDef = pbrSpecularGlossiness.specularGlossinessTexture;
pending.push( parser.assignTexture( materialParams, 'glossinessMap', specGlossMapDef ) );
pending.push( parser.assignTexture( materialParams, 'specularMap', specGlossMapDef ) );
}
return Promise.all( pending );
},
createMaterial: function ( materialParams ) {
var material = new GLTFMeshStandardSGMaterial( materialParams );
material.fog = true;
material.color = materialParams.color;
material.map = materialParams.map === undefined ? null : materialParams.map;
material.lightMap = null;
material.lightMapIntensity = 1.0;
material.aoMap = materialParams.aoMap === undefined ? null : materialParams.aoMap;
material.aoMapIntensity = 1.0;
material.emissive = materialParams.emissive;
material.emissiveIntensity = 1.0;
material.emissiveMap = materialParams.emissiveMap === undefined ? null : materialParams.emissiveMap;
material.bumpMap = materialParams.bumpMap === undefined ? null : materialParams.bumpMap;
material.bumpScale = 1;
material.normalMap = materialParams.normalMap === undefined ? null : materialParams.normalMap;
material.normalMapType = TangentSpaceNormalMap;
if ( materialParams.normalScale ) material.normalScale = materialParams.normalScale;
material.displacementMap = null;
material.displacementScale = 1;
material.displacementBias = 0;
material.specularMap = materialParams.specularMap === undefined ? null : materialParams.specularMap;
material.specular = materialParams.specular;
material.glossinessMap = materialParams.glossinessMap === undefined ? null : materialParams.glossinessMap;
material.glossiness = materialParams.glossiness;
material.alphaMap = null;
material.envMap = materialParams.envMap === undefined ? null : materialParams.envMap;
material.envMapIntensity = 1.0;
material.refractionRatio = 0.98;
return material;
},
};
}
/**
* Mesh Quantization Extension
*
* Specification: https://github.com/KhronosGroup/glTF/tree/master/extensions/2.0/Khronos/KHR_mesh_quantization
*/
function GLTFMeshQuantizationExtension() {
this.name = EXTENSIONS.KHR_MESH_QUANTIZATION;
}
/*********************************/
/********** INTERPOLATION ********/
/*********************************/
// Spline Interpolation
// Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#appendix-c-spline-interpolation
function GLTFCubicSplineInterpolant( parameterPositions, sampleValues, sampleSize, resultBuffer ) {
Interpolant.call( this, parameterPositions, sampleValues, sampleSize, resultBuffer );
}
GLTFCubicSplineInterpolant.prototype = Object.create( Interpolant.prototype );
GLTFCubicSplineInterpolant.prototype.constructor = GLTFCubicSplineInterpolant;
GLTFCubicSplineInterpolant.prototype.copySampleValue_ = function ( index ) {
// Copies a sample value to the result buffer. See description of glTF
// CUBICSPLINE values layout in interpolate_() function below.
var result = this.resultBuffer,
values = this.sampleValues,
valueSize = this.valueSize,
offset = index * valueSize * 3 + valueSize;
for ( var i = 0; i !== valueSize; i ++ ) {
result[ i ] = values[ offset + i ];
}
return result;
};
GLTFCubicSplineInterpolant.prototype.beforeStart_ = GLTFCubicSplineInterpolant.prototype.copySampleValue_;
GLTFCubicSplineInterpolant.prototype.afterEnd_ = GLTFCubicSplineInterpolant.prototype.copySampleValue_;
GLTFCubicSplineInterpolant.prototype.interpolate_ = function ( i1, t0, t, t1 ) {
var result = this.resultBuffer;
var values = this.sampleValues;
var stride = this.valueSize;
var stride2 = stride * 2;
var stride3 = stride * 3;
var td = t1 - t0;
var p = ( t - t0 ) / td;
var pp = p * p;
var ppp = pp * p;
var offset1 = i1 * stride3;
var offset0 = offset1 - stride3;
var s2 = - 2 * ppp + 3 * pp;
var s3 = ppp - pp;
var s0 = 1 - s2;
var s1 = s3 - pp + p;
// Layout of keyframe output values for CUBICSPLINE animations:
// [ inTangent_1, splineVertex_1, outTangent_1, inTangent_2, splineVertex_2, ... ]
for ( var i = 0; i !== stride; i ++ ) {
var p0 = values[ offset0 + i + stride ]; // splineVertex_k
var m0 = values[ offset0 + i + stride2 ] * td; // outTangent_k * (t_k+1 - t_k)
var p1 = values[ offset1 + i + stride ]; // splineVertex_k+1
var m1 = values[ offset1 + i ] * td; // inTangent_k+1 * (t_k+1 - t_k)
result[ i ] = s0 * p0 + s1 * m0 + s2 * p1 + s3 * m1;
}
return result;
};
/*********************************/
/********** INTERNALS ************/
/*********************************/
/* CONSTANTS */
var WEBGL_CONSTANTS = {
FLOAT: 5126,
//FLOAT_MAT2: 35674,
FLOAT_MAT3: 35675,
FLOAT_MAT4: 35676,
FLOAT_VEC2: 35664,
FLOAT_VEC3: 35665,
FLOAT_VEC4: 35666,
LINEAR: 9729,
REPEAT: 10497,
SAMPLER_2D: 35678,
POINTS: 0,
LINES: 1,
LINE_LOOP: 2,
LINE_STRIP: 3,
TRIANGLES: 4,
TRIANGLE_STRIP: 5,
TRIANGLE_FAN: 6,
UNSIGNED_BYTE: 5121,
UNSIGNED_SHORT: 5123
};
var WEBGL_COMPONENT_TYPES = {
5120: Int8Array,
5121: Uint8Array,
5122: Int16Array,
5123: Uint16Array,
5125: Uint32Array,
5126: Float32Array
};
var WEBGL_FILTERS = {
9728: NearestFilter,
9729: LinearFilter,
9984: NearestMipmapNearestFilter,
9985: LinearMipmapNearestFilter,
9986: NearestMipmapLinearFilter,
9987: LinearMipmapLinearFilter
};
var WEBGL_WRAPPINGS = {
33071: ClampToEdgeWrapping,
33648: MirroredRepeatWrapping,
10497: RepeatWrapping
};
var WEBGL_TYPE_SIZES = {
'SCALAR': 1,
'VEC2': 2,
'VEC3': 3,
'VEC4': 4,
'MAT2': 4,
'MAT3': 9,
'MAT4': 16
};
var ATTRIBUTES = {
POSITION: 'position',
NORMAL: 'normal',
TANGENT: 'tangent',
TEXCOORD_0: 'uv',
TEXCOORD_1: 'uv2',
COLOR_0: 'color',
WEIGHTS_0: 'skinWeight',
JOINTS_0: 'skinIndex',
};
var PATH_PROPERTIES = {
scale: 'scale',
translation: 'position',
rotation: 'quaternion',
weights: 'morphTargetInfluences'
};
var INTERPOLATION = {
CUBICSPLINE: undefined, // We use a custom interpolant (GLTFCubicSplineInterpolation) for CUBICSPLINE tracks. Each
// keyframe track will be initialized with a default interpolation type, then modified.
LINEAR: InterpolateLinear,
STEP: InterpolateDiscrete
};
var ALPHA_MODES = {
OPAQUE: 'OPAQUE',
MASK: 'MASK',
BLEND: 'BLEND'
};
var MIME_TYPE_FORMATS = {
'image/png': RGBAFormat,
'image/jpeg': RGBFormat
};
/* UTILITY FUNCTIONS */
function resolveURL( url, path ) {
// Invalid URL
if ( typeof url !== 'string' || url === '' ) return '';
// Host Relative URL
if ( /^https?:\/\//i.test( path ) && /^\//.test( url ) ) {
path = path.replace( /(^https?:\/\/[^\/]+).*/i, '$1' );
}
// Absolute URL http://,https://,//
if ( /^(https?:)?\/\//i.test( url ) ) return url;
// Data URI
if ( /^data:.*,.*$/i.test( url ) ) return url;
// Blob URL
if ( /^blob:.*$/i.test( url ) ) return url;
// Relative URL
return path + url;
}
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#default-material
*/
function createDefaultMaterial( cache ) {
if ( cache[ 'DefaultMaterial' ] === undefined ) {
cache[ 'DefaultMaterial' ] = new MeshStandardMaterial( {
color: 0xFFFFFF,
emissive: 0x000000,
metalness: 1,
roughness: 1,
transparent: false,
depthTest: true,
side: FrontSide
} );
}
return cache[ 'DefaultMaterial' ];
}
function addUnknownExtensionsToUserData( knownExtensions, object, objectDef ) {
// Add unknown glTF extensions to an object's userData.
for ( var name in objectDef.extensions ) {
if ( knownExtensions[ name ] === undefined ) {
object.userData.gltfExtensions = object.userData.gltfExtensions || {};
object.userData.gltfExtensions[ name ] = objectDef.extensions[ name ];
}
}
}
/**
* @param {Object3D|Material|BufferGeometry} object
* @param {GLTF.definition} gltfDef
*/
function assignExtrasToUserData( object, gltfDef ) {
if ( gltfDef.extras !== undefined ) {
if ( typeof gltfDef.extras === 'object' ) {
Object.assign( object.userData, gltfDef.extras );
} else {
console.warn( 'THREE.GLTFLoader: Ignoring primitive type .extras, ' + gltfDef.extras );
}
}
}
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#morph-targets
*
* @param {BufferGeometry} geometry
* @param {Array<GLTF.Target>} targets
* @param {GLTFParser} parser
* @return {Promise<BufferGeometry>}
*/
function addMorphTargets( geometry, targets, parser ) {
var hasMorphPosition = false;
var hasMorphNormal = false;
for ( var i = 0, il = targets.length; i < il; i ++ ) {
var target = targets[ i ];
if ( target.POSITION !== undefined ) hasMorphPosition = true;
if ( target.NORMAL !== undefined ) hasMorphNormal = true;
if ( hasMorphPosition && hasMorphNormal ) break;
}
if ( ! hasMorphPosition && ! hasMorphNormal ) return Promise.resolve( geometry );
var pendingPositionAccessors = [];
var pendingNormalAccessors = [];
for ( var i = 0, il = targets.length; i < il; i ++ ) {
var target = targets[ i ];
if ( hasMorphPosition ) {
var pendingAccessor = target.POSITION !== undefined
? parser.getDependency( 'accessor', target.POSITION )
: geometry.attributes.position;
pendingPositionAccessors.push( pendingAccessor );
}
if ( hasMorphNormal ) {
var pendingAccessor = target.NORMAL !== undefined
? parser.getDependency( 'accessor', target.NORMAL )
: geometry.attributes.normal;
pendingNormalAccessors.push( pendingAccessor );
}
}
return Promise.all( [
Promise.all( pendingPositionAccessors ),
Promise.all( pendingNormalAccessors )
] ).then( function ( accessors ) {
var morphPositions = accessors[ 0 ];
var morphNormals = accessors[ 1 ];
if ( hasMorphPosition ) geometry.morphAttributes.position = morphPositions;
if ( hasMorphNormal ) geometry.morphAttributes.normal = morphNormals;
geometry.morphTargetsRelative = true;
return geometry;
} );
}
/**
* @param {Mesh} mesh
* @param {GLTF.Mesh} meshDef
*/
function updateMorphTargets( mesh, meshDef ) {
mesh.updateMorphTargets();
if ( meshDef.weights !== undefined ) {
for ( var i = 0, il = meshDef.weights.length; i < il; i ++ ) {
mesh.morphTargetInfluences[ i ] = meshDef.weights[ i ];
}
}
// .extras has user-defined data, so check that .extras.targetNames is an array.
if ( meshDef.extras && Array.isArray( meshDef.extras.targetNames ) ) {
var targetNames = meshDef.extras.targetNames;
if ( mesh.morphTargetInfluences.length === targetNames.length ) {
mesh.morphTargetDictionary = {};
for ( var i = 0, il = targetNames.length; i < il; i ++ ) {
mesh.morphTargetDictionary[ targetNames[ i ] ] = i;
}
} else {
console.warn( 'THREE.GLTFLoader: Invalid extras.targetNames length. Ignoring names.' );
}
}
}
function createPrimitiveKey( primitiveDef ) {
var dracoExtension = primitiveDef.extensions && primitiveDef.extensions[ EXTENSIONS.KHR_DRACO_MESH_COMPRESSION ];
var geometryKey;
if ( dracoExtension ) {
geometryKey = 'draco:' + dracoExtension.bufferView
+ ':' + dracoExtension.indices
+ ':' + createAttributesKey( dracoExtension.attributes );
} else {
geometryKey = primitiveDef.indices + ':' + createAttributesKey( primitiveDef.attributes ) + ':' + primitiveDef.mode;
}
return geometryKey;
}
function createAttributesKey( attributes ) {
var attributesKey = '';
var keys = Object.keys( attributes ).sort();
for ( var i = 0, il = keys.length; i < il; i ++ ) {
attributesKey += keys[ i ] + ':' + attributes[ keys[ i ] ] + ';';
}
return attributesKey;
}
/* GLTF PARSER */
function GLTFParser( json, extensions, options ) {
this.json = json || {};
this.extensions = extensions || {};
this.options = options || {};
// loader object cache
this.cache = new GLTFRegistry();
// BufferGeometry caching
this.primitiveCache = {};
this.textureLoader = new TextureLoader( this.options.manager );
this.textureLoader.setCrossOrigin( this.options.crossOrigin );
this.fileLoader = new FileLoader( this.options.manager );
this.fileLoader.setResponseType( 'arraybuffer' );
if ( this.options.crossOrigin === 'use-credentials' ) {
this.fileLoader.setWithCredentials( true );
}
}
GLTFParser.prototype.parse = function ( onLoad, onError ) {
var parser = this;
var json = this.json;
var extensions = this.extensions;
// Clear the loader cache
this.cache.removeAll();
// Mark the special nodes/meshes in json for efficient parse
this.markDefs();
Promise.all( [
this.getDependencies( 'scene' ),
this.getDependencies( 'animation' ),
this.getDependencies( 'camera' ),
] ).then( function ( dependencies ) {
var result = {
scene: dependencies[ 0 ][ json.scene || 0 ],
scenes: dependencies[ 0 ],
animations: dependencies[ 1 ],
cameras: dependencies[ 2 ],
asset: json.asset,
parser: parser,
userData: {}
};
addUnknownExtensionsToUserData( extensions, result, json );
assignExtrasToUserData( result, json );
onLoad( result );
} ).catch( onError );
};
/**
* Marks the special nodes/meshes in json for efficient parse.
*/
GLTFParser.prototype.markDefs = function () {
var nodeDefs = this.json.nodes || [];
var skinDefs = this.json.skins || [];
var meshDefs = this.json.meshes || [];
var meshReferences = {};
var meshUses = {};
// Nothing in the node definition indicates whether it is a Bone or an
// Object3D. Use the skins' joint references to mark bones.
for ( var skinIndex = 0, skinLength = skinDefs.length; skinIndex < skinLength; skinIndex ++ ) {
var joints = skinDefs[ skinIndex ].joints;
for ( var i = 0, il = joints.length; i < il; i ++ ) {
nodeDefs[ joints[ i ] ].isBone = true;
}
}
// Meshes can (and should) be reused by multiple nodes in a glTF asset. To
// avoid having more than one Mesh with the same name, count
// references and rename instances below.
//
// Example: CesiumMilkTruck sample model reuses "Wheel" meshes.
for ( var nodeIndex = 0, nodeLength = nodeDefs.length; nodeIndex < nodeLength; nodeIndex ++ ) {
var nodeDef = nodeDefs[ nodeIndex ];
if ( nodeDef.mesh !== undefined ) {
if ( meshReferences[ nodeDef.mesh ] === undefined ) {
meshReferences[ nodeDef.mesh ] = meshUses[ nodeDef.mesh ] = 0;
}
meshReferences[ nodeDef.mesh ] ++;
// Nothing in the mesh definition indicates whether it is
// a SkinnedMesh or Mesh. Use the node's mesh reference
// to mark SkinnedMesh if node has skin.
if ( nodeDef.skin !== undefined ) {
meshDefs[ nodeDef.mesh ].isSkinnedMesh = true;
}
}
}
this.json.meshReferences = meshReferences;
this.json.meshUses = meshUses;
};
/**
* Requests the specified dependency asynchronously, with caching.
* @param {string} type
* @param {number} index
* @return {Promise<Object3D|Material|THREE.Texture|AnimationClip|ArrayBuffer|Object>}
*/
GLTFParser.prototype.getDependency = function ( type, index ) {
var cacheKey = type + ':' + index;
var dependency = this.cache.get( cacheKey );
if ( ! dependency ) {
switch ( type ) {
case 'scene':
dependency = this.loadScene( index );
break;
case 'node':
dependency = this.loadNode( index );
break;
case 'mesh':
dependency = this.loadMesh( index );
break;
case 'accessor':
dependency = this.loadAccessor( index );
break;
case 'bufferView':
dependency = this.loadBufferView( index );
break;
case 'buffer':
dependency = this.loadBuffer( index );
break;
case 'material':
dependency = this.loadMaterial( index );
break;
case 'texture':
dependency = this.loadTexture( index );
break;
case 'skin':
dependency = this.loadSkin( index );
break;
case 'animation':
dependency = this.loadAnimation( index );
break;
case 'camera':
dependency = this.loadCamera( index );
break;
case 'light':
dependency = this.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ].loadLight( index );
break;
default:
throw new Error( 'Unknown type: ' + type );
}
this.cache.add( cacheKey, dependency );
}
return dependency;
};
/**
* Requests all dependencies of the specified type asynchronously, with caching.
* @param {string} type
* @return {Promise<Array<Object>>}
*/
GLTFParser.prototype.getDependencies = function ( type ) {
var dependencies = this.cache.get( type );
if ( ! dependencies ) {
var parser = this;
var defs = this.json[ type + ( type === 'mesh' ? 'es' : 's' ) ] || [];
dependencies = Promise.all( defs.map( function ( def, index ) {
return parser.getDependency( type, index );
} ) );
this.cache.add( type, dependencies );
}
return dependencies;
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#buffers-and-buffer-views
* @param {number} bufferIndex
* @return {Promise<ArrayBuffer>}
*/
GLTFParser.prototype.loadBuffer = function ( bufferIndex ) {
var bufferDef = this.json.buffers[ bufferIndex ];
var loader = this.fileLoader;
if ( bufferDef.type && bufferDef.type !== 'arraybuffer' ) {
throw new Error( 'THREE.GLTFLoader: ' + bufferDef.type + ' buffer type is not supported.' );
}
// If present, GLB container is required to be the first buffer.
if ( bufferDef.uri === undefined && bufferIndex === 0 ) {
return Promise.resolve( this.extensions[ EXTENSIONS.KHR_BINARY_GLTF ].body );
}
var options = this.options;
return new Promise( function ( resolve, reject ) {
loader.load( resolveURL( bufferDef.uri, options.path ), resolve, undefined, function () {
reject( new Error( 'THREE.GLTFLoader: Failed to load buffer "' + bufferDef.uri + '".' ) );
} );
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#buffers-and-buffer-views
* @param {number} bufferViewIndex
* @return {Promise<ArrayBuffer>}
*/
GLTFParser.prototype.loadBufferView = function ( bufferViewIndex ) {
var bufferViewDef = this.json.bufferViews[ bufferViewIndex ];
return this.getDependency( 'buffer', bufferViewDef.buffer ).then( function ( buffer ) {
var byteLength = bufferViewDef.byteLength || 0;
var byteOffset = bufferViewDef.byteOffset || 0;
return buffer.slice( byteOffset, byteOffset + byteLength );
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#accessors
* @param {number} accessorIndex
* @return {Promise<BufferAttribute|InterleavedBufferAttribute>}
*/
GLTFParser.prototype.loadAccessor = function ( accessorIndex ) {
var parser = this;
var json = this.json;
var accessorDef = this.json.accessors[ accessorIndex ];
if ( accessorDef.bufferView === undefined && accessorDef.sparse === undefined ) {
// Ignore empty accessors, which may be used to declare runtime
// information about attributes coming from another source (e.g. Draco
// compression extension).
return Promise.resolve( null );
}
var pendingBufferViews = [];
if ( accessorDef.bufferView !== undefined ) {
pendingBufferViews.push( this.getDependency( 'bufferView', accessorDef.bufferView ) );
} else {
pendingBufferViews.push( null );
}
if ( accessorDef.sparse !== undefined ) {
pendingBufferViews.push( this.getDependency( 'bufferView', accessorDef.sparse.indices.bufferView ) );
pendingBufferViews.push( this.getDependency( 'bufferView', accessorDef.sparse.values.bufferView ) );
}
return Promise.all( pendingBufferViews ).then( function ( bufferViews ) {
var bufferView = bufferViews[ 0 ];
var itemSize = WEBGL_TYPE_SIZES[ accessorDef.type ];
var TypedArray = WEBGL_COMPONENT_TYPES[ accessorDef.componentType ];
// For VEC3: itemSize is 3, elementBytes is 4, itemBytes is 12.
var elementBytes = TypedArray.BYTES_PER_ELEMENT;
var itemBytes = elementBytes * itemSize;
var byteOffset = accessorDef.byteOffset || 0;
var byteStride = accessorDef.bufferView !== undefined ? json.bufferViews[ accessorDef.bufferView ].byteStride : undefined;
var normalized = accessorDef.normalized === true;
var array, bufferAttribute;
// The buffer is not interleaved if the stride is the item size in bytes.
if ( byteStride && byteStride !== itemBytes ) {
// Each "slice" of the buffer, as defined by 'count' elements of 'byteStride' bytes, gets its own InterleavedBuffer
// This makes sure that IBA.count reflects accessor.count properly
var ibSlice = Math.floor( byteOffset / byteStride );
var ibCacheKey = 'InterleavedBuffer:' + accessorDef.bufferView + ':' + accessorDef.componentType + ':' + ibSlice + ':' + accessorDef.count;
var ib = parser.cache.get( ibCacheKey );
if ( ! ib ) {
array = new TypedArray( bufferView, ibSlice * byteStride, accessorDef.count * byteStride / elementBytes );
// Integer parameters to IB/IBA are in array elements, not bytes.
ib = new InterleavedBuffer( array, byteStride / elementBytes );
parser.cache.add( ibCacheKey, ib );
}
bufferAttribute = new InterleavedBufferAttribute( ib, itemSize, ( byteOffset % byteStride ) / elementBytes, normalized );
} else {
if ( bufferView === null ) {
array = new TypedArray( accessorDef.count * itemSize );
} else {
array = new TypedArray( bufferView, byteOffset, accessorDef.count * itemSize );
}
bufferAttribute = new BufferAttribute( array, itemSize, normalized );
}
// https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#sparse-accessors
if ( accessorDef.sparse !== undefined ) {
var itemSizeIndices = WEBGL_TYPE_SIZES.SCALAR;
var TypedArrayIndices = WEBGL_COMPONENT_TYPES[ accessorDef.sparse.indices.componentType ];
var byteOffsetIndices = accessorDef.sparse.indices.byteOffset || 0;
var byteOffsetValues = accessorDef.sparse.values.byteOffset || 0;
var sparseIndices = new TypedArrayIndices( bufferViews[ 1 ], byteOffsetIndices, accessorDef.sparse.count * itemSizeIndices );
var sparseValues = new TypedArray( bufferViews[ 2 ], byteOffsetValues, accessorDef.sparse.count * itemSize );
if ( bufferView !== null ) {
// Avoid modifying the original ArrayBuffer, if the bufferView wasn't initialized with zeroes.
bufferAttribute = new BufferAttribute( bufferAttribute.array.slice(), bufferAttribute.itemSize, bufferAttribute.normalized );
}
for ( var i = 0, il = sparseIndices.length; i < il; i ++ ) {
var index = sparseIndices[ i ];
bufferAttribute.setX( index, sparseValues[ i * itemSize ] );
if ( itemSize >= 2 ) bufferAttribute.setY( index, sparseValues[ i * itemSize + 1 ] );
if ( itemSize >= 3 ) bufferAttribute.setZ( index, sparseValues[ i * itemSize + 2 ] );
if ( itemSize >= 4 ) bufferAttribute.setW( index, sparseValues[ i * itemSize + 3 ] );
if ( itemSize >= 5 ) throw new Error( 'THREE.GLTFLoader: Unsupported itemSize in sparse BufferAttribute.' );
}
}
return bufferAttribute;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#textures
* @param {number} textureIndex
* @return {Promise<THREE.Texture>}
*/
GLTFParser.prototype.loadTexture = function ( textureIndex ) {
var parser = this;
var json = this.json;
var options = this.options;
var textureLoader = this.textureLoader;
var URL = self.URL || self.webkitURL;
var textureDef = json.textures[ textureIndex ];
var textureExtensions = textureDef.extensions || {};
var source;
if ( textureExtensions[ EXTENSIONS.MSFT_TEXTURE_DDS ] ) {
source = json.images[ textureExtensions[ EXTENSIONS.MSFT_TEXTURE_DDS ].source ];
} else {
source = json.images[ textureDef.source ];
}
var sourceURI = source.uri;
var isObjectURL = false;
if ( source.bufferView !== undefined ) {
// Load binary image data from bufferView, if provided.
sourceURI = parser.getDependency( 'bufferView', source.bufferView ).then( function ( bufferView ) {
isObjectURL = true;
var blob = new Blob( [ bufferView ], { type: source.mimeType } );
sourceURI = URL.createObjectURL( blob );
return sourceURI;
} );
}
return Promise.resolve( sourceURI ).then( function ( sourceURI ) {
// Load Texture resource.
var loader = options.manager.getHandler( sourceURI );
if ( ! loader ) {
loader = textureExtensions[ EXTENSIONS.MSFT_TEXTURE_DDS ]
? parser.extensions[ EXTENSIONS.MSFT_TEXTURE_DDS ].ddsLoader
: textureLoader;
}
return new Promise( function ( resolve, reject ) {
loader.load( resolveURL( sourceURI, options.path ), resolve, undefined, reject );
} );
} ).then( function ( texture ) {
// Clean up resources and configure Texture.
if ( isObjectURL === true ) {
URL.revokeObjectURL( sourceURI );
}
texture.flipY = false;
if ( textureDef.name ) texture.name = textureDef.name;
// Ignore unknown mime types, like DDS files.
if ( source.mimeType in MIME_TYPE_FORMATS ) {
texture.format = MIME_TYPE_FORMATS[ source.mimeType ];
}
var samplers = json.samplers || {};
var sampler = samplers[ textureDef.sampler ] || {};
texture.magFilter = WEBGL_FILTERS[ sampler.magFilter ] || LinearFilter;
texture.minFilter = WEBGL_FILTERS[ sampler.minFilter ] || LinearMipmapLinearFilter;
texture.wrapS = WEBGL_WRAPPINGS[ sampler.wrapS ] || RepeatWrapping;
texture.wrapT = WEBGL_WRAPPINGS[ sampler.wrapT ] || RepeatWrapping;
return texture;
} );
};
/**
* Asynchronously assigns a texture to the given material parameters.
* @param {Object} materialParams
* @param {string} mapName
* @param {Object} mapDef
* @return {Promise}
*/
GLTFParser.prototype.assignTexture = function ( materialParams, mapName, mapDef ) {
var parser = this;
return this.getDependency( 'texture', mapDef.index ).then( function ( texture ) {
if ( ! texture.isCompressedTexture ) {
switch ( mapName ) {
case 'aoMap':
case 'emissiveMap':
case 'metalnessMap':
case 'normalMap':
case 'roughnessMap':
texture.format = RGBFormat;
break;
}
}
// Materials sample aoMap from UV set 1 and other maps from UV set 0 - this can't be configured
// However, we will copy UV set 0 to UV set 1 on demand for aoMap
if ( mapDef.texCoord !== undefined && mapDef.texCoord != 0 && ! ( mapName === 'aoMap' && mapDef.texCoord == 1 ) ) {
console.warn( 'THREE.GLTFLoader: Custom UV set ' + mapDef.texCoord + ' for texture ' + mapName + ' not yet supported.' );
}
if ( parser.extensions[ EXTENSIONS.KHR_TEXTURE_TRANSFORM ] ) {
var transform = mapDef.extensions !== undefined ? mapDef.extensions[ EXTENSIONS.KHR_TEXTURE_TRANSFORM ] : undefined;
if ( transform ) {
texture = parser.extensions[ EXTENSIONS.KHR_TEXTURE_TRANSFORM ].extendTexture( texture, transform );
}
}
materialParams[ mapName ] = texture;
} );
};
/**
* Assigns final material to a Mesh, Line, or Points instance. The instance
* already has a material (generated from the glTF material options alone)
* but reuse of the same glTF material may require multiple threejs materials
* to accomodate different primitive types, defines, etc. New materials will
* be created if necessary, and reused from a cache.
* @param {Object3D} mesh Mesh, Line, or Points instance.
*/
GLTFParser.prototype.assignFinalMaterial = function ( mesh ) {
var geometry = mesh.geometry;
var material = mesh.material;
var useVertexTangents = geometry.attributes.tangent !== undefined;
var useVertexColors = geometry.attributes.color !== undefined;
var useFlatShading = geometry.attributes.normal === undefined;
var useSkinning = mesh.isSkinnedMesh === true;
var useMorphTargets = Object.keys( geometry.morphAttributes ).length > 0;
var useMorphNormals = useMorphTargets && geometry.morphAttributes.normal !== undefined;
if ( mesh.isPoints ) {
var cacheKey = 'PointsMaterial:' + material.uuid;
var pointsMaterial = this.cache.get( cacheKey );
if ( ! pointsMaterial ) {
pointsMaterial = new PointsMaterial();
Material.prototype.copy.call( pointsMaterial, material );
pointsMaterial.color.copy( material.color );
pointsMaterial.map = material.map;
pointsMaterial.sizeAttenuation = false; // glTF spec says points should be 1px
this.cache.add( cacheKey, pointsMaterial );
}
material = pointsMaterial;
} else if ( mesh.isLine ) {
var cacheKey = 'LineBasicMaterial:' + material.uuid;
var lineMaterial = this.cache.get( cacheKey );
if ( ! lineMaterial ) {
lineMaterial = new LineBasicMaterial();
Material.prototype.copy.call( lineMaterial, material );
lineMaterial.color.copy( material.color );
this.cache.add( cacheKey, lineMaterial );
}
material = lineMaterial;
}
// Clone the material if it will be modified
if ( useVertexTangents || useVertexColors || useFlatShading || useSkinning || useMorphTargets ) {
var cacheKey = 'ClonedMaterial:' + material.uuid + ':';
if ( material.isGLTFSpecularGlossinessMaterial ) cacheKey += 'specular-glossiness:';
if ( useSkinning ) cacheKey += 'skinning:';
if ( useVertexTangents ) cacheKey += 'vertex-tangents:';
if ( useVertexColors ) cacheKey += 'vertex-colors:';
if ( useFlatShading ) cacheKey += 'flat-shading:';
if ( useMorphTargets ) cacheKey += 'morph-targets:';
if ( useMorphNormals ) cacheKey += 'morph-normals:';
var cachedMaterial = this.cache.get( cacheKey );
if ( ! cachedMaterial ) {
cachedMaterial = material.clone();
if ( useSkinning ) cachedMaterial.skinning = true;
if ( useVertexTangents ) cachedMaterial.vertexTangents = true;
if ( useVertexColors ) cachedMaterial.vertexColors = true;
if ( useFlatShading ) cachedMaterial.flatShading = true;
if ( useMorphTargets ) cachedMaterial.morphTargets = true;
if ( useMorphNormals ) cachedMaterial.morphNormals = true;
this.cache.add( cacheKey, cachedMaterial );
}
material = cachedMaterial;
}
// workarounds for mesh and geometry
if ( material.aoMap && geometry.attributes.uv2 === undefined && geometry.attributes.uv !== undefined ) {
geometry.setAttribute( 'uv2', new BufferAttribute( geometry.attributes.uv.array, 2 ) );
}
// https://github.com/mrdoob/three.js/issues/11438#issuecomment-507003995
if ( material.normalScale && ! useVertexTangents ) {
material.normalScale.y = - material.normalScale.y;
}
if ( material.clearcoatNormalScale && ! useVertexTangents ) {
material.clearcoatNormalScale.y = - material.clearcoatNormalScale.y;
}
mesh.material = material;
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#materials
* @param {number} materialIndex
* @return {Promise<Material>}
*/
GLTFParser.prototype.loadMaterial = function ( materialIndex ) {
var parser = this;
var json = this.json;
var extensions = this.extensions;
var materialDef = json.materials[ materialIndex ];
var materialType;
var materialParams = {};
var materialExtensions = materialDef.extensions || {};
var pending = [];
if ( materialExtensions[ EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS ] ) {
var sgExtension = extensions[ EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS ];
materialType = sgExtension.getMaterialType();
pending.push( sgExtension.extendParams( materialParams, materialDef, parser ) );
} else if ( materialExtensions[ EXTENSIONS.KHR_MATERIALS_UNLIT ] ) {
var kmuExtension = extensions[ EXTENSIONS.KHR_MATERIALS_UNLIT ];
materialType = kmuExtension.getMaterialType();
pending.push( kmuExtension.extendParams( materialParams, materialDef, parser ) );
} else {
// Specification:
// https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#metallic-roughness-material
materialType = MeshStandardMaterial;
var metallicRoughness = materialDef.pbrMetallicRoughness || {};
materialParams.color = new Color( 1.0, 1.0, 1.0 );
materialParams.opacity = 1.0;
if ( Array.isArray( metallicRoughness.baseColorFactor ) ) {
var array = metallicRoughness.baseColorFactor;
materialParams.color.fromArray( array );
materialParams.opacity = array[ 3 ];
}
if ( metallicRoughness.baseColorTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'map', metallicRoughness.baseColorTexture ) );
}
materialParams.metalness = metallicRoughness.metallicFactor !== undefined ? metallicRoughness.metallicFactor : 1.0;
materialParams.roughness = metallicRoughness.roughnessFactor !== undefined ? metallicRoughness.roughnessFactor : 1.0;
if ( metallicRoughness.metallicRoughnessTexture !== undefined ) {
pending.push( parser.assignTexture( materialParams, 'metalnessMap', metallicRoughness.metallicRoughnessTexture ) );
pending.push( parser.assignTexture( materialParams, 'roughnessMap', metallicRoughness.metallicRoughnessTexture ) );
}
}
if ( materialDef.doubleSided === true ) {
materialParams.side = DoubleSide;
}
var alphaMode = materialDef.alphaMode || ALPHA_MODES.OPAQUE;
if ( alphaMode === ALPHA_MODES.BLEND ) {
materialParams.transparent = true;
// See: https://github.com/mrdoob/three.js/issues/17706
materialParams.depthWrite = false;
} else {
materialParams.transparent = false;
if ( alphaMode === ALPHA_MODES.MASK ) {
materialParams.alphaTest = materialDef.alphaCutoff !== undefined ? materialDef.alphaCutoff : 0.5;
}
}
if ( materialDef.normalTexture !== undefined && materialType !== MeshBasicMaterial ) {
pending.push( parser.assignTexture( materialParams, 'normalMap', materialDef.normalTexture ) );
materialParams.normalScale = new Vector2( 1, 1 );
if ( materialDef.normalTexture.scale !== undefined ) {
materialParams.normalScale.set( materialDef.normalTexture.scale, materialDef.normalTexture.scale );
}
}
if ( materialDef.occlusionTexture !== undefined && materialType !== MeshBasicMaterial ) {
pending.push( parser.assignTexture( materialParams, 'aoMap', materialDef.occlusionTexture ) );
if ( materialDef.occlusionTexture.strength !== undefined ) {
materialParams.aoMapIntensity = materialDef.occlusionTexture.strength;
}
}
if ( materialDef.emissiveFactor !== undefined && materialType !== MeshBasicMaterial ) {
materialParams.emissive = new Color().fromArray( materialDef.emissiveFactor );
}
if ( materialDef.emissiveTexture !== undefined && materialType !== MeshBasicMaterial ) {
pending.push( parser.assignTexture( materialParams, 'emissiveMap', materialDef.emissiveTexture ) );
}
if ( materialExtensions[ EXTENSIONS.KHR_MATERIALS_CLEARCOAT ] ) {
var clearcoatExtension = extensions[ EXTENSIONS.KHR_MATERIALS_CLEARCOAT ];
materialType = clearcoatExtension.getMaterialType();
pending.push( clearcoatExtension.extendParams( materialParams, { extensions: materialExtensions }, parser ) );
}
return Promise.all( pending ).then( function () {
var material;
if ( materialType === GLTFMeshStandardSGMaterial ) {
material = extensions[ EXTENSIONS.KHR_MATERIALS_PBR_SPECULAR_GLOSSINESS ].createMaterial( materialParams );
} else {
material = new materialType( materialParams );
}
if ( materialDef.name ) material.name = materialDef.name;
// baseColorTexture, emissiveTexture, and specularGlossinessTexture use sRGB encoding.
if ( material.map ) material.map.encoding = sRGBEncoding;
if ( material.emissiveMap ) material.emissiveMap.encoding = sRGBEncoding;
assignExtrasToUserData( material, materialDef );
if ( materialDef.extensions ) addUnknownExtensionsToUserData( extensions, material, materialDef );
return material;
} );
};
/**
* @param {BufferGeometry} geometry
* @param {GLTF.Primitive} primitiveDef
* @param {GLTFParser} parser
*/
function computeBounds( geometry, primitiveDef, parser ) {
var attributes = primitiveDef.attributes;
var box = new Box3();
if ( attributes.POSITION !== undefined ) {
var accessor = parser.json.accessors[ attributes.POSITION ];
var min = accessor.min;
var max = accessor.max;
// glTF requires 'min' and 'max', but VRM (which extends glTF) currently ignores that requirement.
if ( min !== undefined && max !== undefined ) {
box.set(
new Vector3( min[ 0 ], min[ 1 ], min[ 2 ] ),
new Vector3( max[ 0 ], max[ 1 ], max[ 2 ] ) );
} else {
console.warn( 'THREE.GLTFLoader: Missing min/max properties for accessor POSITION.' );
return;
}
} else {
return;
}
var targets = primitiveDef.targets;
if ( targets !== undefined ) {
var maxDisplacement = new Vector3();
var vector = new Vector3();
for ( var i = 0, il = targets.length; i < il; i ++ ) {
var target = targets[ i ];
if ( target.POSITION !== undefined ) {
var accessor = parser.json.accessors[ target.POSITION ];
var min = accessor.min;
var max = accessor.max;
// glTF requires 'min' and 'max', but VRM (which extends glTF) currently ignores that requirement.
if ( min !== undefined && max !== undefined ) {
// we need to get max of absolute components because target weight is [-1,1]
vector.setX( Math.max( Math.abs( min[ 0 ] ), Math.abs( max[ 0 ] ) ) );
vector.setY( Math.max( Math.abs( min[ 1 ] ), Math.abs( max[ 1 ] ) ) );
vector.setZ( Math.max( Math.abs( min[ 2 ] ), Math.abs( max[ 2 ] ) ) );
// Note: this assumes that the sum of all weights is at most 1. This isn't quite correct - it's more conservative
// to assume that each target can have a max weight of 1. However, for some use cases - notably, when morph targets
// are used to implement key-frame animations and as such only two are active at a time - this results in very large
// boxes. So for now we make a box that's sometimes a touch too small but is hopefully mostly of reasonable size.
maxDisplacement.max( vector );
} else {
console.warn( 'THREE.GLTFLoader: Missing min/max properties for accessor POSITION.' );
}
}
}
// As per comment above this box isn't conservative, but has a reasonable size for a very large number of morph targets.
box.expandByVector( maxDisplacement );
}
geometry.boundingBox = box;
var sphere = new Sphere();
box.getCenter( sphere.center );
sphere.radius = box.min.distanceTo( box.max ) / 2;
geometry.boundingSphere = sphere;
}
/**
* @param {BufferGeometry} geometry
* @param {GLTF.Primitive} primitiveDef
* @param {GLTFParser} parser
* @return {Promise<BufferGeometry>}
*/
function addPrimitiveAttributes( geometry, primitiveDef, parser ) {
var attributes = primitiveDef.attributes;
var pending = [];
function assignAttributeAccessor( accessorIndex, attributeName ) {
return parser.getDependency( 'accessor', accessorIndex )
.then( function ( accessor ) {
geometry.setAttribute( attributeName, accessor );
} );
}
for ( var gltfAttributeName in attributes ) {
var threeAttributeName = ATTRIBUTES[ gltfAttributeName ] || gltfAttributeName.toLowerCase();
// Skip attributes already provided by e.g. Draco extension.
if ( threeAttributeName in geometry.attributes ) continue;
pending.push( assignAttributeAccessor( attributes[ gltfAttributeName ], threeAttributeName ) );
}
if ( primitiveDef.indices !== undefined && ! geometry.index ) {
var accessor = parser.getDependency( 'accessor', primitiveDef.indices ).then( function ( accessor ) {
geometry.setIndex( accessor );
} );
pending.push( accessor );
}
assignExtrasToUserData( geometry, primitiveDef );
computeBounds( geometry, primitiveDef, parser );
return Promise.all( pending ).then( function () {
return primitiveDef.targets !== undefined
? addMorphTargets( geometry, primitiveDef.targets, parser )
: geometry;
} );
}
/**
* @param {BufferGeometry} geometry
* @param {Number} drawMode
* @return {BufferGeometry}
*/
function toTrianglesDrawMode( geometry, drawMode ) {
var index = geometry.getIndex();
// generate index if not present
if ( index === null ) {
var indices = [];
var position = geometry.getAttribute( 'position' );
if ( position !== undefined ) {
for ( var i = 0; i < position.count; i ++ ) {
indices.push( i );
}
geometry.setIndex( indices );
index = geometry.getIndex();
} else {
console.error( 'THREE.GLTFLoader.toTrianglesDrawMode(): Undefined position attribute. Processing not possible.' );
return geometry;
}
}
//
var numberOfTriangles = index.count - 2;
var newIndices = [];
if ( drawMode === TriangleFanDrawMode ) {
// gl.TRIANGLE_FAN
for ( var i = 1; i <= numberOfTriangles; i ++ ) {
newIndices.push( index.getX( 0 ) );
newIndices.push( index.getX( i ) );
newIndices.push( index.getX( i + 1 ) );
}
} else {
// gl.TRIANGLE_STRIP
for ( var i = 0; i < numberOfTriangles; i ++ ) {
if ( i % 2 === 0 ) {
newIndices.push( index.getX( i ) );
newIndices.push( index.getX( i + 1 ) );
newIndices.push( index.getX( i + 2 ) );
} else {
newIndices.push( index.getX( i + 2 ) );
newIndices.push( index.getX( i + 1 ) );
newIndices.push( index.getX( i ) );
}
}
}
if ( ( newIndices.length / 3 ) !== numberOfTriangles ) {
console.error( 'THREE.GLTFLoader.toTrianglesDrawMode(): Unable to generate correct amount of triangles.' );
}
// build final geometry
var newGeometry = geometry.clone();
newGeometry.setIndex( newIndices );
return newGeometry;
}
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#geometry
*
* Creates BufferGeometries from primitives.
*
* @param {Array<GLTF.Primitive>} primitives
* @return {Promise<Array<BufferGeometry>>}
*/
GLTFParser.prototype.loadGeometries = function ( primitives ) {
var parser = this;
var extensions = this.extensions;
var cache = this.primitiveCache;
function createDracoPrimitive( primitive ) {
return extensions[ EXTENSIONS.KHR_DRACO_MESH_COMPRESSION ]
.decodePrimitive( primitive, parser )
.then( function ( geometry ) {
return addPrimitiveAttributes( geometry, primitive, parser );
} );
}
var pending = [];
for ( var i = 0, il = primitives.length; i < il; i ++ ) {
var primitive = primitives[ i ];
var cacheKey = createPrimitiveKey( primitive );
// See if we've already created this geometry
var cached = cache[ cacheKey ];
if ( cached ) {
// Use the cached geometry if it exists
pending.push( cached.promise );
} else {
var geometryPromise;
if ( primitive.extensions && primitive.extensions[ EXTENSIONS.KHR_DRACO_MESH_COMPRESSION ] ) {
// Use DRACO geometry if available
geometryPromise = createDracoPrimitive( primitive );
} else {
// Otherwise create a new geometry
geometryPromise = addPrimitiveAttributes( new BufferGeometry(), primitive, parser );
}
// Cache this geometry
cache[ cacheKey ] = { primitive: primitive, promise: geometryPromise };
pending.push( geometryPromise );
}
}
return Promise.all( pending );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#meshes
* @param {number} meshIndex
* @return {Promise<Group|Mesh|SkinnedMesh>}
*/
GLTFParser.prototype.loadMesh = function ( meshIndex ) {
var parser = this;
var json = this.json;
var meshDef = json.meshes[ meshIndex ];
var primitives = meshDef.primitives;
var pending = [];
for ( var i = 0, il = primitives.length; i < il; i ++ ) {
var material = primitives[ i ].material === undefined
? createDefaultMaterial( this.cache )
: this.getDependency( 'material', primitives[ i ].material );
pending.push( material );
}
pending.push( parser.loadGeometries( primitives ) );
return Promise.all( pending ).then( function ( results ) {
var materials = results.slice( 0, results.length - 1 );
var geometries = results[ results.length - 1 ];
var meshes = [];
for ( var i = 0, il = geometries.length; i < il; i ++ ) {
var geometry = geometries[ i ];
var primitive = primitives[ i ];
// 1. create Mesh
var mesh;
var material = materials[ i ];
if ( primitive.mode === WEBGL_CONSTANTS.TRIANGLES ||
primitive.mode === WEBGL_CONSTANTS.TRIANGLE_STRIP ||
primitive.mode === WEBGL_CONSTANTS.TRIANGLE_FAN ||
primitive.mode === undefined ) {
// .isSkinnedMesh isn't in glTF spec. See .markDefs()
mesh = meshDef.isSkinnedMesh === true
? new SkinnedMesh( geometry, material )
: new Mesh( geometry, material );
if ( mesh.isSkinnedMesh === true && ! mesh.geometry.attributes.skinWeight.normalized ) {
// we normalize floating point skin weight array to fix malformed assets (see #15319)
// it's important to skip this for non-float32 data since normalizeSkinWeights assumes non-normalized inputs
mesh.normalizeSkinWeights();
}
if ( primitive.mode === WEBGL_CONSTANTS.TRIANGLE_STRIP ) {
mesh.geometry = toTrianglesDrawMode( mesh.geometry, TriangleStripDrawMode );
} else if ( primitive.mode === WEBGL_CONSTANTS.TRIANGLE_FAN ) {
mesh.geometry = toTrianglesDrawMode( mesh.geometry, TriangleFanDrawMode );
}
} else if ( primitive.mode === WEBGL_CONSTANTS.LINES ) {
mesh = new LineSegments( geometry, material );
} else if ( primitive.mode === WEBGL_CONSTANTS.LINE_STRIP ) {
mesh = new Line( geometry, material );
} else if ( primitive.mode === WEBGL_CONSTANTS.LINE_LOOP ) {
mesh = new LineLoop( geometry, material );
} else if ( primitive.mode === WEBGL_CONSTANTS.POINTS ) {
mesh = new Points( geometry, material );
} else {
throw new Error( 'THREE.GLTFLoader: Primitive mode unsupported: ' + primitive.mode );
}
if ( Object.keys( mesh.geometry.morphAttributes ).length > 0 ) {
updateMorphTargets( mesh, meshDef );
}
mesh.name = meshDef.name || ( 'mesh_' + meshIndex );
if ( geometries.length > 1 ) mesh.name += '_' + i;
assignExtrasToUserData( mesh, meshDef );
parser.assignFinalMaterial( mesh );
meshes.push( mesh );
}
if ( meshes.length === 1 ) {
return meshes[ 0 ];
}
var group = new Group();
for ( var i = 0, il = meshes.length; i < il; i ++ ) {
group.add( meshes[ i ] );
}
return group;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#cameras
* @param {number} cameraIndex
* @return {Promise<THREE.Camera>}
*/
GLTFParser.prototype.loadCamera = function ( cameraIndex ) {
var camera;
var cameraDef = this.json.cameras[ cameraIndex ];
var params = cameraDef[ cameraDef.type ];
if ( ! params ) {
console.warn( 'THREE.GLTFLoader: Missing camera parameters.' );
return;
}
if ( cameraDef.type === 'perspective' ) {
camera = new PerspectiveCamera( MathUtils.radToDeg( params.yfov ), params.aspectRatio || 1, params.znear || 1, params.zfar || 2e6 );
} else if ( cameraDef.type === 'orthographic' ) {
camera = new OrthographicCamera( params.xmag / - 2, params.xmag / 2, params.ymag / 2, params.ymag / - 2, params.znear, params.zfar );
}
if ( cameraDef.name ) camera.name = cameraDef.name;
assignExtrasToUserData( camera, cameraDef );
return Promise.resolve( camera );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#skins
* @param {number} skinIndex
* @return {Promise<Object>}
*/
GLTFParser.prototype.loadSkin = function ( skinIndex ) {
var skinDef = this.json.skins[ skinIndex ];
var skinEntry = { joints: skinDef.joints };
if ( skinDef.inverseBindMatrices === undefined ) {
return Promise.resolve( skinEntry );
}
return this.getDependency( 'accessor', skinDef.inverseBindMatrices ).then( function ( accessor ) {
skinEntry.inverseBindMatrices = accessor;
return skinEntry;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#animations
* @param {number} animationIndex
* @return {Promise<AnimationClip>}
*/
GLTFParser.prototype.loadAnimation = function ( animationIndex ) {
var json = this.json;
var animationDef = json.animations[ animationIndex ];
var pendingNodes = [];
var pendingInputAccessors = [];
var pendingOutputAccessors = [];
var pendingSamplers = [];
var pendingTargets = [];
for ( var i = 0, il = animationDef.channels.length; i < il; i ++ ) {
var channel = animationDef.channels[ i ];
var sampler = animationDef.samplers[ channel.sampler ];
var target = channel.target;
var name = target.node !== undefined ? target.node : target.id; // NOTE: target.id is deprecated.
var input = animationDef.parameters !== undefined ? animationDef.parameters[ sampler.input ] : sampler.input;
var output = animationDef.parameters !== undefined ? animationDef.parameters[ sampler.output ] : sampler.output;
pendingNodes.push( this.getDependency( 'node', name ) );
pendingInputAccessors.push( this.getDependency( 'accessor', input ) );
pendingOutputAccessors.push( this.getDependency( 'accessor', output ) );
pendingSamplers.push( sampler );
pendingTargets.push( target );
}
return Promise.all( [
Promise.all( pendingNodes ),
Promise.all( pendingInputAccessors ),
Promise.all( pendingOutputAccessors ),
Promise.all( pendingSamplers ),
Promise.all( pendingTargets )
] ).then( function ( dependencies ) {
var nodes = dependencies[ 0 ];
var inputAccessors = dependencies[ 1 ];
var outputAccessors = dependencies[ 2 ];
var samplers = dependencies[ 3 ];
var targets = dependencies[ 4 ];
var tracks = [];
for ( var i = 0, il = nodes.length; i < il; i ++ ) {
var node = nodes[ i ];
var inputAccessor = inputAccessors[ i ];
var outputAccessor = outputAccessors[ i ];
var sampler = samplers[ i ];
var target = targets[ i ];
if ( node === undefined ) continue;
node.updateMatrix();
node.matrixAutoUpdate = true;
var TypedKeyframeTrack;
switch ( PATH_PROPERTIES[ target.path ] ) {
case PATH_PROPERTIES.weights:
TypedKeyframeTrack = NumberKeyframeTrack;
break;
case PATH_PROPERTIES.rotation:
TypedKeyframeTrack = QuaternionKeyframeTrack;
break;
case PATH_PROPERTIES.position:
case PATH_PROPERTIES.scale:
default:
TypedKeyframeTrack = VectorKeyframeTrack;
break;
}
var targetName = node.name ? node.name : node.uuid;
var interpolation = sampler.interpolation !== undefined ? INTERPOLATION[ sampler.interpolation ] : InterpolateLinear;
var targetNames = [];
if ( PATH_PROPERTIES[ target.path ] === PATH_PROPERTIES.weights ) {
// Node may be a Group (glTF mesh with several primitives) or a Mesh.
node.traverse( function ( object ) {
if ( object.isMesh === true && object.morphTargetInfluences ) {
targetNames.push( object.name ? object.name : object.uuid );
}
} );
} else {
targetNames.push( targetName );
}
var outputArray = outputAccessor.array;
if ( outputAccessor.normalized ) {
var scale;
if ( outputArray.constructor === Int8Array ) {
scale = 1 / 127;
} else if ( outputArray.constructor === Uint8Array ) {
scale = 1 / 255;
} else if ( outputArray.constructor == Int16Array ) {
scale = 1 / 32767;
} else if ( outputArray.constructor === Uint16Array ) {
scale = 1 / 65535;
} else {
throw new Error( 'THREE.GLTFLoader: Unsupported output accessor component type.' );
}
var scaled = new Float32Array( outputArray.length );
for ( var j = 0, jl = outputArray.length; j < jl; j ++ ) {
scaled[ j ] = outputArray[ j ] * scale;
}
outputArray = scaled;
}
for ( var j = 0, jl = targetNames.length; j < jl; j ++ ) {
var track = new TypedKeyframeTrack(
targetNames[ j ] + '.' + PATH_PROPERTIES[ target.path ],
inputAccessor.array,
outputArray,
interpolation
);
// Override interpolation with custom factory method.
if ( sampler.interpolation === 'CUBICSPLINE' ) {
track.createInterpolant = function InterpolantFactoryMethodGLTFCubicSpline( result ) {
// A CUBICSPLINE keyframe in glTF has three output values for each input value,
// representing inTangent, splineVertex, and outTangent. As a result, track.getValueSize()
// must be divided by three to get the interpolant's sampleSize argument.
return new GLTFCubicSplineInterpolant( this.times, this.values, this.getValueSize() / 3, result );
};
// Mark as CUBICSPLINE. `track.getInterpolation()` doesn't support custom interpolants.
track.createInterpolant.isInterpolantFactoryMethodGLTFCubicSpline = true;
}
tracks.push( track );
}
}
var name = animationDef.name ? animationDef.name : 'animation_' + animationIndex;
return new AnimationClip( name, undefined, tracks );
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#nodes-and-hierarchy
* @param {number} nodeIndex
* @return {Promise<Object3D>}
*/
GLTFParser.prototype.loadNode = function ( nodeIndex ) {
var json = this.json;
var extensions = this.extensions;
var parser = this;
var meshReferences = json.meshReferences;
var meshUses = json.meshUses;
var nodeDef = json.nodes[ nodeIndex ];
return ( function () {
var pending = [];
if ( nodeDef.mesh !== undefined ) {
pending.push( parser.getDependency( 'mesh', nodeDef.mesh ).then( function ( mesh ) {
var node;
if ( meshReferences[ nodeDef.mesh ] > 1 ) {
var instanceNum = meshUses[ nodeDef.mesh ] ++;
node = mesh.clone();
node.name += '_instance_' + instanceNum;
} else {
node = mesh;
}
// if weights are provided on the node, override weights on the mesh.
if ( nodeDef.weights !== undefined ) {
node.traverse( function ( o ) {
if ( ! o.isMesh ) return;
for ( var i = 0, il = nodeDef.weights.length; i < il; i ++ ) {
o.morphTargetInfluences[ i ] = nodeDef.weights[ i ];
}
} );
}
return node;
} ) );
}
if ( nodeDef.camera !== undefined ) {
pending.push( parser.getDependency( 'camera', nodeDef.camera ) );
}
if ( nodeDef.extensions
&& nodeDef.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ]
&& nodeDef.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ].light !== undefined ) {
pending.push( parser.getDependency( 'light', nodeDef.extensions[ EXTENSIONS.KHR_LIGHTS_PUNCTUAL ].light ) );
}
return Promise.all( pending );
}() ).then( function ( objects ) {
var node;
// .isBone isn't in glTF spec. See .markDefs
if ( nodeDef.isBone === true ) {
node = new Bone();
} else if ( objects.length > 1 ) {
node = new Group();
} else if ( objects.length === 1 ) {
node = objects[ 0 ];
} else {
node = new Object3D();
}
if ( node !== objects[ 0 ] ) {
for ( var i = 0, il = objects.length; i < il; i ++ ) {
node.add( objects[ i ] );
}
}
if ( nodeDef.name ) {
node.userData.name = nodeDef.name;
node.name = PropertyBinding.sanitizeNodeName( nodeDef.name );
}
assignExtrasToUserData( node, nodeDef );
if ( nodeDef.extensions ) addUnknownExtensionsToUserData( extensions, node, nodeDef );
if ( nodeDef.matrix !== undefined ) {
var matrix = new Matrix4();
matrix.fromArray( nodeDef.matrix );
node.applyMatrix4( matrix );
} else {
if ( nodeDef.translation !== undefined ) {
node.position.fromArray( nodeDef.translation );
}
if ( nodeDef.rotation !== undefined ) {
node.quaternion.fromArray( nodeDef.rotation );
}
if ( nodeDef.scale !== undefined ) {
node.scale.fromArray( nodeDef.scale );
}
}
return node;
} );
};
/**
* Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#scenes
* @param {number} sceneIndex
* @return {Promise<Group>}
*/
GLTFParser.prototype.loadScene = function () {
// scene node hierachy builder
function buildNodeHierachy( nodeId, parentObject, json, parser ) {
var nodeDef = json.nodes[ nodeId ];
return parser.getDependency( 'node', nodeId ).then( function ( node ) {
if ( nodeDef.skin === undefined ) return node;
// build skeleton here as well
var skinEntry;
return parser.getDependency( 'skin', nodeDef.skin ).then( function ( skin ) {
skinEntry = skin;
var pendingJoints = [];
for ( var i = 0, il = skinEntry.joints.length; i < il; i ++ ) {
pendingJoints.push( parser.getDependency( 'node', skinEntry.joints[ i ] ) );
}
return Promise.all( pendingJoints );
} ).then( function ( jointNodes ) {
node.traverse( function ( mesh ) {
if ( ! mesh.isMesh ) return;
var bones = [];
var boneInverses = [];
for ( var j = 0, jl = jointNodes.length; j < jl; j ++ ) {
var jointNode = jointNodes[ j ];
if ( jointNode ) {
bones.push( jointNode );
var mat = new Matrix4();
if ( skinEntry.inverseBindMatrices !== undefined ) {
mat.fromArray( skinEntry.inverseBindMatrices.array, j * 16 );
}
boneInverses.push( mat );
} else {
console.warn( 'THREE.GLTFLoader: Joint "%s" could not be found.', skinEntry.joints[ j ] );
}
}
mesh.bind( new Skeleton( bones, boneInverses ), mesh.matrixWorld );
} );
return node;
} );
} ).then( function ( node ) {
// build node hierachy
parentObject.add( node );
var pending = [];
if ( nodeDef.children ) {
var children = nodeDef.children;
for ( var i = 0, il = children.length; i < il; i ++ ) {
var child = children[ i ];
pending.push( buildNodeHierachy( child, node, json, parser ) );
}
}
return Promise.all( pending );
} );
}
return function loadScene( sceneIndex ) {
var json = this.json;
var extensions = this.extensions;
var sceneDef = this.json.scenes[ sceneIndex ];
var parser = this;
// Loader returns Group, not Scene.
// See: https://github.com/mrdoob/three.js/issues/18342#issuecomment-578981172
var scene = new Group();
if ( sceneDef.name ) scene.name = sceneDef.name;
assignExtrasToUserData( scene, sceneDef );
if ( sceneDef.extensions ) addUnknownExtensionsToUserData( extensions, scene, sceneDef );
var nodeIds = sceneDef.nodes || [];
var pending = [];
for ( var i = 0, il = nodeIds.length; i < il; i ++ ) {
pending.push( buildNodeHierachy( nodeIds[ i ], scene, json, parser ) );
}
return Promise.all( pending ).then( function () {
return scene;
} );
};
}();
return GLTFLoader;
} )()
Example #9
Source File: ColladaLoader.js From Computer-Graphics with MIT License | 4 votes |
parse( text, path ) {
function getElementsByTagName( xml, name ) {
// Non recursive xml.getElementsByTagName() ...
const array = [];
const childNodes = xml.childNodes;
for ( let i = 0, l = childNodes.length; i < l; i ++ ) {
const child = childNodes[ i ];
if ( child.nodeName === name ) {
array.push( child );
}
}
return array;
}
function parseStrings( text ) {
if ( text.length === 0 ) return [];
const parts = text.trim().split( /\s+/ );
const array = new Array( parts.length );
for ( let i = 0, l = parts.length; i < l; i ++ ) {
array[ i ] = parts[ i ];
}
return array;
}
function parseFloats( text ) {
if ( text.length === 0 ) return [];
const parts = text.trim().split( /\s+/ );
const array = new Array( parts.length );
for ( let i = 0, l = parts.length; i < l; i ++ ) {
array[ i ] = parseFloat( parts[ i ] );
}
return array;
}
function parseInts( text ) {
if ( text.length === 0 ) return [];
const parts = text.trim().split( /\s+/ );
const array = new Array( parts.length );
for ( let i = 0, l = parts.length; i < l; i ++ ) {
array[ i ] = parseInt( parts[ i ] );
}
return array;
}
function parseId( text ) {
return text.substring( 1 );
}
function generateId() {
return 'three_default_' + ( count ++ );
}
function isEmpty( object ) {
return Object.keys( object ).length === 0;
}
// asset
function parseAsset( xml ) {
return {
unit: parseAssetUnit( getElementsByTagName( xml, 'unit' )[ 0 ] ),
upAxis: parseAssetUpAxis( getElementsByTagName( xml, 'up_axis' )[ 0 ] )
};
}
function parseAssetUnit( xml ) {
if ( ( xml !== undefined ) && ( xml.hasAttribute( 'meter' ) === true ) ) {
return parseFloat( xml.getAttribute( 'meter' ) );
} else {
return 1; // default 1 meter
}
}
function parseAssetUpAxis( xml ) {
return xml !== undefined ? xml.textContent : 'Y_UP';
}
// library
function parseLibrary( xml, libraryName, nodeName, parser ) {
const library = getElementsByTagName( xml, libraryName )[ 0 ];
if ( library !== undefined ) {
const elements = getElementsByTagName( library, nodeName );
for ( let i = 0; i < elements.length; i ++ ) {
parser( elements[ i ] );
}
}
}
function buildLibrary( data, builder ) {
for ( const name in data ) {
const object = data[ name ];
object.build = builder( data[ name ] );
}
}
// get
function getBuild( data, builder ) {
if ( data.build !== undefined ) return data.build;
data.build = builder( data );
return data.build;
}
// animation
function parseAnimation( xml ) {
const data = {
sources: {},
samplers: {},
channels: {}
};
let hasChildren = false;
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
let id;
switch ( child.nodeName ) {
case 'source':
id = child.getAttribute( 'id' );
data.sources[ id ] = parseSource( child );
break;
case 'sampler':
id = child.getAttribute( 'id' );
data.samplers[ id ] = parseAnimationSampler( child );
break;
case 'channel':
id = child.getAttribute( 'target' );
data.channels[ id ] = parseAnimationChannel( child );
break;
case 'animation':
// hierarchy of related animations
parseAnimation( child );
hasChildren = true;
break;
default:
console.log( child );
}
}
if ( hasChildren === false ) {
// since 'id' attributes can be optional, it's necessary to generate a UUID for unqiue assignment
library.animations[ xml.getAttribute( 'id' ) || MathUtils.generateUUID() ] = data;
}
}
function parseAnimationSampler( xml ) {
const data = {
inputs: {},
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'input':
const id = parseId( child.getAttribute( 'source' ) );
const semantic = child.getAttribute( 'semantic' );
data.inputs[ semantic ] = id;
break;
}
}
return data;
}
function parseAnimationChannel( xml ) {
const data = {};
const target = xml.getAttribute( 'target' );
// parsing SID Addressing Syntax
let parts = target.split( '/' );
const id = parts.shift();
let sid = parts.shift();
// check selection syntax
const arraySyntax = ( sid.indexOf( '(' ) !== - 1 );
const memberSyntax = ( sid.indexOf( '.' ) !== - 1 );
if ( memberSyntax ) {
// member selection access
parts = sid.split( '.' );
sid = parts.shift();
data.member = parts.shift();
} else if ( arraySyntax ) {
// array-access syntax. can be used to express fields in one-dimensional vectors or two-dimensional matrices.
const indices = sid.split( '(' );
sid = indices.shift();
for ( let i = 0; i < indices.length; i ++ ) {
indices[ i ] = parseInt( indices[ i ].replace( /\)/, '' ) );
}
data.indices = indices;
}
data.id = id;
data.sid = sid;
data.arraySyntax = arraySyntax;
data.memberSyntax = memberSyntax;
data.sampler = parseId( xml.getAttribute( 'source' ) );
return data;
}
function buildAnimation( data ) {
const tracks = [];
const channels = data.channels;
const samplers = data.samplers;
const sources = data.sources;
for ( const target in channels ) {
if ( channels.hasOwnProperty( target ) ) {
const channel = channels[ target ];
const sampler = samplers[ channel.sampler ];
const inputId = sampler.inputs.INPUT;
const outputId = sampler.inputs.OUTPUT;
const inputSource = sources[ inputId ];
const outputSource = sources[ outputId ];
const animation = buildAnimationChannel( channel, inputSource, outputSource );
createKeyframeTracks( animation, tracks );
}
}
return tracks;
}
function getAnimation( id ) {
return getBuild( library.animations[ id ], buildAnimation );
}
function buildAnimationChannel( channel, inputSource, outputSource ) {
const node = library.nodes[ channel.id ];
const object3D = getNode( node.id );
const transform = node.transforms[ channel.sid ];
const defaultMatrix = node.matrix.clone().transpose();
let time, stride;
let i, il, j, jl;
const data = {};
// the collada spec allows the animation of data in various ways.
// depending on the transform type (matrix, translate, rotate, scale), we execute different logic
switch ( transform ) {
case 'matrix':
for ( i = 0, il = inputSource.array.length; i < il; i ++ ) {
time = inputSource.array[ i ];
stride = i * outputSource.stride;
if ( data[ time ] === undefined ) data[ time ] = {};
if ( channel.arraySyntax === true ) {
const value = outputSource.array[ stride ];
const index = channel.indices[ 0 ] + 4 * channel.indices[ 1 ];
data[ time ][ index ] = value;
} else {
for ( j = 0, jl = outputSource.stride; j < jl; j ++ ) {
data[ time ][ j ] = outputSource.array[ stride + j ];
}
}
}
break;
case 'translate':
console.warn( 'THREE.ColladaLoader: Animation transform type "%s" not yet implemented.', transform );
break;
case 'rotate':
console.warn( 'THREE.ColladaLoader: Animation transform type "%s" not yet implemented.', transform );
break;
case 'scale':
console.warn( 'THREE.ColladaLoader: Animation transform type "%s" not yet implemented.', transform );
break;
}
const keyframes = prepareAnimationData( data, defaultMatrix );
const animation = {
name: object3D.uuid,
keyframes: keyframes
};
return animation;
}
function prepareAnimationData( data, defaultMatrix ) {
const keyframes = [];
// transfer data into a sortable array
for ( const time in data ) {
keyframes.push( { time: parseFloat( time ), value: data[ time ] } );
}
// ensure keyframes are sorted by time
keyframes.sort( ascending );
// now we clean up all animation data, so we can use them for keyframe tracks
for ( let i = 0; i < 16; i ++ ) {
transformAnimationData( keyframes, i, defaultMatrix.elements[ i ] );
}
return keyframes;
// array sort function
function ascending( a, b ) {
return a.time - b.time;
}
}
const position = new Vector3();
const scale = new Vector3();
const quaternion = new Quaternion();
function createKeyframeTracks( animation, tracks ) {
const keyframes = animation.keyframes;
const name = animation.name;
const times = [];
const positionData = [];
const quaternionData = [];
const scaleData = [];
for ( let i = 0, l = keyframes.length; i < l; i ++ ) {
const keyframe = keyframes[ i ];
const time = keyframe.time;
const value = keyframe.value;
matrix.fromArray( value ).transpose();
matrix.decompose( position, quaternion, scale );
times.push( time );
positionData.push( position.x, position.y, position.z );
quaternionData.push( quaternion.x, quaternion.y, quaternion.z, quaternion.w );
scaleData.push( scale.x, scale.y, scale.z );
}
if ( positionData.length > 0 ) tracks.push( new VectorKeyframeTrack( name + '.position', times, positionData ) );
if ( quaternionData.length > 0 ) tracks.push( new QuaternionKeyframeTrack( name + '.quaternion', times, quaternionData ) );
if ( scaleData.length > 0 ) tracks.push( new VectorKeyframeTrack( name + '.scale', times, scaleData ) );
return tracks;
}
function transformAnimationData( keyframes, property, defaultValue ) {
let keyframe;
let empty = true;
let i, l;
// check, if values of a property are missing in our keyframes
for ( i = 0, l = keyframes.length; i < l; i ++ ) {
keyframe = keyframes[ i ];
if ( keyframe.value[ property ] === undefined ) {
keyframe.value[ property ] = null; // mark as missing
} else {
empty = false;
}
}
if ( empty === true ) {
// no values at all, so we set a default value
for ( i = 0, l = keyframes.length; i < l; i ++ ) {
keyframe = keyframes[ i ];
keyframe.value[ property ] = defaultValue;
}
} else {
// filling gaps
createMissingKeyframes( keyframes, property );
}
}
function createMissingKeyframes( keyframes, property ) {
let prev, next;
for ( let i = 0, l = keyframes.length; i < l; i ++ ) {
const keyframe = keyframes[ i ];
if ( keyframe.value[ property ] === null ) {
prev = getPrev( keyframes, i, property );
next = getNext( keyframes, i, property );
if ( prev === null ) {
keyframe.value[ property ] = next.value[ property ];
continue;
}
if ( next === null ) {
keyframe.value[ property ] = prev.value[ property ];
continue;
}
interpolate( keyframe, prev, next, property );
}
}
}
function getPrev( keyframes, i, property ) {
while ( i >= 0 ) {
const keyframe = keyframes[ i ];
if ( keyframe.value[ property ] !== null ) return keyframe;
i --;
}
return null;
}
function getNext( keyframes, i, property ) {
while ( i < keyframes.length ) {
const keyframe = keyframes[ i ];
if ( keyframe.value[ property ] !== null ) return keyframe;
i ++;
}
return null;
}
function interpolate( key, prev, next, property ) {
if ( ( next.time - prev.time ) === 0 ) {
key.value[ property ] = prev.value[ property ];
return;
}
key.value[ property ] = ( ( key.time - prev.time ) * ( next.value[ property ] - prev.value[ property ] ) / ( next.time - prev.time ) ) + prev.value[ property ];
}
// animation clips
function parseAnimationClip( xml ) {
const data = {
name: xml.getAttribute( 'id' ) || 'default',
start: parseFloat( xml.getAttribute( 'start' ) || 0 ),
end: parseFloat( xml.getAttribute( 'end' ) || 0 ),
animations: []
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'instance_animation':
data.animations.push( parseId( child.getAttribute( 'url' ) ) );
break;
}
}
library.clips[ xml.getAttribute( 'id' ) ] = data;
}
function buildAnimationClip( data ) {
const tracks = [];
const name = data.name;
const duration = ( data.end - data.start ) || - 1;
const animations = data.animations;
for ( let i = 0, il = animations.length; i < il; i ++ ) {
const animationTracks = getAnimation( animations[ i ] );
for ( let j = 0, jl = animationTracks.length; j < jl; j ++ ) {
tracks.push( animationTracks[ j ] );
}
}
return new AnimationClip( name, duration, tracks );
}
function getAnimationClip( id ) {
return getBuild( library.clips[ id ], buildAnimationClip );
}
// controller
function parseController( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'skin':
// there is exactly one skin per controller
data.id = parseId( child.getAttribute( 'source' ) );
data.skin = parseSkin( child );
break;
case 'morph':
data.id = parseId( child.getAttribute( 'source' ) );
console.warn( 'THREE.ColladaLoader: Morph target animation not supported yet.' );
break;
}
}
library.controllers[ xml.getAttribute( 'id' ) ] = data;
}
function parseSkin( xml ) {
const data = {
sources: {}
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'bind_shape_matrix':
data.bindShapeMatrix = parseFloats( child.textContent );
break;
case 'source':
const id = child.getAttribute( 'id' );
data.sources[ id ] = parseSource( child );
break;
case 'joints':
data.joints = parseJoints( child );
break;
case 'vertex_weights':
data.vertexWeights = parseVertexWeights( child );
break;
}
}
return data;
}
function parseJoints( xml ) {
const data = {
inputs: {}
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'input':
const semantic = child.getAttribute( 'semantic' );
const id = parseId( child.getAttribute( 'source' ) );
data.inputs[ semantic ] = id;
break;
}
}
return data;
}
function parseVertexWeights( xml ) {
const data = {
inputs: {}
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'input':
const semantic = child.getAttribute( 'semantic' );
const id = parseId( child.getAttribute( 'source' ) );
const offset = parseInt( child.getAttribute( 'offset' ) );
data.inputs[ semantic ] = { id: id, offset: offset };
break;
case 'vcount':
data.vcount = parseInts( child.textContent );
break;
case 'v':
data.v = parseInts( child.textContent );
break;
}
}
return data;
}
function buildController( data ) {
const build = {
id: data.id
};
const geometry = library.geometries[ build.id ];
if ( data.skin !== undefined ) {
build.skin = buildSkin( data.skin );
// we enhance the 'sources' property of the corresponding geometry with our skin data
geometry.sources.skinIndices = build.skin.indices;
geometry.sources.skinWeights = build.skin.weights;
}
return build;
}
function buildSkin( data ) {
const BONE_LIMIT = 4;
const build = {
joints: [], // this must be an array to preserve the joint order
indices: {
array: [],
stride: BONE_LIMIT
},
weights: {
array: [],
stride: BONE_LIMIT
}
};
const sources = data.sources;
const vertexWeights = data.vertexWeights;
const vcount = vertexWeights.vcount;
const v = vertexWeights.v;
const jointOffset = vertexWeights.inputs.JOINT.offset;
const weightOffset = vertexWeights.inputs.WEIGHT.offset;
const jointSource = data.sources[ data.joints.inputs.JOINT ];
const inverseSource = data.sources[ data.joints.inputs.INV_BIND_MATRIX ];
const weights = sources[ vertexWeights.inputs.WEIGHT.id ].array;
let stride = 0;
let i, j, l;
// procces skin data for each vertex
for ( i = 0, l = vcount.length; i < l; i ++ ) {
const jointCount = vcount[ i ]; // this is the amount of joints that affect a single vertex
const vertexSkinData = [];
for ( j = 0; j < jointCount; j ++ ) {
const skinIndex = v[ stride + jointOffset ];
const weightId = v[ stride + weightOffset ];
const skinWeight = weights[ weightId ];
vertexSkinData.push( { index: skinIndex, weight: skinWeight } );
stride += 2;
}
// we sort the joints in descending order based on the weights.
// this ensures, we only procced the most important joints of the vertex
vertexSkinData.sort( descending );
// now we provide for each vertex a set of four index and weight values.
// the order of the skin data matches the order of vertices
for ( j = 0; j < BONE_LIMIT; j ++ ) {
const d = vertexSkinData[ j ];
if ( d !== undefined ) {
build.indices.array.push( d.index );
build.weights.array.push( d.weight );
} else {
build.indices.array.push( 0 );
build.weights.array.push( 0 );
}
}
}
// setup bind matrix
if ( data.bindShapeMatrix ) {
build.bindMatrix = new Matrix4().fromArray( data.bindShapeMatrix ).transpose();
} else {
build.bindMatrix = new Matrix4().identity();
}
// process bones and inverse bind matrix data
for ( i = 0, l = jointSource.array.length; i < l; i ++ ) {
const name = jointSource.array[ i ];
const boneInverse = new Matrix4().fromArray( inverseSource.array, i * inverseSource.stride ).transpose();
build.joints.push( { name: name, boneInverse: boneInverse } );
}
return build;
// array sort function
function descending( a, b ) {
return b.weight - a.weight;
}
}
function getController( id ) {
return getBuild( library.controllers[ id ], buildController );
}
// image
function parseImage( xml ) {
const data = {
init_from: getElementsByTagName( xml, 'init_from' )[ 0 ].textContent
};
library.images[ xml.getAttribute( 'id' ) ] = data;
}
function buildImage( data ) {
if ( data.build !== undefined ) return data.build;
return data.init_from;
}
function getImage( id ) {
const data = library.images[ id ];
if ( data !== undefined ) {
return getBuild( data, buildImage );
}
console.warn( 'THREE.ColladaLoader: Couldn\'t find image with ID:', id );
return null;
}
// effect
function parseEffect( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'profile_COMMON':
data.profile = parseEffectProfileCOMMON( child );
break;
}
}
library.effects[ xml.getAttribute( 'id' ) ] = data;
}
function parseEffectProfileCOMMON( xml ) {
const data = {
surfaces: {},
samplers: {}
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'newparam':
parseEffectNewparam( child, data );
break;
case 'technique':
data.technique = parseEffectTechnique( child );
break;
case 'extra':
data.extra = parseEffectExtra( child );
break;
}
}
return data;
}
function parseEffectNewparam( xml, data ) {
const sid = xml.getAttribute( 'sid' );
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'surface':
data.surfaces[ sid ] = parseEffectSurface( child );
break;
case 'sampler2D':
data.samplers[ sid ] = parseEffectSampler( child );
break;
}
}
}
function parseEffectSurface( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'init_from':
data.init_from = child.textContent;
break;
}
}
return data;
}
function parseEffectSampler( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'source':
data.source = child.textContent;
break;
}
}
return data;
}
function parseEffectTechnique( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'constant':
case 'lambert':
case 'blinn':
case 'phong':
data.type = child.nodeName;
data.parameters = parseEffectParameters( child );
break;
case 'extra':
data.extra = parseEffectExtra( child );
break;
}
}
return data;
}
function parseEffectParameters( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'emission':
case 'diffuse':
case 'specular':
case 'bump':
case 'ambient':
case 'shininess':
case 'transparency':
data[ child.nodeName ] = parseEffectParameter( child );
break;
case 'transparent':
data[ child.nodeName ] = {
opaque: child.hasAttribute( 'opaque' ) ? child.getAttribute( 'opaque' ) : 'A_ONE',
data: parseEffectParameter( child )
};
break;
}
}
return data;
}
function parseEffectParameter( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'color':
data[ child.nodeName ] = parseFloats( child.textContent );
break;
case 'float':
data[ child.nodeName ] = parseFloat( child.textContent );
break;
case 'texture':
data[ child.nodeName ] = { id: child.getAttribute( 'texture' ), extra: parseEffectParameterTexture( child ) };
break;
}
}
return data;
}
function parseEffectParameterTexture( xml ) {
const data = {
technique: {}
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'extra':
parseEffectParameterTextureExtra( child, data );
break;
}
}
return data;
}
function parseEffectParameterTextureExtra( xml, data ) {
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'technique':
parseEffectParameterTextureExtraTechnique( child, data );
break;
}
}
}
function parseEffectParameterTextureExtraTechnique( xml, data ) {
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'repeatU':
case 'repeatV':
case 'offsetU':
case 'offsetV':
data.technique[ child.nodeName ] = parseFloat( child.textContent );
break;
case 'wrapU':
case 'wrapV':
// some files have values for wrapU/wrapV which become NaN via parseInt
if ( child.textContent.toUpperCase() === 'TRUE' ) {
data.technique[ child.nodeName ] = 1;
} else if ( child.textContent.toUpperCase() === 'FALSE' ) {
data.technique[ child.nodeName ] = 0;
} else {
data.technique[ child.nodeName ] = parseInt( child.textContent );
}
break;
case 'bump':
data[ child.nodeName ] = parseEffectExtraTechniqueBump( child );
break;
}
}
}
function parseEffectExtra( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'technique':
data.technique = parseEffectExtraTechnique( child );
break;
}
}
return data;
}
function parseEffectExtraTechnique( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'double_sided':
data[ child.nodeName ] = parseInt( child.textContent );
break;
case 'bump':
data[ child.nodeName ] = parseEffectExtraTechniqueBump( child );
break;
}
}
return data;
}
function parseEffectExtraTechniqueBump( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'texture':
data[ child.nodeName ] = { id: child.getAttribute( 'texture' ), texcoord: child.getAttribute( 'texcoord' ), extra: parseEffectParameterTexture( child ) };
break;
}
}
return data;
}
function buildEffect( data ) {
return data;
}
function getEffect( id ) {
return getBuild( library.effects[ id ], buildEffect );
}
// material
function parseMaterial( xml ) {
const data = {
name: xml.getAttribute( 'name' )
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'instance_effect':
data.url = parseId( child.getAttribute( 'url' ) );
break;
}
}
library.materials[ xml.getAttribute( 'id' ) ] = data;
}
function getTextureLoader( image ) {
let loader;
let extension = image.slice( ( image.lastIndexOf( '.' ) - 1 >>> 0 ) + 2 ); // http://www.jstips.co/en/javascript/get-file-extension/
extension = extension.toLowerCase();
switch ( extension ) {
case 'tga':
loader = tgaLoader;
break;
default:
loader = textureLoader;
}
return loader;
}
function buildMaterial( data ) {
const effect = getEffect( data.url );
const technique = effect.profile.technique;
let material;
switch ( technique.type ) {
case 'phong':
case 'blinn':
material = new MeshPhongMaterial();
break;
case 'lambert':
material = new MeshLambertMaterial();
break;
default:
material = new MeshBasicMaterial();
break;
}
material.name = data.name || '';
function getTexture( textureObject, encoding = null ) {
const sampler = effect.profile.samplers[ textureObject.id ];
let image = null;
// get image
if ( sampler !== undefined ) {
const surface = effect.profile.surfaces[ sampler.source ];
image = getImage( surface.init_from );
} else {
console.warn( 'THREE.ColladaLoader: Undefined sampler. Access image directly (see #12530).' );
image = getImage( textureObject.id );
}
// create texture if image is avaiable
if ( image !== null ) {
const loader = getTextureLoader( image );
if ( loader !== undefined ) {
const texture = loader.load( image );
const extra = textureObject.extra;
if ( extra !== undefined && extra.technique !== undefined && isEmpty( extra.technique ) === false ) {
const technique = extra.technique;
texture.wrapS = technique.wrapU ? RepeatWrapping : ClampToEdgeWrapping;
texture.wrapT = technique.wrapV ? RepeatWrapping : ClampToEdgeWrapping;
texture.offset.set( technique.offsetU || 0, technique.offsetV || 0 );
texture.repeat.set( technique.repeatU || 1, technique.repeatV || 1 );
} else {
texture.wrapS = RepeatWrapping;
texture.wrapT = RepeatWrapping;
}
if ( encoding !== null ) {
texture.encoding = encoding;
}
return texture;
} else {
console.warn( 'THREE.ColladaLoader: Loader for texture %s not found.', image );
return null;
}
} else {
console.warn( 'THREE.ColladaLoader: Couldn\'t create texture with ID:', textureObject.id );
return null;
}
}
const parameters = technique.parameters;
for ( const key in parameters ) {
const parameter = parameters[ key ];
switch ( key ) {
case 'diffuse':
if ( parameter.color ) material.color.fromArray( parameter.color );
if ( parameter.texture ) material.map = getTexture( parameter.texture, sRGBEncoding );
break;
case 'specular':
if ( parameter.color && material.specular ) material.specular.fromArray( parameter.color );
if ( parameter.texture ) material.specularMap = getTexture( parameter.texture );
break;
case 'bump':
if ( parameter.texture ) material.normalMap = getTexture( parameter.texture );
break;
case 'ambient':
if ( parameter.texture ) material.lightMap = getTexture( parameter.texture, sRGBEncoding );
break;
case 'shininess':
if ( parameter.float && material.shininess ) material.shininess = parameter.float;
break;
case 'emission':
if ( parameter.color && material.emissive ) material.emissive.fromArray( parameter.color );
if ( parameter.texture ) material.emissiveMap = getTexture( parameter.texture, sRGBEncoding );
break;
}
}
material.color.convertSRGBToLinear();
if ( material.specular ) material.specular.convertSRGBToLinear();
if ( material.emissive ) material.emissive.convertSRGBToLinear();
//
let transparent = parameters[ 'transparent' ];
let transparency = parameters[ 'transparency' ];
// <transparency> does not exist but <transparent>
if ( transparency === undefined && transparent ) {
transparency = {
float: 1
};
}
// <transparent> does not exist but <transparency>
if ( transparent === undefined && transparency ) {
transparent = {
opaque: 'A_ONE',
data: {
color: [ 1, 1, 1, 1 ]
} };
}
if ( transparent && transparency ) {
// handle case if a texture exists but no color
if ( transparent.data.texture ) {
// we do not set an alpha map (see #13792)
material.transparent = true;
} else {
const color = transparent.data.color;
switch ( transparent.opaque ) {
case 'A_ONE':
material.opacity = color[ 3 ] * transparency.float;
break;
case 'RGB_ZERO':
material.opacity = 1 - ( color[ 0 ] * transparency.float );
break;
case 'A_ZERO':
material.opacity = 1 - ( color[ 3 ] * transparency.float );
break;
case 'RGB_ONE':
material.opacity = color[ 0 ] * transparency.float;
break;
default:
console.warn( 'THREE.ColladaLoader: Invalid opaque type "%s" of transparent tag.', transparent.opaque );
}
if ( material.opacity < 1 ) material.transparent = true;
}
}
//
if ( technique.extra !== undefined && technique.extra.technique !== undefined ) {
const techniques = technique.extra.technique;
for ( const k in techniques ) {
const v = techniques[ k ];
switch ( k ) {
case 'double_sided':
material.side = ( v === 1 ? DoubleSide : FrontSide );
break;
case 'bump':
material.normalMap = getTexture( v.texture );
material.normalScale = new Vector2( 1, 1 );
break;
}
}
}
return material;
}
function getMaterial( id ) {
return getBuild( library.materials[ id ], buildMaterial );
}
// camera
function parseCamera( xml ) {
const data = {
name: xml.getAttribute( 'name' )
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'optics':
data.optics = parseCameraOptics( child );
break;
}
}
library.cameras[ xml.getAttribute( 'id' ) ] = data;
}
function parseCameraOptics( xml ) {
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
switch ( child.nodeName ) {
case 'technique_common':
return parseCameraTechnique( child );
}
}
return {};
}
function parseCameraTechnique( xml ) {
const data = {};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
switch ( child.nodeName ) {
case 'perspective':
case 'orthographic':
data.technique = child.nodeName;
data.parameters = parseCameraParameters( child );
break;
}
}
return data;
}
function parseCameraParameters( xml ) {
const data = {};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
switch ( child.nodeName ) {
case 'xfov':
case 'yfov':
case 'xmag':
case 'ymag':
case 'znear':
case 'zfar':
case 'aspect_ratio':
data[ child.nodeName ] = parseFloat( child.textContent );
break;
}
}
return data;
}
function buildCamera( data ) {
let camera;
switch ( data.optics.technique ) {
case 'perspective':
camera = new PerspectiveCamera(
data.optics.parameters.yfov,
data.optics.parameters.aspect_ratio,
data.optics.parameters.znear,
data.optics.parameters.zfar
);
break;
case 'orthographic':
let ymag = data.optics.parameters.ymag;
let xmag = data.optics.parameters.xmag;
const aspectRatio = data.optics.parameters.aspect_ratio;
xmag = ( xmag === undefined ) ? ( ymag * aspectRatio ) : xmag;
ymag = ( ymag === undefined ) ? ( xmag / aspectRatio ) : ymag;
xmag *= 0.5;
ymag *= 0.5;
camera = new OrthographicCamera(
- xmag, xmag, ymag, - ymag, // left, right, top, bottom
data.optics.parameters.znear,
data.optics.parameters.zfar
);
break;
default:
camera = new PerspectiveCamera();
break;
}
camera.name = data.name || '';
return camera;
}
function getCamera( id ) {
const data = library.cameras[ id ];
if ( data !== undefined ) {
return getBuild( data, buildCamera );
}
console.warn( 'THREE.ColladaLoader: Couldn\'t find camera with ID:', id );
return null;
}
// light
function parseLight( xml ) {
let data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'technique_common':
data = parseLightTechnique( child );
break;
}
}
library.lights[ xml.getAttribute( 'id' ) ] = data;
}
function parseLightTechnique( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'directional':
case 'point':
case 'spot':
case 'ambient':
data.technique = child.nodeName;
data.parameters = parseLightParameters( child );
}
}
return data;
}
function parseLightParameters( xml ) {
const data = {};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'color':
const array = parseFloats( child.textContent );
data.color = new Color().fromArray( array ).convertSRGBToLinear();
break;
case 'falloff_angle':
data.falloffAngle = parseFloat( child.textContent );
break;
case 'quadratic_attenuation':
const f = parseFloat( child.textContent );
data.distance = f ? Math.sqrt( 1 / f ) : 0;
break;
}
}
return data;
}
function buildLight( data ) {
let light;
switch ( data.technique ) {
case 'directional':
light = new DirectionalLight();
break;
case 'point':
light = new PointLight();
break;
case 'spot':
light = new SpotLight();
break;
case 'ambient':
light = new AmbientLight();
break;
}
if ( data.parameters.color ) light.color.copy( data.parameters.color );
if ( data.parameters.distance ) light.distance = data.parameters.distance;
return light;
}
function getLight( id ) {
const data = library.lights[ id ];
if ( data !== undefined ) {
return getBuild( data, buildLight );
}
console.warn( 'THREE.ColladaLoader: Couldn\'t find light with ID:', id );
return null;
}
// geometry
function parseGeometry( xml ) {
const data = {
name: xml.getAttribute( 'name' ),
sources: {},
vertices: {},
primitives: []
};
const mesh = getElementsByTagName( xml, 'mesh' )[ 0 ];
// the following tags inside geometry are not supported yet (see https://github.com/mrdoob/three.js/pull/12606): convex_mesh, spline, brep
if ( mesh === undefined ) return;
for ( let i = 0; i < mesh.childNodes.length; i ++ ) {
const child = mesh.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
const id = child.getAttribute( 'id' );
switch ( child.nodeName ) {
case 'source':
data.sources[ id ] = parseSource( child );
break;
case 'vertices':
// data.sources[ id ] = data.sources[ parseId( getElementsByTagName( child, 'input' )[ 0 ].getAttribute( 'source' ) ) ];
data.vertices = parseGeometryVertices( child );
break;
case 'polygons':
console.warn( 'THREE.ColladaLoader: Unsupported primitive type: ', child.nodeName );
break;
case 'lines':
case 'linestrips':
case 'polylist':
case 'triangles':
data.primitives.push( parseGeometryPrimitive( child ) );
break;
default:
console.log( child );
}
}
library.geometries[ xml.getAttribute( 'id' ) ] = data;
}
function parseSource( xml ) {
const data = {
array: [],
stride: 3
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'float_array':
data.array = parseFloats( child.textContent );
break;
case 'Name_array':
data.array = parseStrings( child.textContent );
break;
case 'technique_common':
const accessor = getElementsByTagName( child, 'accessor' )[ 0 ];
if ( accessor !== undefined ) {
data.stride = parseInt( accessor.getAttribute( 'stride' ) );
}
break;
}
}
return data;
}
function parseGeometryVertices( xml ) {
const data = {};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
data[ child.getAttribute( 'semantic' ) ] = parseId( child.getAttribute( 'source' ) );
}
return data;
}
function parseGeometryPrimitive( xml ) {
const primitive = {
type: xml.nodeName,
material: xml.getAttribute( 'material' ),
count: parseInt( xml.getAttribute( 'count' ) ),
inputs: {},
stride: 0,
hasUV: false
};
for ( let i = 0, l = xml.childNodes.length; i < l; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'input':
const id = parseId( child.getAttribute( 'source' ) );
const semantic = child.getAttribute( 'semantic' );
const offset = parseInt( child.getAttribute( 'offset' ) );
const set = parseInt( child.getAttribute( 'set' ) );
const inputname = ( set > 0 ? semantic + set : semantic );
primitive.inputs[ inputname ] = { id: id, offset: offset };
primitive.stride = Math.max( primitive.stride, offset + 1 );
if ( semantic === 'TEXCOORD' ) primitive.hasUV = true;
break;
case 'vcount':
primitive.vcount = parseInts( child.textContent );
break;
case 'p':
primitive.p = parseInts( child.textContent );
break;
}
}
return primitive;
}
function groupPrimitives( primitives ) {
const build = {};
for ( let i = 0; i < primitives.length; i ++ ) {
const primitive = primitives[ i ];
if ( build[ primitive.type ] === undefined ) build[ primitive.type ] = [];
build[ primitive.type ].push( primitive );
}
return build;
}
function checkUVCoordinates( primitives ) {
let count = 0;
for ( let i = 0, l = primitives.length; i < l; i ++ ) {
const primitive = primitives[ i ];
if ( primitive.hasUV === true ) {
count ++;
}
}
if ( count > 0 && count < primitives.length ) {
primitives.uvsNeedsFix = true;
}
}
function buildGeometry( data ) {
const build = {};
const sources = data.sources;
const vertices = data.vertices;
const primitives = data.primitives;
if ( primitives.length === 0 ) return {};
// our goal is to create one buffer geometry for a single type of primitives
// first, we group all primitives by their type
const groupedPrimitives = groupPrimitives( primitives );
for ( const type in groupedPrimitives ) {
const primitiveType = groupedPrimitives[ type ];
// second, ensure consistent uv coordinates for each type of primitives (polylist,triangles or lines)
checkUVCoordinates( primitiveType );
// third, create a buffer geometry for each type of primitives
build[ type ] = buildGeometryType( primitiveType, sources, vertices );
}
return build;
}
function buildGeometryType( primitives, sources, vertices ) {
const build = {};
const position = { array: [], stride: 0 };
const normal = { array: [], stride: 0 };
const uv = { array: [], stride: 0 };
const uv2 = { array: [], stride: 0 };
const color = { array: [], stride: 0 };
const skinIndex = { array: [], stride: 4 };
const skinWeight = { array: [], stride: 4 };
const geometry = new BufferGeometry();
const materialKeys = [];
let start = 0;
for ( let p = 0; p < primitives.length; p ++ ) {
const primitive = primitives[ p ];
const inputs = primitive.inputs;
// groups
let count = 0;
switch ( primitive.type ) {
case 'lines':
case 'linestrips':
count = primitive.count * 2;
break;
case 'triangles':
count = primitive.count * 3;
break;
case 'polylist':
for ( let g = 0; g < primitive.count; g ++ ) {
const vc = primitive.vcount[ g ];
switch ( vc ) {
case 3:
count += 3; // single triangle
break;
case 4:
count += 6; // quad, subdivided into two triangles
break;
default:
count += ( vc - 2 ) * 3; // polylist with more than four vertices
break;
}
}
break;
default:
console.warn( 'THREE.ColladaLoader: Unknow primitive type:', primitive.type );
}
geometry.addGroup( start, count, p );
start += count;
// material
if ( primitive.material ) {
materialKeys.push( primitive.material );
}
// geometry data
for ( const name in inputs ) {
const input = inputs[ name ];
switch ( name ) {
case 'VERTEX':
for ( const key in vertices ) {
const id = vertices[ key ];
switch ( key ) {
case 'POSITION':
const prevLength = position.array.length;
buildGeometryData( primitive, sources[ id ], input.offset, position.array );
position.stride = sources[ id ].stride;
if ( sources.skinWeights && sources.skinIndices ) {
buildGeometryData( primitive, sources.skinIndices, input.offset, skinIndex.array );
buildGeometryData( primitive, sources.skinWeights, input.offset, skinWeight.array );
}
// see #3803
if ( primitive.hasUV === false && primitives.uvsNeedsFix === true ) {
const count = ( position.array.length - prevLength ) / position.stride;
for ( let i = 0; i < count; i ++ ) {
// fill missing uv coordinates
uv.array.push( 0, 0 );
}
}
break;
case 'NORMAL':
buildGeometryData( primitive, sources[ id ], input.offset, normal.array );
normal.stride = sources[ id ].stride;
break;
case 'COLOR':
buildGeometryData( primitive, sources[ id ], input.offset, color.array );
color.stride = sources[ id ].stride;
break;
case 'TEXCOORD':
buildGeometryData( primitive, sources[ id ], input.offset, uv.array );
uv.stride = sources[ id ].stride;
break;
case 'TEXCOORD1':
buildGeometryData( primitive, sources[ id ], input.offset, uv2.array );
uv.stride = sources[ id ].stride;
break;
default:
console.warn( 'THREE.ColladaLoader: Semantic "%s" not handled in geometry build process.', key );
}
}
break;
case 'NORMAL':
buildGeometryData( primitive, sources[ input.id ], input.offset, normal.array );
normal.stride = sources[ input.id ].stride;
break;
case 'COLOR':
buildGeometryData( primitive, sources[ input.id ], input.offset, color.array, true );
color.stride = sources[ input.id ].stride;
break;
case 'TEXCOORD':
buildGeometryData( primitive, sources[ input.id ], input.offset, uv.array );
uv.stride = sources[ input.id ].stride;
break;
case 'TEXCOORD1':
buildGeometryData( primitive, sources[ input.id ], input.offset, uv2.array );
uv2.stride = sources[ input.id ].stride;
break;
}
}
}
// build geometry
if ( position.array.length > 0 ) geometry.setAttribute( 'position', new Float32BufferAttribute( position.array, position.stride ) );
if ( normal.array.length > 0 ) geometry.setAttribute( 'normal', new Float32BufferAttribute( normal.array, normal.stride ) );
if ( color.array.length > 0 ) geometry.setAttribute( 'color', new Float32BufferAttribute( color.array, color.stride ) );
if ( uv.array.length > 0 ) geometry.setAttribute( 'uv', new Float32BufferAttribute( uv.array, uv.stride ) );
if ( uv2.array.length > 0 ) geometry.setAttribute( 'uv2', new Float32BufferAttribute( uv2.array, uv2.stride ) );
if ( skinIndex.array.length > 0 ) geometry.setAttribute( 'skinIndex', new Float32BufferAttribute( skinIndex.array, skinIndex.stride ) );
if ( skinWeight.array.length > 0 ) geometry.setAttribute( 'skinWeight', new Float32BufferAttribute( skinWeight.array, skinWeight.stride ) );
build.data = geometry;
build.type = primitives[ 0 ].type;
build.materialKeys = materialKeys;
return build;
}
function buildGeometryData( primitive, source, offset, array, isColor = false ) {
const indices = primitive.p;
const stride = primitive.stride;
const vcount = primitive.vcount;
function pushVector( i ) {
let index = indices[ i + offset ] * sourceStride;
const length = index + sourceStride;
for ( ; index < length; index ++ ) {
array.push( sourceArray[ index ] );
}
if ( isColor ) {
// convert the vertex colors from srgb to linear if present
const startIndex = array.length - sourceStride - 1;
tempColor.setRGB(
array[ startIndex + 0 ],
array[ startIndex + 1 ],
array[ startIndex + 2 ]
).convertSRGBToLinear();
array[ startIndex + 0 ] = tempColor.r;
array[ startIndex + 1 ] = tempColor.g;
array[ startIndex + 2 ] = tempColor.b;
}
}
const sourceArray = source.array;
const sourceStride = source.stride;
if ( primitive.vcount !== undefined ) {
let index = 0;
for ( let i = 0, l = vcount.length; i < l; i ++ ) {
const count = vcount[ i ];
if ( count === 4 ) {
const a = index + stride * 0;
const b = index + stride * 1;
const c = index + stride * 2;
const d = index + stride * 3;
pushVector( a ); pushVector( b ); pushVector( d );
pushVector( b ); pushVector( c ); pushVector( d );
} else if ( count === 3 ) {
const a = index + stride * 0;
const b = index + stride * 1;
const c = index + stride * 2;
pushVector( a ); pushVector( b ); pushVector( c );
} else if ( count > 4 ) {
for ( let k = 1, kl = ( count - 2 ); k <= kl; k ++ ) {
const a = index + stride * 0;
const b = index + stride * k;
const c = index + stride * ( k + 1 );
pushVector( a ); pushVector( b ); pushVector( c );
}
}
index += stride * count;
}
} else {
for ( let i = 0, l = indices.length; i < l; i += stride ) {
pushVector( i );
}
}
}
function getGeometry( id ) {
return getBuild( library.geometries[ id ], buildGeometry );
}
// kinematics
function parseKinematicsModel( xml ) {
const data = {
name: xml.getAttribute( 'name' ) || '',
joints: {},
links: []
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'technique_common':
parseKinematicsTechniqueCommon( child, data );
break;
}
}
library.kinematicsModels[ xml.getAttribute( 'id' ) ] = data;
}
function buildKinematicsModel( data ) {
if ( data.build !== undefined ) return data.build;
return data;
}
function getKinematicsModel( id ) {
return getBuild( library.kinematicsModels[ id ], buildKinematicsModel );
}
function parseKinematicsTechniqueCommon( xml, data ) {
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'joint':
data.joints[ child.getAttribute( 'sid' ) ] = parseKinematicsJoint( child );
break;
case 'link':
data.links.push( parseKinematicsLink( child ) );
break;
}
}
}
function parseKinematicsJoint( xml ) {
let data;
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'prismatic':
case 'revolute':
data = parseKinematicsJointParameter( child );
break;
}
}
return data;
}
function parseKinematicsJointParameter( xml ) {
const data = {
sid: xml.getAttribute( 'sid' ),
name: xml.getAttribute( 'name' ) || '',
axis: new Vector3(),
limits: {
min: 0,
max: 0
},
type: xml.nodeName,
static: false,
zeroPosition: 0,
middlePosition: 0
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'axis':
const array = parseFloats( child.textContent );
data.axis.fromArray( array );
break;
case 'limits':
const max = child.getElementsByTagName( 'max' )[ 0 ];
const min = child.getElementsByTagName( 'min' )[ 0 ];
data.limits.max = parseFloat( max.textContent );
data.limits.min = parseFloat( min.textContent );
break;
}
}
// if min is equal to or greater than max, consider the joint static
if ( data.limits.min >= data.limits.max ) {
data.static = true;
}
// calculate middle position
data.middlePosition = ( data.limits.min + data.limits.max ) / 2.0;
return data;
}
function parseKinematicsLink( xml ) {
const data = {
sid: xml.getAttribute( 'sid' ),
name: xml.getAttribute( 'name' ) || '',
attachments: [],
transforms: []
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'attachment_full':
data.attachments.push( parseKinematicsAttachment( child ) );
break;
case 'matrix':
case 'translate':
case 'rotate':
data.transforms.push( parseKinematicsTransform( child ) );
break;
}
}
return data;
}
function parseKinematicsAttachment( xml ) {
const data = {
joint: xml.getAttribute( 'joint' ).split( '/' ).pop(),
transforms: [],
links: []
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'link':
data.links.push( parseKinematicsLink( child ) );
break;
case 'matrix':
case 'translate':
case 'rotate':
data.transforms.push( parseKinematicsTransform( child ) );
break;
}
}
return data;
}
function parseKinematicsTransform( xml ) {
const data = {
type: xml.nodeName
};
const array = parseFloats( xml.textContent );
switch ( data.type ) {
case 'matrix':
data.obj = new Matrix4();
data.obj.fromArray( array ).transpose();
break;
case 'translate':
data.obj = new Vector3();
data.obj.fromArray( array );
break;
case 'rotate':
data.obj = new Vector3();
data.obj.fromArray( array );
data.angle = MathUtils.degToRad( array[ 3 ] );
break;
}
return data;
}
// physics
function parsePhysicsModel( xml ) {
const data = {
name: xml.getAttribute( 'name' ) || '',
rigidBodies: {}
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'rigid_body':
data.rigidBodies[ child.getAttribute( 'name' ) ] = {};
parsePhysicsRigidBody( child, data.rigidBodies[ child.getAttribute( 'name' ) ] );
break;
}
}
library.physicsModels[ xml.getAttribute( 'id' ) ] = data;
}
function parsePhysicsRigidBody( xml, data ) {
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'technique_common':
parsePhysicsTechniqueCommon( child, data );
break;
}
}
}
function parsePhysicsTechniqueCommon( xml, data ) {
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'inertia':
data.inertia = parseFloats( child.textContent );
break;
case 'mass':
data.mass = parseFloats( child.textContent )[ 0 ];
break;
}
}
}
// scene
function parseKinematicsScene( xml ) {
const data = {
bindJointAxis: []
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'bind_joint_axis':
data.bindJointAxis.push( parseKinematicsBindJointAxis( child ) );
break;
}
}
library.kinematicsScenes[ parseId( xml.getAttribute( 'url' ) ) ] = data;
}
function parseKinematicsBindJointAxis( xml ) {
const data = {
target: xml.getAttribute( 'target' ).split( '/' ).pop()
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
switch ( child.nodeName ) {
case 'axis':
const param = child.getElementsByTagName( 'param' )[ 0 ];
data.axis = param.textContent;
const tmpJointIndex = data.axis.split( 'inst_' ).pop().split( 'axis' )[ 0 ];
data.jointIndex = tmpJointIndex.substr( 0, tmpJointIndex.length - 1 );
break;
}
}
return data;
}
function buildKinematicsScene( data ) {
if ( data.build !== undefined ) return data.build;
return data;
}
function getKinematicsScene( id ) {
return getBuild( library.kinematicsScenes[ id ], buildKinematicsScene );
}
function setupKinematics() {
const kinematicsModelId = Object.keys( library.kinematicsModels )[ 0 ];
const kinematicsSceneId = Object.keys( library.kinematicsScenes )[ 0 ];
const visualSceneId = Object.keys( library.visualScenes )[ 0 ];
if ( kinematicsModelId === undefined || kinematicsSceneId === undefined ) return;
const kinematicsModel = getKinematicsModel( kinematicsModelId );
const kinematicsScene = getKinematicsScene( kinematicsSceneId );
const visualScene = getVisualScene( visualSceneId );
const bindJointAxis = kinematicsScene.bindJointAxis;
const jointMap = {};
for ( let i = 0, l = bindJointAxis.length; i < l; i ++ ) {
const axis = bindJointAxis[ i ];
// the result of the following query is an element of type 'translate', 'rotate','scale' or 'matrix'
const targetElement = collada.querySelector( '[sid="' + axis.target + '"]' );
if ( targetElement ) {
// get the parent of the transform element
const parentVisualElement = targetElement.parentElement;
// connect the joint of the kinematics model with the element in the visual scene
connect( axis.jointIndex, parentVisualElement );
}
}
function connect( jointIndex, visualElement ) {
const visualElementName = visualElement.getAttribute( 'name' );
const joint = kinematicsModel.joints[ jointIndex ];
visualScene.traverse( function ( object ) {
if ( object.name === visualElementName ) {
jointMap[ jointIndex ] = {
object: object,
transforms: buildTransformList( visualElement ),
joint: joint,
position: joint.zeroPosition
};
}
} );
}
const m0 = new Matrix4();
kinematics = {
joints: kinematicsModel && kinematicsModel.joints,
getJointValue: function ( jointIndex ) {
const jointData = jointMap[ jointIndex ];
if ( jointData ) {
return jointData.position;
} else {
console.warn( 'THREE.ColladaLoader: Joint ' + jointIndex + ' doesn\'t exist.' );
}
},
setJointValue: function ( jointIndex, value ) {
const jointData = jointMap[ jointIndex ];
if ( jointData ) {
const joint = jointData.joint;
if ( value > joint.limits.max || value < joint.limits.min ) {
console.warn( 'THREE.ColladaLoader: Joint ' + jointIndex + ' value ' + value + ' outside of limits (min: ' + joint.limits.min + ', max: ' + joint.limits.max + ').' );
} else if ( joint.static ) {
console.warn( 'THREE.ColladaLoader: Joint ' + jointIndex + ' is static.' );
} else {
const object = jointData.object;
const axis = joint.axis;
const transforms = jointData.transforms;
matrix.identity();
// each update, we have to apply all transforms in the correct order
for ( let i = 0; i < transforms.length; i ++ ) {
const transform = transforms[ i ];
// if there is a connection of the transform node with a joint, apply the joint value
if ( transform.sid && transform.sid.indexOf( jointIndex ) !== - 1 ) {
switch ( joint.type ) {
case 'revolute':
matrix.multiply( m0.makeRotationAxis( axis, MathUtils.degToRad( value ) ) );
break;
case 'prismatic':
matrix.multiply( m0.makeTranslation( axis.x * value, axis.y * value, axis.z * value ) );
break;
default:
console.warn( 'THREE.ColladaLoader: Unknown joint type: ' + joint.type );
break;
}
} else {
switch ( transform.type ) {
case 'matrix':
matrix.multiply( transform.obj );
break;
case 'translate':
matrix.multiply( m0.makeTranslation( transform.obj.x, transform.obj.y, transform.obj.z ) );
break;
case 'scale':
matrix.scale( transform.obj );
break;
case 'rotate':
matrix.multiply( m0.makeRotationAxis( transform.obj, transform.angle ) );
break;
}
}
}
object.matrix.copy( matrix );
object.matrix.decompose( object.position, object.quaternion, object.scale );
jointMap[ jointIndex ].position = value;
}
} else {
console.log( 'THREE.ColladaLoader: ' + jointIndex + ' does not exist.' );
}
}
};
}
function buildTransformList( node ) {
const transforms = [];
const xml = collada.querySelector( '[id="' + node.id + '"]' );
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
let array, vector;
switch ( child.nodeName ) {
case 'matrix':
array = parseFloats( child.textContent );
const matrix = new Matrix4().fromArray( array ).transpose();
transforms.push( {
sid: child.getAttribute( 'sid' ),
type: child.nodeName,
obj: matrix
} );
break;
case 'translate':
case 'scale':
array = parseFloats( child.textContent );
vector = new Vector3().fromArray( array );
transforms.push( {
sid: child.getAttribute( 'sid' ),
type: child.nodeName,
obj: vector
} );
break;
case 'rotate':
array = parseFloats( child.textContent );
vector = new Vector3().fromArray( array );
const angle = MathUtils.degToRad( array[ 3 ] );
transforms.push( {
sid: child.getAttribute( 'sid' ),
type: child.nodeName,
obj: vector,
angle: angle
} );
break;
}
}
return transforms;
}
// nodes
function prepareNodes( xml ) {
const elements = xml.getElementsByTagName( 'node' );
// ensure all node elements have id attributes
for ( let i = 0; i < elements.length; i ++ ) {
const element = elements[ i ];
if ( element.hasAttribute( 'id' ) === false ) {
element.setAttribute( 'id', generateId() );
}
}
}
const matrix = new Matrix4();
const vector = new Vector3();
function parseNode( xml ) {
const data = {
name: xml.getAttribute( 'name' ) || '',
type: xml.getAttribute( 'type' ),
id: xml.getAttribute( 'id' ),
sid: xml.getAttribute( 'sid' ),
matrix: new Matrix4(),
nodes: [],
instanceCameras: [],
instanceControllers: [],
instanceLights: [],
instanceGeometries: [],
instanceNodes: [],
transforms: {}
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
if ( child.nodeType !== 1 ) continue;
let array;
switch ( child.nodeName ) {
case 'node':
data.nodes.push( child.getAttribute( 'id' ) );
parseNode( child );
break;
case 'instance_camera':
data.instanceCameras.push( parseId( child.getAttribute( 'url' ) ) );
break;
case 'instance_controller':
data.instanceControllers.push( parseNodeInstance( child ) );
break;
case 'instance_light':
data.instanceLights.push( parseId( child.getAttribute( 'url' ) ) );
break;
case 'instance_geometry':
data.instanceGeometries.push( parseNodeInstance( child ) );
break;
case 'instance_node':
data.instanceNodes.push( parseId( child.getAttribute( 'url' ) ) );
break;
case 'matrix':
array = parseFloats( child.textContent );
data.matrix.multiply( matrix.fromArray( array ).transpose() );
data.transforms[ child.getAttribute( 'sid' ) ] = child.nodeName;
break;
case 'translate':
array = parseFloats( child.textContent );
vector.fromArray( array );
data.matrix.multiply( matrix.makeTranslation( vector.x, vector.y, vector.z ) );
data.transforms[ child.getAttribute( 'sid' ) ] = child.nodeName;
break;
case 'rotate':
array = parseFloats( child.textContent );
const angle = MathUtils.degToRad( array[ 3 ] );
data.matrix.multiply( matrix.makeRotationAxis( vector.fromArray( array ), angle ) );
data.transforms[ child.getAttribute( 'sid' ) ] = child.nodeName;
break;
case 'scale':
array = parseFloats( child.textContent );
data.matrix.scale( vector.fromArray( array ) );
data.transforms[ child.getAttribute( 'sid' ) ] = child.nodeName;
break;
case 'extra':
break;
default:
console.log( child );
}
}
if ( hasNode( data.id ) ) {
console.warn( 'THREE.ColladaLoader: There is already a node with ID %s. Exclude current node from further processing.', data.id );
} else {
library.nodes[ data.id ] = data;
}
return data;
}
function parseNodeInstance( xml ) {
const data = {
id: parseId( xml.getAttribute( 'url' ) ),
materials: {},
skeletons: []
};
for ( let i = 0; i < xml.childNodes.length; i ++ ) {
const child = xml.childNodes[ i ];
switch ( child.nodeName ) {
case 'bind_material':
const instances = child.getElementsByTagName( 'instance_material' );
for ( let j = 0; j < instances.length; j ++ ) {
const instance = instances[ j ];
const symbol = instance.getAttribute( 'symbol' );
const target = instance.getAttribute( 'target' );
data.materials[ symbol ] = parseId( target );
}
break;
case 'skeleton':
data.skeletons.push( parseId( child.textContent ) );
break;
default:
break;
}
}
return data;
}
function buildSkeleton( skeletons, joints ) {
const boneData = [];
const sortedBoneData = [];
let i, j, data;
// a skeleton can have multiple root bones. collada expresses this
// situtation with multiple "skeleton" tags per controller instance
for ( i = 0; i < skeletons.length; i ++ ) {
const skeleton = skeletons[ i ];
let root;
if ( hasNode( skeleton ) ) {
root = getNode( skeleton );
buildBoneHierarchy( root, joints, boneData );
} else if ( hasVisualScene( skeleton ) ) {
// handle case where the skeleton refers to the visual scene (#13335)
const visualScene = library.visualScenes[ skeleton ];
const children = visualScene.children;
for ( let j = 0; j < children.length; j ++ ) {
const child = children[ j ];
if ( child.type === 'JOINT' ) {
const root = getNode( child.id );
buildBoneHierarchy( root, joints, boneData );
}
}
} else {
console.error( 'THREE.ColladaLoader: Unable to find root bone of skeleton with ID:', skeleton );
}
}
// sort bone data (the order is defined in the corresponding controller)
for ( i = 0; i < joints.length; i ++ ) {
for ( j = 0; j < boneData.length; j ++ ) {
data = boneData[ j ];
if ( data.bone.name === joints[ i ].name ) {
sortedBoneData[ i ] = data;
data.processed = true;
break;
}
}
}
// add unprocessed bone data at the end of the list
for ( i = 0; i < boneData.length; i ++ ) {
data = boneData[ i ];
if ( data.processed === false ) {
sortedBoneData.push( data );
data.processed = true;
}
}
// setup arrays for skeleton creation
const bones = [];
const boneInverses = [];
for ( i = 0; i < sortedBoneData.length; i ++ ) {
data = sortedBoneData[ i ];
bones.push( data.bone );
boneInverses.push( data.boneInverse );
}
return new Skeleton( bones, boneInverses );
}
function buildBoneHierarchy( root, joints, boneData ) {
// setup bone data from visual scene
root.traverse( function ( object ) {
if ( object.isBone === true ) {
let boneInverse;
// retrieve the boneInverse from the controller data
for ( let i = 0; i < joints.length; i ++ ) {
const joint = joints[ i ];
if ( joint.name === object.name ) {
boneInverse = joint.boneInverse;
break;
}
}
if ( boneInverse === undefined ) {
// Unfortunately, there can be joints in the visual scene that are not part of the
// corresponding controller. In this case, we have to create a dummy boneInverse matrix
// for the respective bone. This bone won't affect any vertices, because there are no skin indices
// and weights defined for it. But we still have to add the bone to the sorted bone list in order to
// ensure a correct animation of the model.
boneInverse = new Matrix4();
}
boneData.push( { bone: object, boneInverse: boneInverse, processed: false } );
}
} );
}
function buildNode( data ) {
const objects = [];
const matrix = data.matrix;
const nodes = data.nodes;
const type = data.type;
const instanceCameras = data.instanceCameras;
const instanceControllers = data.instanceControllers;
const instanceLights = data.instanceLights;
const instanceGeometries = data.instanceGeometries;
const instanceNodes = data.instanceNodes;
// nodes
for ( let i = 0, l = nodes.length; i < l; i ++ ) {
objects.push( getNode( nodes[ i ] ) );
}
// instance cameras
for ( let i = 0, l = instanceCameras.length; i < l; i ++ ) {
const instanceCamera = getCamera( instanceCameras[ i ] );
if ( instanceCamera !== null ) {
objects.push( instanceCamera.clone() );
}
}
// instance controllers
for ( let i = 0, l = instanceControllers.length; i < l; i ++ ) {
const instance = instanceControllers[ i ];
const controller = getController( instance.id );
const geometries = getGeometry( controller.id );
const newObjects = buildObjects( geometries, instance.materials );
const skeletons = instance.skeletons;
const joints = controller.skin.joints;
const skeleton = buildSkeleton( skeletons, joints );
for ( let j = 0, jl = newObjects.length; j < jl; j ++ ) {
const object = newObjects[ j ];
if ( object.isSkinnedMesh ) {
object.bind( skeleton, controller.skin.bindMatrix );
object.normalizeSkinWeights();
}
objects.push( object );
}
}
// instance lights
for ( let i = 0, l = instanceLights.length; i < l; i ++ ) {
const instanceLight = getLight( instanceLights[ i ] );
if ( instanceLight !== null ) {
objects.push( instanceLight.clone() );
}
}
// instance geometries
for ( let i = 0, l = instanceGeometries.length; i < l; i ++ ) {
const instance = instanceGeometries[ i ];
// a single geometry instance in collada can lead to multiple object3Ds.
// this is the case when primitives are combined like triangles and lines
const geometries = getGeometry( instance.id );
const newObjects = buildObjects( geometries, instance.materials );
for ( let j = 0, jl = newObjects.length; j < jl; j ++ ) {
objects.push( newObjects[ j ] );
}
}
// instance nodes
for ( let i = 0, l = instanceNodes.length; i < l; i ++ ) {
objects.push( getNode( instanceNodes[ i ] ).clone() );
}
let object;
if ( nodes.length === 0 && objects.length === 1 ) {
object = objects[ 0 ];
} else {
object = ( type === 'JOINT' ) ? new Bone() : new Group();
for ( let i = 0; i < objects.length; i ++ ) {
object.add( objects[ i ] );
}
}
object.name = ( type === 'JOINT' ) ? data.sid : data.name;
object.matrix.copy( matrix );
object.matrix.decompose( object.position, object.quaternion, object.scale );
return object;
}
const fallbackMaterial = new MeshBasicMaterial( { color: 0xff00ff } );
function resolveMaterialBinding( keys, instanceMaterials ) {
const materials = [];
for ( let i = 0, l = keys.length; i < l; i ++ ) {
const id = instanceMaterials[ keys[ i ] ];
if ( id === undefined ) {
console.warn( 'THREE.ColladaLoader: Material with key %s not found. Apply fallback material.', keys[ i ] );
materials.push( fallbackMaterial );
} else {
materials.push( getMaterial( id ) );
}
}
return materials;
}
function buildObjects( geometries, instanceMaterials ) {
const objects = [];
for ( const type in geometries ) {
const geometry = geometries[ type ];
const materials = resolveMaterialBinding( geometry.materialKeys, instanceMaterials );
// handle case if no materials are defined
if ( materials.length === 0 ) {
if ( type === 'lines' || type === 'linestrips' ) {
materials.push( new LineBasicMaterial() );
} else {
materials.push( new MeshPhongMaterial() );
}
}
// regard skinning
const skinning = ( geometry.data.attributes.skinIndex !== undefined );
// choose between a single or multi materials (material array)
const material = ( materials.length === 1 ) ? materials[ 0 ] : materials;
// now create a specific 3D object
let object;
switch ( type ) {
case 'lines':
object = new LineSegments( geometry.data, material );
break;
case 'linestrips':
object = new Line( geometry.data, material );
break;
case 'triangles':
case 'polylist':
if ( skinning ) {
object = new SkinnedMesh( geometry.data, material );
} else {
object = new Mesh( geometry.data, material );
}
break;
}
objects.push( object );
}
return objects;
}
function hasNode( id ) {
return library.nodes[ id ] !== undefined;
}
function getNode( id ) {
return getBuild( library.nodes[ id ], buildNode );
}
// visual scenes
function parseVisualScene( xml ) {
const data = {
name: xml.getAttribute( 'name' ),
children: []
};
prepareNodes( xml );
const elements = getElementsByTagName( xml, 'node' );
for ( let i = 0; i < elements.length; i ++ ) {
data.children.push( parseNode( elements[ i ] ) );
}
library.visualScenes[ xml.getAttribute( 'id' ) ] = data;
}
function buildVisualScene( data ) {
const group = new Group();
group.name = data.name;
const children = data.children;
for ( let i = 0; i < children.length; i ++ ) {
const child = children[ i ];
group.add( getNode( child.id ) );
}
return group;
}
function hasVisualScene( id ) {
return library.visualScenes[ id ] !== undefined;
}
function getVisualScene( id ) {
return getBuild( library.visualScenes[ id ], buildVisualScene );
}
// scenes
function parseScene( xml ) {
const instance = getElementsByTagName( xml, 'instance_visual_scene' )[ 0 ];
return getVisualScene( parseId( instance.getAttribute( 'url' ) ) );
}
function setupAnimations() {
const clips = library.clips;
if ( isEmpty( clips ) === true ) {
if ( isEmpty( library.animations ) === false ) {
// if there are animations but no clips, we create a default clip for playback
const tracks = [];
for ( const id in library.animations ) {
const animationTracks = getAnimation( id );
for ( let i = 0, l = animationTracks.length; i < l; i ++ ) {
tracks.push( animationTracks[ i ] );
}
}
animations.push( new AnimationClip( 'default', - 1, tracks ) );
}
} else {
for ( const id in clips ) {
animations.push( getAnimationClip( id ) );
}
}
}
// convert the parser error element into text with each child elements text
// separated by new lines.
function parserErrorToText( parserError ) {
let result = '';
const stack = [ parserError ];
while ( stack.length ) {
const node = stack.shift();
if ( node.nodeType === Node.TEXT_NODE ) {
result += node.textContent;
} else {
result += '\n';
stack.push.apply( stack, node.childNodes );
}
}
return result.trim();
}
if ( text.length === 0 ) {
return { scene: new Scene() };
}
const xml = new DOMParser().parseFromString( text, 'application/xml' );
const collada = getElementsByTagName( xml, 'COLLADA' )[ 0 ];
const parserError = xml.getElementsByTagName( 'parsererror' )[ 0 ];
if ( parserError !== undefined ) {
// Chrome will return parser error with a div in it
const errorElement = getElementsByTagName( parserError, 'div' )[ 0 ];
let errorText;
if ( errorElement ) {
errorText = errorElement.textContent;
} else {
errorText = parserErrorToText( parserError );
}
console.error( 'THREE.ColladaLoader: Failed to parse collada file.\n', errorText );
return null;
}
// metadata
const version = collada.getAttribute( 'version' );
console.log( 'THREE.ColladaLoader: File version', version );
const asset = parseAsset( getElementsByTagName( collada, 'asset' )[ 0 ] );
const textureLoader = new TextureLoader( this.manager );
textureLoader.setPath( this.resourcePath || path ).setCrossOrigin( this.crossOrigin );
let tgaLoader;
if ( TGALoader ) {
tgaLoader = new TGALoader( this.manager );
tgaLoader.setPath( this.resourcePath || path );
}
//
const tempColor = new Color();
const animations = [];
let kinematics = {};
let count = 0;
//
const library = {
animations: {},
clips: {},
controllers: {},
images: {},
effects: {},
materials: {},
cameras: {},
lights: {},
geometries: {},
nodes: {},
visualScenes: {},
kinematicsModels: {},
physicsModels: {},
kinematicsScenes: {}
};
parseLibrary( collada, 'library_animations', 'animation', parseAnimation );
parseLibrary( collada, 'library_animation_clips', 'animation_clip', parseAnimationClip );
parseLibrary( collada, 'library_controllers', 'controller', parseController );
parseLibrary( collada, 'library_images', 'image', parseImage );
parseLibrary( collada, 'library_effects', 'effect', parseEffect );
parseLibrary( collada, 'library_materials', 'material', parseMaterial );
parseLibrary( collada, 'library_cameras', 'camera', parseCamera );
parseLibrary( collada, 'library_lights', 'light', parseLight );
parseLibrary( collada, 'library_geometries', 'geometry', parseGeometry );
parseLibrary( collada, 'library_nodes', 'node', parseNode );
parseLibrary( collada, 'library_visual_scenes', 'visual_scene', parseVisualScene );
parseLibrary( collada, 'library_kinematics_models', 'kinematics_model', parseKinematicsModel );
parseLibrary( collada, 'library_physics_models', 'physics_model', parsePhysicsModel );
parseLibrary( collada, 'scene', 'instance_kinematics_scene', parseKinematicsScene );
buildLibrary( library.animations, buildAnimation );
buildLibrary( library.clips, buildAnimationClip );
buildLibrary( library.controllers, buildController );
buildLibrary( library.images, buildImage );
buildLibrary( library.effects, buildEffect );
buildLibrary( library.materials, buildMaterial );
buildLibrary( library.cameras, buildCamera );
buildLibrary( library.lights, buildLight );
buildLibrary( library.geometries, buildGeometry );
buildLibrary( library.visualScenes, buildVisualScene );
setupAnimations();
setupKinematics();
const scene = parseScene( getElementsByTagName( collada, 'scene' )[ 0 ] );
scene.animations = animations;
if ( asset.upAxis === 'Z_UP' ) {
scene.quaternion.setFromEuler( new Euler( - Math.PI / 2, 0, 0 ) );
}
scene.scale.multiplyScalar( asset.unit );
return {
get animations() {
console.warn( 'THREE.ColladaLoader: Please access animations over scene.animations now.' );
return animations;
},
kinematics: kinematics,
library: library,
scene: scene
};
}