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ktongue/docker_container / simsite /frontend /node_modules /three-stdlib /loaders /GLTFLoader.cjs
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"use strict";
Object.defineProperty(exports, Symbol.toStringTag, { value: "Module" });
const THREE = require("three");
const BufferGeometryUtils = require("../utils/BufferGeometryUtils.cjs");
const constants = require("../_polyfill/constants.cjs");
const LoaderUtils = require("../_polyfill/LoaderUtils.cjs");
const SRGBColorSpace = "srgb";
const LinearSRGBColorSpace = "srgb-linear";
const sRGBEncoding = 3001;
const LinearEncoding = 3e3;
class GLTFLoader extends THREE.Loader {
 constructor(manager) {
 super(manager);
 this.dracoLoader = null;
 this.ktx2Loader = null;
 this.meshoptDecoder = null;
 this.pluginCallbacks = [];
 this.register(function(parser) {
 return new GLTFMaterialsClearcoatExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsDispersionExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFTextureBasisUExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFTextureWebPExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFTextureAVIFExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsSheenExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsTransmissionExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsVolumeExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsIorExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsEmissiveStrengthExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsSpecularExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsIridescenceExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsAnisotropyExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMaterialsBumpExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFLightsExtension(parser);
 });
 this.register(function(parser) {
 return new GLTFMeshoptCompression(parser);
 });
 this.register(function(parser) {
 return new GLTFMeshGpuInstancing(parser);
 });
 }
 load(url, onLoad, onProgress, onError) {
 const scope = this;
 let resourcePath;
 if (this.resourcePath !== "") {
 resourcePath = this.resourcePath;
 } else if (this.path !== "") {
 const relativeUrl = THREE.LoaderUtils.extractUrlBase(url);
 resourcePath = THREE.LoaderUtils.resolveURL(relativeUrl, this.path);
 } else {
 resourcePath = THREE.LoaderUtils.extractUrlBase(url);
 }
 this.manager.itemStart(url);
 const _onError = function(e) {
 if (onError) {
 onError(e);
 } else {
 console.error(e);
 }
 scope.manager.itemError(url);
 scope.manager.itemEnd(url);
 };
 const loader = new THREE.FileLoader(this.manager);
 loader.setPath(this.path);
 loader.setResponseType("arraybuffer");
 loader.setRequestHeader(this.requestHeader);
 loader.setWithCredentials(this.withCredentials);
 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(dracoLoader) {
 this.dracoLoader = dracoLoader;
 return this;
 }
 setDDSLoader() {
 throw new Error('THREE.GLTFLoader: "MSFT_texture_dds" no longer supported. Please update to "KHR_texture_basisu".');
 }
 setKTX2Loader(ktx2Loader) {
 this.ktx2Loader = ktx2Loader;
 return this;
 }
 setMeshoptDecoder(meshoptDecoder) {
 this.meshoptDecoder = meshoptDecoder;
 return this;
 }
 register(callback) {
 if (this.pluginCallbacks.indexOf(callback) === -1) {
 this.pluginCallbacks.push(callback);
 }
 return this;
 }
 unregister(callback) {
 if (this.pluginCallbacks.indexOf(callback) !== -1) {
 this.pluginCallbacks.splice(this.pluginCallbacks.indexOf(callback), 1);
 }
 return this;
 }
 parse(data, path, onLoad, onError) {
 let json;
 const extensions = {};
 const plugins = {};
 if (typeof data === "string") {
 json = JSON.parse(data);
 } else if (data instanceof ArrayBuffer) {
 const magic = LoaderUtils.decodeText(new Uint8Array(data.slice(0, 4)));
 if (magic === BINARY_EXTENSION_HEADER_MAGIC) {
 try {
 extensions[EXTENSIONS.KHR_BINARY_GLTF] = new GLTFBinaryExtension(data);
 } catch (error) {
 if (onError)
 onError(error);
 return;
 }
 json = JSON.parse(extensions[EXTENSIONS.KHR_BINARY_GLTF].content);
 } else {
 json = JSON.parse(LoaderUtils.decodeText(new Uint8Array(data)));
 }
 } else {
 json = data;
 }
 if (json.asset === void 0 || json.asset.version[0] < 2) {
 if (onError)
 onError(new Error("THREE.GLTFLoader: Unsupported asset. glTF versions >=2.0 are supported."));
 return;
 }
 const parser = new GLTFParser(json, {
 path: path || this.resourcePath || "",
 crossOrigin: this.crossOrigin,
 requestHeader: this.requestHeader,
 manager: this.manager,
 ktx2Loader: this.ktx2Loader,
 meshoptDecoder: this.meshoptDecoder
 });
 parser.fileLoader.setRequestHeader(this.requestHeader);
 for (let i = 0; i < this.pluginCallbacks.length; i++) {
 const plugin = this.pluginCallbacks[i](parser);
 if (!plugin.name)
 console.error("THREE.GLTFLoader: Invalid plugin found: missing name");
 plugins[plugin.name] = plugin;
 extensions[plugin.name] = true;
 }
 if (json.extensionsUsed) {
 for (let i = 0; i < json.extensionsUsed.length; ++i) {
 const extensionName = json.extensionsUsed[i];
 const extensionsRequired = json.extensionsRequired || [];
 switch (extensionName) {
 case EXTENSIONS.KHR_MATERIALS_UNLIT:
 extensions[extensionName] = new GLTFMaterialsUnlitExtension();
 break;
 case EXTENSIONS.KHR_DRACO_MESH_COMPRESSION:
 extensions[extensionName] = new GLTFDracoMeshCompressionExtension(json, this.dracoLoader);
 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 && plugins[extensionName] === void 0) {
 console.warn('THREE.GLTFLoader: Unknown extension "' + extensionName + '".');
 }
 }
 }
 }
 parser.setExtensions(extensions);
 parser.setPlugins(plugins);
 parser.parse(onLoad, onError);
 }
 parseAsync(data, path) {
 const scope = this;
 return new Promise(function(resolve, reject) {
 scope.parse(data, path, resolve, reject);
 });
 }
}
function GLTFRegistry() {
 let objects = {};
 return {
 get: function(key) {
 return objects[key];
 },
 add: function(key, object) {
 objects[key] = object;
 },
 remove: function(key) {
 delete objects[key];
 },
 removeAll: function() {
 objects = {};
 }
 };
}
const 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_DISPERSION: "KHR_materials_dispersion",
 KHR_MATERIALS_IOR: "KHR_materials_ior",
 KHR_MATERIALS_SHEEN: "KHR_materials_sheen",
 KHR_MATERIALS_SPECULAR: "KHR_materials_specular",
 KHR_MATERIALS_TRANSMISSION: "KHR_materials_transmission",
 KHR_MATERIALS_IRIDESCENCE: "KHR_materials_iridescence",
 KHR_MATERIALS_ANISOTROPY: "KHR_materials_anisotropy",
 KHR_MATERIALS_UNLIT: "KHR_materials_unlit",
 KHR_MATERIALS_VOLUME: "KHR_materials_volume",
 KHR_TEXTURE_BASISU: "KHR_texture_basisu",
 KHR_TEXTURE_TRANSFORM: "KHR_texture_transform",
 KHR_MESH_QUANTIZATION: "KHR_mesh_quantization",
 KHR_MATERIALS_EMISSIVE_STRENGTH: "KHR_materials_emissive_strength",
 EXT_MATERIALS_BUMP: "EXT_materials_bump",
 EXT_TEXTURE_WEBP: "EXT_texture_webp",
 EXT_TEXTURE_AVIF: "EXT_texture_avif",
 EXT_MESHOPT_COMPRESSION: "EXT_meshopt_compression",
 EXT_MESH_GPU_INSTANCING: "EXT_mesh_gpu_instancing"
};
class GLTFLightsExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_LIGHTS_PUNCTUAL;
 this.cache = { refs: {}, uses: {} };
 }
 _markDefs() {
 const parser = this.parser;
 const nodeDefs = this.parser.json.nodes || [];
 for (let nodeIndex = 0, nodeLength = nodeDefs.length; nodeIndex < nodeLength; nodeIndex++) {
 const nodeDef = nodeDefs[nodeIndex];
 if (nodeDef.extensions && nodeDef.extensions[this.name] && nodeDef.extensions[this.name].light !== void 0) {
 parser._addNodeRef(this.cache, nodeDef.extensions[this.name].light);
 }
 }
 }
 _loadLight(lightIndex) {
 const parser = this.parser;
 const cacheKey = "light:" + lightIndex;
 let dependency = parser.cache.get(cacheKey);
 if (dependency)
 return dependency;
 const json = parser.json;
 const extensions = json.extensions && json.extensions[this.name] || {};
 const lightDefs = extensions.lights || [];
 const lightDef = lightDefs[lightIndex];
 let lightNode;
 const color = new THREE.Color(16777215);
 if (lightDef.color !== void 0)
 color.setRGB(lightDef.color[0], lightDef.color[1], lightDef.color[2], LinearSRGBColorSpace);
 const range = lightDef.range !== void 0 ? lightDef.range : 0;
 switch (lightDef.type) {
 case "directional":
 lightNode = new THREE.DirectionalLight(color);
 lightNode.target.position.set(0, 0, -1);
 lightNode.add(lightNode.target);
 break;
 case "point":
 lightNode = new THREE.PointLight(color);
 lightNode.distance = range;
 break;
 case "spot":
 lightNode = new THREE.SpotLight(color);
 lightNode.distance = range;
 lightDef.spot = lightDef.spot || {};
 lightDef.spot.innerConeAngle = lightDef.spot.innerConeAngle !== void 0 ? lightDef.spot.innerConeAngle : 0;
 lightDef.spot.outerConeAngle = lightDef.spot.outerConeAngle !== void 0 ? lightDef.spot.outerConeAngle : Math.PI / 4;
 lightNode.angle = lightDef.spot.outerConeAngle;
 lightNode.penumbra = 1 - 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);
 }
 lightNode.position.set(0, 0, 0);
 lightNode.decay = 2;
 assignExtrasToUserData(lightNode, lightDef);
 if (lightDef.intensity !== void 0)
 lightNode.intensity = lightDef.intensity;
 lightNode.name = parser.createUniqueName(lightDef.name || "light_" + lightIndex);
 dependency = Promise.resolve(lightNode);
 parser.cache.add(cacheKey, dependency);
 return dependency;
 }
 getDependency(type, index) {
 if (type !== "light")
 return;
 return this._loadLight(index);
 }
 createNodeAttachment(nodeIndex) {
 const self2 = this;
 const parser = this.parser;
 const json = parser.json;
 const nodeDef = json.nodes[nodeIndex];
 const lightDef = nodeDef.extensions && nodeDef.extensions[this.name] || {};
 const lightIndex = lightDef.light;
 if (lightIndex === void 0)
 return null;
 return this._loadLight(lightIndex).then(function(light) {
 return parser._getNodeRef(self2.cache, lightIndex, light);
 });
 }
}
class GLTFMaterialsUnlitExtension {
 constructor() {
 this.name = EXTENSIONS.KHR_MATERIALS_UNLIT;
 }
 getMaterialType() {
 return THREE.MeshBasicMaterial;
 }
 extendParams(materialParams, materialDef, parser) {
 const pending = [];
 materialParams.color = new THREE.Color(1, 1, 1);
 materialParams.opacity = 1;
 const metallicRoughness = materialDef.pbrMetallicRoughness;
 if (metallicRoughness) {
 if (Array.isArray(metallicRoughness.baseColorFactor)) {
 const array = metallicRoughness.baseColorFactor;
 materialParams.color.setRGB(array[0], array[1], array[2], LinearSRGBColorSpace);
 materialParams.opacity = array[3];
 }
 if (metallicRoughness.baseColorTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "map", metallicRoughness.baseColorTexture, SRGBColorSpace));
 }
 }
 return Promise.all(pending);
 }
}
class GLTFMaterialsEmissiveStrengthExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_EMISSIVE_STRENGTH;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const emissiveStrength = materialDef.extensions[this.name].emissiveStrength;
 if (emissiveStrength !== void 0) {
 materialParams.emissiveIntensity = emissiveStrength;
 }
 return Promise.resolve();
 }
}
class GLTFMaterialsClearcoatExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_CLEARCOAT;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 const extension = materialDef.extensions[this.name];
 if (extension.clearcoatFactor !== void 0) {
 materialParams.clearcoat = extension.clearcoatFactor;
 }
 if (extension.clearcoatTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "clearcoatMap", extension.clearcoatTexture));
 }
 if (extension.clearcoatRoughnessFactor !== void 0) {
 materialParams.clearcoatRoughness = extension.clearcoatRoughnessFactor;
 }
 if (extension.clearcoatRoughnessTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "clearcoatRoughnessMap", extension.clearcoatRoughnessTexture));
 }
 if (extension.clearcoatNormalTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "clearcoatNormalMap", extension.clearcoatNormalTexture));
 if (extension.clearcoatNormalTexture.scale !== void 0) {
 const scale = extension.clearcoatNormalTexture.scale;
 materialParams.clearcoatNormalScale = new THREE.Vector2(scale, scale);
 }
 }
 return Promise.all(pending);
 }
}
class GLTFMaterialsDispersionExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_DISPERSION;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const extension = materialDef.extensions[this.name];
 materialParams.dispersion = extension.dispersion !== void 0 ? extension.dispersion : 0;
 return Promise.resolve();
 }
}
class GLTFMaterialsIridescenceExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_IRIDESCENCE;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 const extension = materialDef.extensions[this.name];
 if (extension.iridescenceFactor !== void 0) {
 materialParams.iridescence = extension.iridescenceFactor;
 }
 if (extension.iridescenceTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "iridescenceMap", extension.iridescenceTexture));
 }
 if (extension.iridescenceIor !== void 0) {
 materialParams.iridescenceIOR = extension.iridescenceIor;
 }
 if (materialParams.iridescenceThicknessRange === void 0) {
 materialParams.iridescenceThicknessRange = [100, 400];
 }
 if (extension.iridescenceThicknessMinimum !== void 0) {
 materialParams.iridescenceThicknessRange[0] = extension.iridescenceThicknessMinimum;
 }
 if (extension.iridescenceThicknessMaximum !== void 0) {
 materialParams.iridescenceThicknessRange[1] = extension.iridescenceThicknessMaximum;
 }
 if (extension.iridescenceThicknessTexture !== void 0) {
 pending.push(
 parser.assignTexture(materialParams, "iridescenceThicknessMap", extension.iridescenceThicknessTexture)
 );
 }
 return Promise.all(pending);
 }
}
class GLTFMaterialsSheenExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_SHEEN;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 materialParams.sheenColor = new THREE.Color(0, 0, 0);
 materialParams.sheenRoughness = 0;
 materialParams.sheen = 1;
 const extension = materialDef.extensions[this.name];
 if (extension.sheenColorFactor !== void 0) {
 const colorFactor = extension.sheenColorFactor;
 materialParams.sheenColor.setRGB(colorFactor[0], colorFactor[1], colorFactor[2], LinearSRGBColorSpace);
 }
 if (extension.sheenRoughnessFactor !== void 0) {
 materialParams.sheenRoughness = extension.sheenRoughnessFactor;
 }
 if (extension.sheenColorTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "sheenColorMap", extension.sheenColorTexture, SRGBColorSpace));
 }
 if (extension.sheenRoughnessTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "sheenRoughnessMap", extension.sheenRoughnessTexture));
 }
 return Promise.all(pending);
 }
}
class GLTFMaterialsTransmissionExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_TRANSMISSION;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 const extension = materialDef.extensions[this.name];
 if (extension.transmissionFactor !== void 0) {
 materialParams.transmission = extension.transmissionFactor;
 }
 if (extension.transmissionTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "transmissionMap", extension.transmissionTexture));
 }
 return Promise.all(pending);
 }
}
class GLTFMaterialsVolumeExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_VOLUME;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 const extension = materialDef.extensions[this.name];
 materialParams.thickness = extension.thicknessFactor !== void 0 ? extension.thicknessFactor : 0;
 if (extension.thicknessTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "thicknessMap", extension.thicknessTexture));
 }
 materialParams.attenuationDistance = extension.attenuationDistance || Infinity;
 const colorArray = extension.attenuationColor || [1, 1, 1];
 materialParams.attenuationColor = new THREE.Color().setRGB(
 colorArray[0],
 colorArray[1],
 colorArray[2],
 LinearSRGBColorSpace
 );
 return Promise.all(pending);
 }
}
class GLTFMaterialsIorExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_IOR;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const extension = materialDef.extensions[this.name];
 materialParams.ior = extension.ior !== void 0 ? extension.ior : 1.5;
 return Promise.resolve();
 }
}
class GLTFMaterialsSpecularExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_SPECULAR;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 const extension = materialDef.extensions[this.name];
 materialParams.specularIntensity = extension.specularFactor !== void 0 ? extension.specularFactor : 1;
 if (extension.specularTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "specularIntensityMap", extension.specularTexture));
 }
 const colorArray = extension.specularColorFactor || [1, 1, 1];
 materialParams.specularColor = new THREE.Color().setRGB(colorArray[0], colorArray[1], colorArray[2], LinearSRGBColorSpace);
 if (extension.specularColorTexture !== void 0) {
 pending.push(
 parser.assignTexture(materialParams, "specularColorMap", extension.specularColorTexture, SRGBColorSpace)
 );
 }
 return Promise.all(pending);
 }
}
class GLTFMaterialsBumpExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.EXT_MATERIALS_BUMP;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 const extension = materialDef.extensions[this.name];
 materialParams.bumpScale = extension.bumpFactor !== void 0 ? extension.bumpFactor : 1;
 if (extension.bumpTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "bumpMap", extension.bumpTexture));
 }
 return Promise.all(pending);
 }
}
class GLTFMaterialsAnisotropyExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_MATERIALS_ANISOTROPY;
 }
 getMaterialType(materialIndex) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name])
 return null;
 return THREE.MeshPhysicalMaterial;
 }
 extendMaterialParams(materialIndex, materialParams) {
 const parser = this.parser;
 const materialDef = parser.json.materials[materialIndex];
 if (!materialDef.extensions || !materialDef.extensions[this.name]) {
 return Promise.resolve();
 }
 const pending = [];
 const extension = materialDef.extensions[this.name];
 if (extension.anisotropyStrength !== void 0) {
 materialParams.anisotropy = extension.anisotropyStrength;
 }
 if (extension.anisotropyRotation !== void 0) {
 materialParams.anisotropyRotation = extension.anisotropyRotation;
 }
 if (extension.anisotropyTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "anisotropyMap", extension.anisotropyTexture));
 }
 return Promise.all(pending);
 }
}
class GLTFTextureBasisUExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.KHR_TEXTURE_BASISU;
 }
 loadTexture(textureIndex) {
 const parser = this.parser;
 const json = parser.json;
 const textureDef = json.textures[textureIndex];
 if (!textureDef.extensions || !textureDef.extensions[this.name]) {
 return null;
 }
 const extension = textureDef.extensions[this.name];
 const loader = parser.options.ktx2Loader;
 if (!loader) {
 if (json.extensionsRequired && json.extensionsRequired.indexOf(this.name) >= 0) {
 throw new Error("THREE.GLTFLoader: setKTX2Loader must be called before loading KTX2 textures");
 } else {
 return null;
 }
 }
 return parser.loadTextureImage(textureIndex, extension.source, loader);
 }
}
class GLTFTextureWebPExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.EXT_TEXTURE_WEBP;
 this.isSupported = null;
 }
 loadTexture(textureIndex) {
 const name = this.name;
 const parser = this.parser;
 const json = parser.json;
 const textureDef = json.textures[textureIndex];
 if (!textureDef.extensions || !textureDef.extensions[name]) {
 return null;
 }
 const extension = textureDef.extensions[name];
 const source = json.images[extension.source];
 let loader = parser.textureLoader;
 if (source.uri) {
 const handler = parser.options.manager.getHandler(source.uri);
 if (handler !== null)
 loader = handler;
 }
 return this.detectSupport().then(function(isSupported) {
 if (isSupported)
 return parser.loadTextureImage(textureIndex, extension.source, loader);
 if (json.extensionsRequired && json.extensionsRequired.indexOf(name) >= 0) {
 throw new Error("THREE.GLTFLoader: WebP required by asset but unsupported.");
 }
 return parser.loadTexture(textureIndex);
 });
 }
 detectSupport() {
 if (!this.isSupported) {
 this.isSupported = new Promise(function(resolve) {
 const image = new Image();
 image.src = "data:image/webp;base64,UklGRiIAAABXRUJQVlA4IBYAAAAwAQCdASoBAAEADsD+JaQAA3AAAAAA";
 image.onload = image.onerror = function() {
 resolve(image.height === 1);
 };
 });
 }
 return this.isSupported;
 }
}
class GLTFTextureAVIFExtension {
 constructor(parser) {
 this.parser = parser;
 this.name = EXTENSIONS.EXT_TEXTURE_AVIF;
 this.isSupported = null;
 }
 loadTexture(textureIndex) {
 const name = this.name;
 const parser = this.parser;
 const json = parser.json;
 const textureDef = json.textures[textureIndex];
 if (!textureDef.extensions || !textureDef.extensions[name]) {
 return null;
 }
 const extension = textureDef.extensions[name];
 const source = json.images[extension.source];
 let loader = parser.textureLoader;
 if (source.uri) {
 const handler = parser.options.manager.getHandler(source.uri);
 if (handler !== null)
 loader = handler;
 }
 return this.detectSupport().then(function(isSupported) {
 if (isSupported)
 return parser.loadTextureImage(textureIndex, extension.source, loader);
 if (json.extensionsRequired && json.extensionsRequired.indexOf(name) >= 0) {
 throw new Error("THREE.GLTFLoader: AVIF required by asset but unsupported.");
 }
 return parser.loadTexture(textureIndex);
 });
 }
 detectSupport() {
 if (!this.isSupported) {
 this.isSupported = new Promise(function(resolve) {
 const image = new Image();
 image.src = "data:image/avif;base64,AAAAIGZ0eXBhdmlmAAAAAGF2aWZtaWYxbWlhZk1BMUIAAADybWV0YQAAAAAAAAAoaGRscgAAAAAAAAAAcGljdAAAAAAAAAAAAAAAAGxpYmF2aWYAAAAADnBpdG0AAAAAAAEAAAAeaWxvYwAAAABEAAABAAEAAAABAAABGgAAABcAAAAoaWluZgAAAAAAAQAAABppbmZlAgAAAAABAABhdjAxQ29sb3IAAAAAamlwcnAAAABLaXBjbwAAABRpc3BlAAAAAAAAAAEAAAABAAAAEHBpeGkAAAAAAwgICAAAAAxhdjFDgQAMAAAAABNjb2xybmNseAACAAIABoAAAAAXaXBtYQAAAAAAAAABAAEEAQKDBAAAAB9tZGF0EgAKCBgABogQEDQgMgkQAAAAB8dSLfI=";
 image.onload = image.onerror = function() {
 resolve(image.height === 1);
 };
 });
 }
 return this.isSupported;
 }
}
class GLTFMeshoptCompression {
 constructor(parser) {
 this.name = EXTENSIONS.EXT_MESHOPT_COMPRESSION;
 this.parser = parser;
 }
 loadBufferView(index) {
 const json = this.parser.json;
 const bufferView = json.bufferViews[index];
 if (bufferView.extensions && bufferView.extensions[this.name]) {
 const extensionDef = bufferView.extensions[this.name];
 const buffer = this.parser.getDependency("buffer", extensionDef.buffer);
 const decoder = this.parser.options.meshoptDecoder;
 if (!decoder || !decoder.supported) {
 if (json.extensionsRequired && json.extensionsRequired.indexOf(this.name) >= 0) {
 throw new Error("THREE.GLTFLoader: setMeshoptDecoder must be called before loading compressed files");
 } else {
 return null;
 }
 }
 return buffer.then(function(res) {
 const byteOffset = extensionDef.byteOffset || 0;
 const byteLength = extensionDef.byteLength || 0;
 const count = extensionDef.count;
 const stride = extensionDef.byteStride;
 const source = new Uint8Array(res, byteOffset, byteLength);
 if (decoder.decodeGltfBufferAsync) {
 return decoder.decodeGltfBufferAsync(count, stride, source, extensionDef.mode, extensionDef.filter).then(function(res2) {
 return res2.buffer;
 });
 } else {
 return decoder.ready.then(function() {
 const result = new ArrayBuffer(count * stride);
 decoder.decodeGltfBuffer(
 new Uint8Array(result),
 count,
 stride,
 source,
 extensionDef.mode,
 extensionDef.filter
 );
 return result;
 });
 }
 });
 } else {
 return null;
 }
 }
}
class GLTFMeshGpuInstancing {
 constructor(parser) {
 this.name = EXTENSIONS.EXT_MESH_GPU_INSTANCING;
 this.parser = parser;
 }
 createNodeMesh(nodeIndex) {
 const json = this.parser.json;
 const nodeDef = json.nodes[nodeIndex];
 if (!nodeDef.extensions || !nodeDef.extensions[this.name] || nodeDef.mesh === void 0) {
 return null;
 }
 const meshDef = json.meshes[nodeDef.mesh];
 for (const primitive of meshDef.primitives) {
 if (primitive.mode !== WEBGL_CONSTANTS.TRIANGLES && primitive.mode !== WEBGL_CONSTANTS.TRIANGLE_STRIP && primitive.mode !== WEBGL_CONSTANTS.TRIANGLE_FAN && primitive.mode !== void 0) {
 return null;
 }
 }
 const extensionDef = nodeDef.extensions[this.name];
 const attributesDef = extensionDef.attributes;
 const pending = [];
 const attributes = {};
 for (const key in attributesDef) {
 pending.push(
 this.parser.getDependency("accessor", attributesDef[key]).then((accessor) => {
 attributes[key] = accessor;
 return attributes[key];
 })
 );
 }
 if (pending.length < 1) {
 return null;
 }
 pending.push(this.parser.createNodeMesh(nodeIndex));
 return Promise.all(pending).then((results) => {
 const nodeObject = results.pop();
 const meshes = nodeObject.isGroup ? nodeObject.children : [nodeObject];
 const count = results[0].count;
 const instancedMeshes = [];
 for (const mesh of meshes) {
 const m = new THREE.Matrix4();
 const p = new THREE.Vector3();
 const q = new THREE.Quaternion();
 const s = new THREE.Vector3(1, 1, 1);
 const instancedMesh = new THREE.InstancedMesh(mesh.geometry, mesh.material, count);
 for (let i = 0; i < count; i++) {
 if (attributes.TRANSLATION) {
 p.fromBufferAttribute(attributes.TRANSLATION, i);
 }
 if (attributes.ROTATION) {
 q.fromBufferAttribute(attributes.ROTATION, i);
 }
 if (attributes.SCALE) {
 s.fromBufferAttribute(attributes.SCALE, i);
 }
 instancedMesh.setMatrixAt(i, m.compose(p, q, s));
 }
 for (const attributeName in attributes) {
 if (attributeName === "_COLOR_0") {
 const attr = attributes[attributeName];
 instancedMesh.instanceColor = new THREE.InstancedBufferAttribute(attr.array, attr.itemSize, attr.normalized);
 } else if (attributeName !== "TRANSLATION" && attributeName !== "ROTATION" && attributeName !== "SCALE") {
 mesh.geometry.setAttribute(attributeName, attributes[attributeName]);
 }
 }
 THREE.Object3D.prototype.copy.call(instancedMesh, mesh);
 this.parser.assignFinalMaterial(instancedMesh);
 instancedMeshes.push(instancedMesh);
 }
 if (nodeObject.isGroup) {
 nodeObject.clear();
 nodeObject.add(...instancedMeshes);
 return nodeObject;
 }
 return instancedMeshes[0];
 });
 }
}
const BINARY_EXTENSION_HEADER_MAGIC = "glTF";
const BINARY_EXTENSION_HEADER_LENGTH = 12;
const BINARY_EXTENSION_CHUNK_TYPES = { JSON: 1313821514, BIN: 5130562 };
class GLTFBinaryExtension {
 constructor(data) {
 this.name = EXTENSIONS.KHR_BINARY_GLTF;
 this.content = null;
 this.body = null;
 const 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) {
 throw new Error("THREE.GLTFLoader: Legacy binary file detected.");
 }
 const chunkContentsLength = this.header.length - BINARY_EXTENSION_HEADER_LENGTH;
 const chunkView = new DataView(data, BINARY_EXTENSION_HEADER_LENGTH);
 let chunkIndex = 0;
 while (chunkIndex < chunkContentsLength) {
 const chunkLength = chunkView.getUint32(chunkIndex, true);
 chunkIndex += 4;
 const chunkType = chunkView.getUint32(chunkIndex, true);
 chunkIndex += 4;
 if (chunkType === BINARY_EXTENSION_CHUNK_TYPES.JSON) {
 const contentArray = new Uint8Array(data, BINARY_EXTENSION_HEADER_LENGTH + chunkIndex, chunkLength);
 this.content = LoaderUtils.decodeText(contentArray);
 } else if (chunkType === BINARY_EXTENSION_CHUNK_TYPES.BIN) {
 const byteOffset = BINARY_EXTENSION_HEADER_LENGTH + chunkIndex;
 this.body = data.slice(byteOffset, byteOffset + chunkLength);
 }
 chunkIndex += chunkLength;
 }
 if (this.content === null) {
 throw new Error("THREE.GLTFLoader: JSON content not found.");
 }
 }
}
class GLTFDracoMeshCompressionExtension {
 constructor(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();
 }
 decodePrimitive(primitive, parser) {
 const json = this.json;
 const dracoLoader = this.dracoLoader;
 const bufferViewIndex = primitive.extensions[this.name].bufferView;
 const gltfAttributeMap = primitive.extensions[this.name].attributes;
 const threeAttributeMap = {};
 const attributeNormalizedMap = {};
 const attributeTypeMap = {};
 for (const attributeName in gltfAttributeMap) {
 const threeAttributeName = ATTRIBUTES[attributeName] || attributeName.toLowerCase();
 threeAttributeMap[threeAttributeName] = gltfAttributeMap[attributeName];
 }
 for (const attributeName in primitive.attributes) {
 const threeAttributeName = ATTRIBUTES[attributeName] || attributeName.toLowerCase();
 if (gltfAttributeMap[attributeName] !== void 0) {
 const accessorDef = json.accessors[primitive.attributes[attributeName]];
 const componentType = WEBGL_COMPONENT_TYPES[accessorDef.componentType];
 attributeTypeMap[threeAttributeName] = componentType.name;
 attributeNormalizedMap[threeAttributeName] = accessorDef.normalized === true;
 }
 }
 return parser.getDependency("bufferView", bufferViewIndex).then(function(bufferView) {
 return new Promise(function(resolve, reject) {
 dracoLoader.decodeDracoFile(
 bufferView,
 function(geometry) {
 for (const attributeName in geometry.attributes) {
 const attribute = geometry.attributes[attributeName];
 const normalized = attributeNormalizedMap[attributeName];
 if (normalized !== void 0)
 attribute.normalized = normalized;
 }
 resolve(geometry);
 },
 threeAttributeMap,
 attributeTypeMap,
 LinearSRGBColorSpace,
 reject
 );
 });
 });
 }
}
class GLTFTextureTransformExtension {
 constructor() {
 this.name = EXTENSIONS.KHR_TEXTURE_TRANSFORM;
 }
 extendTexture(texture, transform) {
 if ((transform.texCoord === void 0 || transform.texCoord === texture.channel) && transform.offset === void 0 && transform.rotation === void 0 && transform.scale === void 0) {
 return texture;
 }
 texture = texture.clone();
 if (transform.texCoord !== void 0) {
 texture.channel = transform.texCoord;
 }
 if (transform.offset !== void 0) {
 texture.offset.fromArray(transform.offset);
 }
 if (transform.rotation !== void 0) {
 texture.rotation = transform.rotation;
 }
 if (transform.scale !== void 0) {
 texture.repeat.fromArray(transform.scale);
 }
 texture.needsUpdate = true;
 return texture;
 }
}
class GLTFMeshQuantizationExtension {
 constructor() {
 this.name = EXTENSIONS.KHR_MESH_QUANTIZATION;
 }
}
class GLTFCubicSplineInterpolant extends THREE.Interpolant {
 constructor(parameterPositions, sampleValues, sampleSize, resultBuffer) {
 super(parameterPositions, sampleValues, sampleSize, resultBuffer);
 }
 copySampleValue_(index) {
 const result = this.resultBuffer, values = this.sampleValues, valueSize = this.valueSize, offset = index * valueSize * 3 + valueSize;
 for (let i = 0; i !== valueSize; i++) {
 result[i] = values[offset + i];
 }
 return result;
 }
 interpolate_(i1, t0, t, t1) {
 const result = this.resultBuffer;
 const values = this.sampleValues;
 const stride = this.valueSize;
 const stride2 = stride * 2;
 const stride3 = stride * 3;
 const td = t1 - t0;
 const p = (t - t0) / td;
 const pp = p * p;
 const ppp = pp * p;
 const offset1 = i1 * stride3;
 const offset0 = offset1 - stride3;
 const s2 = -2 * ppp + 3 * pp;
 const s3 = ppp - pp;
 const s0 = 1 - s2;
 const s1 = s3 - pp + p;
 for (let i = 0; i !== stride; i++) {
 const p0 = values[offset0 + i + stride];
 const m0 = values[offset0 + i + stride2] * td;
 const p1 = values[offset1 + i + stride];
 const m1 = values[offset1 + i] * td;
 result[i] = s0 * p0 + s1 * m0 + s2 * p1 + s3 * m1;
 }
 return result;
 }
}
const _q = /* @__PURE__ */ new THREE.Quaternion();
class GLTFCubicSplineQuaternionInterpolant extends GLTFCubicSplineInterpolant {
 interpolate_(i1, t0, t, t1) {
 const result = super.interpolate_(i1, t0, t, t1);
 _q.fromArray(result).normalize().toArray(result);
 return result;
 }
}
const 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
};
const WEBGL_COMPONENT_TYPES = {
 5120: Int8Array,
 5121: Uint8Array,
 5122: Int16Array,
 5123: Uint16Array,
 5125: Uint32Array,
 5126: Float32Array
};
const WEBGL_FILTERS = {
 9728: THREE.NearestFilter,
 9729: THREE.LinearFilter,
 9984: THREE.NearestMipmapNearestFilter,
 9985: THREE.LinearMipmapNearestFilter,
 9986: THREE.NearestMipmapLinearFilter,
 9987: THREE.LinearMipmapLinearFilter
};
const WEBGL_WRAPPINGS = {
 33071: THREE.ClampToEdgeWrapping,
 33648: THREE.MirroredRepeatWrapping,
 10497: THREE.RepeatWrapping
};
const WEBGL_TYPE_SIZES = {
 SCALAR: 1,
 VEC2: 2,
 VEC3: 3,
 VEC4: 4,
 MAT2: 4,
 MAT3: 9,
 MAT4: 16
};
const ATTRIBUTES = {
 POSITION: "position",
 NORMAL: "normal",
 TANGENT: "tangent",
 // uv => uv1, 4 uv channels
 // https://github.com/mrdoob/three.js/pull/25943
 // https://github.com/mrdoob/three.js/pull/25788
 ...constants.version >= 152 ? {
 TEXCOORD_0: "uv",
 TEXCOORD_1: "uv1",
 TEXCOORD_2: "uv2",
 TEXCOORD_3: "uv3"
 } : {
 TEXCOORD_0: "uv",
 TEXCOORD_1: "uv2"
 },
 COLOR_0: "color",
 WEIGHTS_0: "skinWeight",
 JOINTS_0: "skinIndex"
};
const PATH_PROPERTIES = {
 scale: "scale",
 translation: "position",
 rotation: "quaternion",
 weights: "morphTargetInfluences"
};
const INTERPOLATION = {
 CUBICSPLINE: void 0,
 // We use a custom interpolant (GLTFCubicSplineInterpolation) for CUBICSPLINE tracks. Each
 // keyframe track will be initialized with a default interpolation type, then modified.
 LINEAR: THREE.InterpolateLinear,
 STEP: THREE.InterpolateDiscrete
};
const ALPHA_MODES = {
 OPAQUE: "OPAQUE",
 MASK: "MASK",
 BLEND: "BLEND"
};
function createDefaultMaterial(cache) {
 if (cache["DefaultMaterial"] === void 0) {
 cache["DefaultMaterial"] = new THREE.MeshStandardMaterial({
 color: 16777215,
 emissive: 0,
 metalness: 1,
 roughness: 1,
 transparent: false,
 depthTest: true,
 side: THREE.FrontSide
 });
 }
 return cache["DefaultMaterial"];
}
function addUnknownExtensionsToUserData(knownExtensions, object, objectDef) {
 for (const name in objectDef.extensions) {
 if (knownExtensions[name] === void 0) {
 object.userData.gltfExtensions = object.userData.gltfExtensions || {};
 object.userData.gltfExtensions[name] = objectDef.extensions[name];
 }
 }
}
function assignExtrasToUserData(object, gltfDef) {
 if (gltfDef.extras !== void 0) {
 if (typeof gltfDef.extras === "object") {
 Object.assign(object.userData, gltfDef.extras);
 } else {
 console.warn("THREE.GLTFLoader: Ignoring primitive type .extras, " + gltfDef.extras);
 }
 }
}
function addMorphTargets(geometry, targets, parser) {
 let hasMorphPosition = false;
 let hasMorphNormal = false;
 let hasMorphColor = false;
 for (let i = 0, il = targets.length; i < il; i++) {
 const target = targets[i];
 if (target.POSITION !== void 0)
 hasMorphPosition = true;
 if (target.NORMAL !== void 0)
 hasMorphNormal = true;
 if (target.COLOR_0 !== void 0)
 hasMorphColor = true;
 if (hasMorphPosition && hasMorphNormal && hasMorphColor)
 break;
 }
 if (!hasMorphPosition && !hasMorphNormal && !hasMorphColor)
 return Promise.resolve(geometry);
 const pendingPositionAccessors = [];
 const pendingNormalAccessors = [];
 const pendingColorAccessors = [];
 for (let i = 0, il = targets.length; i < il; i++) {
 const target = targets[i];
 if (hasMorphPosition) {
 const pendingAccessor = target.POSITION !== void 0 ? parser.getDependency("accessor", target.POSITION) : geometry.attributes.position;
 pendingPositionAccessors.push(pendingAccessor);
 }
 if (hasMorphNormal) {
 const pendingAccessor = target.NORMAL !== void 0 ? parser.getDependency("accessor", target.NORMAL) : geometry.attributes.normal;
 pendingNormalAccessors.push(pendingAccessor);
 }
 if (hasMorphColor) {
 const pendingAccessor = target.COLOR_0 !== void 0 ? parser.getDependency("accessor", target.COLOR_0) : geometry.attributes.color;
 pendingColorAccessors.push(pendingAccessor);
 }
 }
 return Promise.all([
 Promise.all(pendingPositionAccessors),
 Promise.all(pendingNormalAccessors),
 Promise.all(pendingColorAccessors)
 ]).then(function(accessors) {
 const morphPositions = accessors[0];
 const morphNormals = accessors[1];
 const morphColors = accessors[2];
 if (hasMorphPosition)
 geometry.morphAttributes.position = morphPositions;
 if (hasMorphNormal)
 geometry.morphAttributes.normal = morphNormals;
 if (hasMorphColor)
 geometry.morphAttributes.color = morphColors;
 geometry.morphTargetsRelative = true;
 return geometry;
 });
}
function updateMorphTargets(mesh, meshDef) {
 mesh.updateMorphTargets();
 if (meshDef.weights !== void 0) {
 for (let i = 0, il = meshDef.weights.length; i < il; i++) {
 mesh.morphTargetInfluences[i] = meshDef.weights[i];
 }
 }
 if (meshDef.extras && Array.isArray(meshDef.extras.targetNames)) {
 const targetNames = meshDef.extras.targetNames;
 if (mesh.morphTargetInfluences.length === targetNames.length) {
 mesh.morphTargetDictionary = {};
 for (let 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) {
 let geometryKey;
 const dracoExtension = primitiveDef.extensions && primitiveDef.extensions[EXTENSIONS.KHR_DRACO_MESH_COMPRESSION];
 if (dracoExtension) {
 geometryKey = "draco:" + dracoExtension.bufferView + ":" + dracoExtension.indices + ":" + createAttributesKey(dracoExtension.attributes);
 } else {
 geometryKey = primitiveDef.indices + ":" + createAttributesKey(primitiveDef.attributes) + ":" + primitiveDef.mode;
 }
 if (primitiveDef.targets !== void 0) {
 for (let i = 0, il = primitiveDef.targets.length; i < il; i++) {
 geometryKey += ":" + createAttributesKey(primitiveDef.targets[i]);
 }
 }
 return geometryKey;
}
function createAttributesKey(attributes) {
 let attributesKey = "";
 const keys = Object.keys(attributes).sort();
 for (let i = 0, il = keys.length; i < il; i++) {
 attributesKey += keys[i] + ":" + attributes[keys[i]] + ";";
 }
 return attributesKey;
}
function getNormalizedComponentScale(constructor) {
 switch (constructor) {
 case Int8Array:
 return 1 / 127;
 case Uint8Array:
 return 1 / 255;
 case Int16Array:
 return 1 / 32767;
 case Uint16Array:
 return 1 / 65535;
 default:
 throw new Error("THREE.GLTFLoader: Unsupported normalized accessor component type.");
 }
}
function getImageURIMimeType(uri) {
 if (uri.search(/\.jpe?g($|\?)/i) > 0 || uri.search(/^data\:image\/jpeg/) === 0)
 return "image/jpeg";
 if (uri.search(/\.webp($|\?)/i) > 0 || uri.search(/^data\:image\/webp/) === 0)
 return "image/webp";
 return "image/png";
}
const _identityMatrix = /* @__PURE__ */ new THREE.Matrix4();
class GLTFParser {
 constructor(json = {}, options = {}) {
 this.json = json;
 this.extensions = {};
 this.plugins = {};
 this.options = options;
 this.cache = new GLTFRegistry();
 this.associations = /* @__PURE__ */ new Map();
 this.primitiveCache = {};
 this.nodeCache = {};
 this.meshCache = { refs: {}, uses: {} };
 this.cameraCache = { refs: {}, uses: {} };
 this.lightCache = { refs: {}, uses: {} };
 this.sourceCache = {};
 this.textureCache = {};
 this.nodeNamesUsed = {};
 let isSafari = false;
 let isFirefox = false;
 let firefoxVersion = -1;
 if (typeof navigator !== "undefined" && typeof navigator.userAgent !== "undefined") {
 isSafari = /^((?!chrome|android).)*safari/i.test(navigator.userAgent) === true;
 isFirefox = navigator.userAgent.indexOf("Firefox") > -1;
 firefoxVersion = isFirefox ? navigator.userAgent.match(/Firefox\/([0-9]+)\./)[1] : -1;
 }
 if (typeof createImageBitmap === "undefined" || isSafari || isFirefox && firefoxVersion < 98) {
 this.textureLoader = new THREE.TextureLoader(this.options.manager);
 } else {
 this.textureLoader = new THREE.ImageBitmapLoader(this.options.manager);
 }
 this.textureLoader.setCrossOrigin(this.options.crossOrigin);
 this.textureLoader.setRequestHeader(this.options.requestHeader);
 this.fileLoader = new THREE.FileLoader(this.options.manager);
 this.fileLoader.setResponseType("arraybuffer");
 if (this.options.crossOrigin === "use-credentials") {
 this.fileLoader.setWithCredentials(true);
 }
 }
 setExtensions(extensions) {
 this.extensions = extensions;
 }
 setPlugins(plugins) {
 this.plugins = plugins;
 }
 parse(onLoad, onError) {
 const parser = this;
 const json = this.json;
 const extensions = this.extensions;
 this.cache.removeAll();
 this.nodeCache = {};
 this._invokeAll(function(ext) {
 return ext._markDefs && ext._markDefs();
 });
 Promise.all(
 this._invokeAll(function(ext) {
 return ext.beforeRoot && ext.beforeRoot();
 })
 ).then(function() {
 return Promise.all([
 parser.getDependencies("scene"),
 parser.getDependencies("animation"),
 parser.getDependencies("camera")
 ]);
 }).then(function(dependencies) {
 const result = {
 scene: dependencies[0][json.scene || 0],
 scenes: dependencies[0],
 animations: dependencies[1],
 cameras: dependencies[2],
 asset: json.asset,
 parser,
 userData: {}
 };
 addUnknownExtensionsToUserData(extensions, result, json);
 assignExtrasToUserData(result, json);
 return Promise.all(
 parser._invokeAll(function(ext) {
 return ext.afterRoot && ext.afterRoot(result);
 })
 ).then(function() {
 for (const scene of result.scenes) {
 scene.updateMatrixWorld();
 }
 onLoad(result);
 });
 }).catch(onError);
 }
 /**
 * Marks the special nodes/meshes in json for efficient parse.
 */
 _markDefs() {
 const nodeDefs = this.json.nodes || [];
 const skinDefs = this.json.skins || [];
 const meshDefs = this.json.meshes || [];
 for (let skinIndex = 0, skinLength = skinDefs.length; skinIndex < skinLength; skinIndex++) {
 const joints = skinDefs[skinIndex].joints;
 for (let i = 0, il = joints.length; i < il; i++) {
 nodeDefs[joints[i]].isBone = true;
 }
 }
 for (let nodeIndex = 0, nodeLength = nodeDefs.length; nodeIndex < nodeLength; nodeIndex++) {
 const nodeDef = nodeDefs[nodeIndex];
 if (nodeDef.mesh !== void 0) {
 this._addNodeRef(this.meshCache, nodeDef.mesh);
 if (nodeDef.skin !== void 0) {
 meshDefs[nodeDef.mesh].isSkinnedMesh = true;
 }
 }
 if (nodeDef.camera !== void 0) {
 this._addNodeRef(this.cameraCache, nodeDef.camera);
 }
 }
 }
 /**
 * Counts references to shared node / Object3D resources. These resources
 * can be reused, or "instantiated", at multiple nodes in the scene
 * hierarchy. Mesh, Camera, and Light instances are instantiated and must
 * be marked. Non-scenegraph resources (like Materials, Geometries, and
 * Textures) can be reused directly and are not marked here.
 *
 * Example: CesiumMilkTruck sample model reuses "Wheel" meshes.
 */
 _addNodeRef(cache, index) {
 if (index === void 0)
 return;
 if (cache.refs[index] === void 0) {
 cache.refs[index] = cache.uses[index] = 0;
 }
 cache.refs[index]++;
 }
 /** Returns a reference to a shared resource, cloning it if necessary. */
 _getNodeRef(cache, index, object) {
 if (cache.refs[index] <= 1)
 return object;
 const ref = object.clone();
 const updateMappings = (original, clone) => {
 const mappings = this.associations.get(original);
 if (mappings != null) {
 this.associations.set(clone, mappings);
 }
 for (const [i, child] of original.children.entries()) {
 updateMappings(child, clone.children[i]);
 }
 };
 updateMappings(object, ref);
 ref.name += "_instance_" + cache.uses[index]++;
 return ref;
 }
 _invokeOne(func) {
 const extensions = Object.values(this.plugins);
 extensions.push(this);
 for (let i = 0; i < extensions.length; i++) {
 const result = func(extensions[i]);
 if (result)
 return result;
 }
 return null;
 }
 _invokeAll(func) {
 const extensions = Object.values(this.plugins);
 extensions.unshift(this);
 const pending = [];
 for (let i = 0; i < extensions.length; i++) {
 const result = func(extensions[i]);
 if (result)
 pending.push(result);
 }
 return pending;
 }
 /**
 * Requests the specified dependency asynchronously, with caching.
 * @param {string} type
 * @param {number} index
 * @return {Promise<Object3D|Material|THREE.Texture|AnimationClip|ArrayBuffer|Object>}
 */
 getDependency(type, index) {
 const cacheKey = type + ":" + index;
 let dependency = this.cache.get(cacheKey);
 if (!dependency) {
 switch (type) {
 case "scene":
 dependency = this.loadScene(index);
 break;
 case "node":
 dependency = this._invokeOne(function(ext) {
 return ext.loadNode && ext.loadNode(index);
 });
 break;
 case "mesh":
 dependency = this._invokeOne(function(ext) {
 return ext.loadMesh && ext.loadMesh(index);
 });
 break;
 case "accessor":
 dependency = this.loadAccessor(index);
 break;
 case "bufferView":
 dependency = this._invokeOne(function(ext) {
 return ext.loadBufferView && ext.loadBufferView(index);
 });
 break;
 case "buffer":
 dependency = this.loadBuffer(index);
 break;
 case "material":
 dependency = this._invokeOne(function(ext) {
 return ext.loadMaterial && ext.loadMaterial(index);
 });
 break;
 case "texture":
 dependency = this._invokeOne(function(ext) {
 return ext.loadTexture && ext.loadTexture(index);
 });
 break;
 case "skin":
 dependency = this.loadSkin(index);
 break;
 case "animation":
 dependency = this._invokeOne(function(ext) {
 return ext.loadAnimation && ext.loadAnimation(index);
 });
 break;
 case "camera":
 dependency = this.loadCamera(index);
 break;
 default:
 dependency = this._invokeOne(function(ext) {
 return ext != this && ext.getDependency && ext.getDependency(type, index);
 });
 if (!dependency) {
 throw new Error("Unknown type: " + type);
 }
 break;
 }
 this.cache.add(cacheKey, dependency);
 }
 return dependency;
 }
 /**
 * Requests all dependencies of the specified type asynchronously, with caching.
 * @param {string} type
 * @return {Promise<Array<Object>>}
 */
 getDependencies(type) {
 let dependencies = this.cache.get(type);
 if (!dependencies) {
 const parser = this;
 const 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>}
 */
 loadBuffer(bufferIndex) {
 const bufferDef = this.json.buffers[bufferIndex];
 const loader = this.fileLoader;
 if (bufferDef.type && bufferDef.type !== "arraybuffer") {
 throw new Error("THREE.GLTFLoader: " + bufferDef.type + " buffer type is not supported.");
 }
 if (bufferDef.uri === void 0 && bufferIndex === 0) {
 return Promise.resolve(this.extensions[EXTENSIONS.KHR_BINARY_GLTF].body);
 }
 const options = this.options;
 return new Promise(function(resolve, reject) {
 loader.load(THREE.LoaderUtils.resolveURL(bufferDef.uri, options.path), resolve, void 0, 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>}
 */
 loadBufferView(bufferViewIndex) {
 const bufferViewDef = this.json.bufferViews[bufferViewIndex];
 return this.getDependency("buffer", bufferViewDef.buffer).then(function(buffer) {
 const byteLength = bufferViewDef.byteLength || 0;
 const 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>}
 */
 loadAccessor(accessorIndex) {
 const parser = this;
 const json = this.json;
 const accessorDef = this.json.accessors[accessorIndex];
 if (accessorDef.bufferView === void 0 && accessorDef.sparse === void 0) {
 const itemSize = WEBGL_TYPE_SIZES[accessorDef.type];
 const TypedArray = WEBGL_COMPONENT_TYPES[accessorDef.componentType];
 const normalized = accessorDef.normalized === true;
 const array = new TypedArray(accessorDef.count * itemSize);
 return Promise.resolve(new THREE.BufferAttribute(array, itemSize, normalized));
 }
 const pendingBufferViews = [];
 if (accessorDef.bufferView !== void 0) {
 pendingBufferViews.push(this.getDependency("bufferView", accessorDef.bufferView));
 } else {
 pendingBufferViews.push(null);
 }
 if (accessorDef.sparse !== void 0) {
 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) {
 const bufferView = bufferViews[0];
 const itemSize = WEBGL_TYPE_SIZES[accessorDef.type];
 const TypedArray = WEBGL_COMPONENT_TYPES[accessorDef.componentType];
 const elementBytes = TypedArray.BYTES_PER_ELEMENT;
 const itemBytes = elementBytes * itemSize;
 const byteOffset = accessorDef.byteOffset || 0;
 const byteStride = accessorDef.bufferView !== void 0 ? json.bufferViews[accessorDef.bufferView].byteStride : void 0;
 const normalized = accessorDef.normalized === true;
 let array, bufferAttribute;
 if (byteStride && byteStride !== itemBytes) {
 const ibSlice = Math.floor(byteOffset / byteStride);
 const ibCacheKey = "InterleavedBuffer:" + accessorDef.bufferView + ":" + accessorDef.componentType + ":" + ibSlice + ":" + accessorDef.count;
 let ib = parser.cache.get(ibCacheKey);
 if (!ib) {
 array = new TypedArray(bufferView, ibSlice * byteStride, accessorDef.count * byteStride / elementBytes);
 ib = new THREE.InterleavedBuffer(array, byteStride / elementBytes);
 parser.cache.add(ibCacheKey, ib);
 }
 bufferAttribute = new THREE.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 THREE.BufferAttribute(array, itemSize, normalized);
 }
 if (accessorDef.sparse !== void 0) {
 const itemSizeIndices = WEBGL_TYPE_SIZES.SCALAR;
 const TypedArrayIndices = WEBGL_COMPONENT_TYPES[accessorDef.sparse.indices.componentType];
 const byteOffsetIndices = accessorDef.sparse.indices.byteOffset || 0;
 const byteOffsetValues = accessorDef.sparse.values.byteOffset || 0;
 const sparseIndices = new TypedArrayIndices(
 bufferViews[1],
 byteOffsetIndices,
 accessorDef.sparse.count * itemSizeIndices
 );
 const sparseValues = new TypedArray(bufferViews[2], byteOffsetValues, accessorDef.sparse.count * itemSize);
 if (bufferView !== null) {
 bufferAttribute = new THREE.BufferAttribute(
 bufferAttribute.array.slice(),
 bufferAttribute.itemSize,
 bufferAttribute.normalized
 );
 }
 for (let i = 0, il = sparseIndices.length; i < il; i++) {
 const 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|null>}
 */
 loadTexture(textureIndex) {
 const json = this.json;
 const options = this.options;
 const textureDef = json.textures[textureIndex];
 const sourceIndex = textureDef.source;
 const sourceDef = json.images[sourceIndex];
 let loader = this.textureLoader;
 if (sourceDef.uri) {
 const handler = options.manager.getHandler(sourceDef.uri);
 if (handler !== null)
 loader = handler;
 }
 return this.loadTextureImage(textureIndex, sourceIndex, loader);
 }
 loadTextureImage(textureIndex, sourceIndex, loader) {
 const parser = this;
 const json = this.json;
 const textureDef = json.textures[textureIndex];
 const sourceDef = json.images[sourceIndex];
 const cacheKey = (sourceDef.uri || sourceDef.bufferView) + ":" + textureDef.sampler;
 if (this.textureCache[cacheKey]) {
 return this.textureCache[cacheKey];
 }
 const promise = this.loadImageSource(sourceIndex, loader).then(function(texture) {
 texture.flipY = false;
 texture.name = textureDef.name || sourceDef.name || "";
 if (texture.name === "" && typeof sourceDef.uri === "string" && sourceDef.uri.startsWith("data:image/") === false) {
 texture.name = sourceDef.uri;
 }
 const samplers = json.samplers || {};
 const sampler = samplers[textureDef.sampler] || {};
 texture.magFilter = WEBGL_FILTERS[sampler.magFilter] || THREE.LinearFilter;
 texture.minFilter = WEBGL_FILTERS[sampler.minFilter] || THREE.LinearMipmapLinearFilter;
 texture.wrapS = WEBGL_WRAPPINGS[sampler.wrapS] || THREE.RepeatWrapping;
 texture.wrapT = WEBGL_WRAPPINGS[sampler.wrapT] || THREE.RepeatWrapping;
 parser.associations.set(texture, { textures: textureIndex });
 return texture;
 }).catch(function() {
 return null;
 });
 this.textureCache[cacheKey] = promise;
 return promise;
 }
 loadImageSource(sourceIndex, loader) {
 const parser = this;
 const json = this.json;
 const options = this.options;
 if (this.sourceCache[sourceIndex] !== void 0) {
 return this.sourceCache[sourceIndex].then((texture) => texture.clone());
 }
 const sourceDef = json.images[sourceIndex];
 const URL = self.URL || self.webkitURL;
 let sourceURI = sourceDef.uri || "";
 let isObjectURL = false;
 if (sourceDef.bufferView !== void 0) {
 sourceURI = parser.getDependency("bufferView", sourceDef.bufferView).then(function(bufferView) {
 isObjectURL = true;
 const blob = new Blob([bufferView], { type: sourceDef.mimeType });
 sourceURI = URL.createObjectURL(blob);
 return sourceURI;
 });
 } else if (sourceDef.uri === void 0) {
 throw new Error("THREE.GLTFLoader: Image " + sourceIndex + " is missing URI and bufferView");
 }
 const promise = Promise.resolve(sourceURI).then(function(sourceURI2) {
 return new Promise(function(resolve, reject) {
 let onLoad = resolve;
 if (loader.isImageBitmapLoader === true) {
 onLoad = function(imageBitmap) {
 const texture = new THREE.Texture(imageBitmap);
 texture.needsUpdate = true;
 resolve(texture);
 };
 }
 loader.load(THREE.LoaderUtils.resolveURL(sourceURI2, options.path), onLoad, void 0, reject);
 });
 }).then(function(texture) {
 if (isObjectURL === true) {
 URL.revokeObjectURL(sourceURI);
 }
 assignExtrasToUserData(texture, sourceDef);
 texture.userData.mimeType = sourceDef.mimeType || getImageURIMimeType(sourceDef.uri);
 return texture;
 }).catch(function(error) {
 console.error("THREE.GLTFLoader: Couldn't load texture", sourceURI);
 throw error;
 });
 this.sourceCache[sourceIndex] = promise;
 return promise;
 }
 /**
 * Asynchronously assigns a texture to the given material parameters.
 * @param {Object} materialParams
 * @param {string} mapName
 * @param {Object} mapDef
 * @return {Promise<Texture>}
 */
 assignTexture(materialParams, mapName, mapDef, colorSpace) {
 const parser = this;
 return this.getDependency("texture", mapDef.index).then(function(texture) {
 if (!texture)
 return null;
 if (mapDef.texCoord !== void 0 && mapDef.texCoord > 0) {
 texture = texture.clone();
 texture.channel = mapDef.texCoord;
 }
 if (parser.extensions[EXTENSIONS.KHR_TEXTURE_TRANSFORM]) {
 const transform = mapDef.extensions !== void 0 ? mapDef.extensions[EXTENSIONS.KHR_TEXTURE_TRANSFORM] : void 0;
 if (transform) {
 const gltfReference = parser.associations.get(texture);
 texture = parser.extensions[EXTENSIONS.KHR_TEXTURE_TRANSFORM].extendTexture(texture, transform);
 parser.associations.set(texture, gltfReference);
 }
 }
 if (colorSpace !== void 0) {
 if (typeof colorSpace === "number")
 colorSpace = colorSpace === sRGBEncoding ? SRGBColorSpace : LinearSRGBColorSpace;
 if ("colorSpace" in texture)
 texture.colorSpace = colorSpace;
 else
 texture.encoding = colorSpace === SRGBColorSpace ? sRGBEncoding : LinearEncoding;
 }
 materialParams[mapName] = texture;
 return 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 accommodate 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.
 */
 assignFinalMaterial(mesh) {
 const geometry = mesh.geometry;
 let material = mesh.material;
 const useDerivativeTangents = geometry.attributes.tangent === void 0;
 const useVertexColors = geometry.attributes.color !== void 0;
 const useFlatShading = geometry.attributes.normal === void 0;
 if (mesh.isPoints) {
 const cacheKey = "PointsMaterial:" + material.uuid;
 let pointsMaterial = this.cache.get(cacheKey);
 if (!pointsMaterial) {
 pointsMaterial = new THREE.PointsMaterial();
 THREE.Material.prototype.copy.call(pointsMaterial, material);
 pointsMaterial.color.copy(material.color);
 pointsMaterial.map = material.map;
 pointsMaterial.sizeAttenuation = false;
 this.cache.add(cacheKey, pointsMaterial);
 }
 material = pointsMaterial;
 } else if (mesh.isLine) {
 const cacheKey = "LineBasicMaterial:" + material.uuid;
 let lineMaterial = this.cache.get(cacheKey);
 if (!lineMaterial) {
 lineMaterial = new THREE.LineBasicMaterial();
 THREE.Material.prototype.copy.call(lineMaterial, material);
 lineMaterial.color.copy(material.color);
 lineMaterial.map = material.map;
 this.cache.add(cacheKey, lineMaterial);
 }
 material = lineMaterial;
 }
 if (useDerivativeTangents || useVertexColors || useFlatShading) {
 let cacheKey = "ClonedMaterial:" + material.uuid + ":";
 if (useDerivativeTangents)
 cacheKey += "derivative-tangents:";
 if (useVertexColors)
 cacheKey += "vertex-colors:";
 if (useFlatShading)
 cacheKey += "flat-shading:";
 let cachedMaterial = this.cache.get(cacheKey);
 if (!cachedMaterial) {
 cachedMaterial = material.clone();
 if (useVertexColors)
 cachedMaterial.vertexColors = true;
 if (useFlatShading)
 cachedMaterial.flatShading = true;
 if (useDerivativeTangents) {
 if (cachedMaterial.normalScale)
 cachedMaterial.normalScale.y *= -1;
 if (cachedMaterial.clearcoatNormalScale)
 cachedMaterial.clearcoatNormalScale.y *= -1;
 }
 this.cache.add(cacheKey, cachedMaterial);
 this.associations.set(cachedMaterial, this.associations.get(material));
 }
 material = cachedMaterial;
 }
 mesh.material = material;
 }
 getMaterialType() {
 return THREE.MeshStandardMaterial;
 }
 /**
 * Specification: https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#materials
 * @param {number} materialIndex
 * @return {Promise<Material>}
 */
 loadMaterial(materialIndex) {
 const parser = this;
 const json = this.json;
 const extensions = this.extensions;
 const materialDef = json.materials[materialIndex];
 let materialType;
 const materialParams = {};
 const materialExtensions = materialDef.extensions || {};
 const pending = [];
 if (materialExtensions[EXTENSIONS.KHR_MATERIALS_UNLIT]) {
 const kmuExtension = extensions[EXTENSIONS.KHR_MATERIALS_UNLIT];
 materialType = kmuExtension.getMaterialType();
 pending.push(kmuExtension.extendParams(materialParams, materialDef, parser));
 } else {
 const metallicRoughness = materialDef.pbrMetallicRoughness || {};
 materialParams.color = new THREE.Color(1, 1, 1);
 materialParams.opacity = 1;
 if (Array.isArray(metallicRoughness.baseColorFactor)) {
 const array = metallicRoughness.baseColorFactor;
 materialParams.color.setRGB(array[0], array[1], array[2], LinearSRGBColorSpace);
 materialParams.opacity = array[3];
 }
 if (metallicRoughness.baseColorTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "map", metallicRoughness.baseColorTexture, SRGBColorSpace));
 }
 materialParams.metalness = metallicRoughness.metallicFactor !== void 0 ? metallicRoughness.metallicFactor : 1;
 materialParams.roughness = metallicRoughness.roughnessFactor !== void 0 ? metallicRoughness.roughnessFactor : 1;
 if (metallicRoughness.metallicRoughnessTexture !== void 0) {
 pending.push(parser.assignTexture(materialParams, "metalnessMap", metallicRoughness.metallicRoughnessTexture));
 pending.push(parser.assignTexture(materialParams, "roughnessMap", metallicRoughness.metallicRoughnessTexture));
 }
 materialType = this._invokeOne(function(ext) {
 return ext.getMaterialType && ext.getMaterialType(materialIndex);
 });
 pending.push(
 Promise.all(
 this._invokeAll(function(ext) {
 return ext.extendMaterialParams && ext.extendMaterialParams(materialIndex, materialParams);
 })
 )
 );
 }
 if (materialDef.doubleSided === true) {
 materialParams.side = THREE.DoubleSide;
 }
 const alphaMode = materialDef.alphaMode || ALPHA_MODES.OPAQUE;
 if (alphaMode === ALPHA_MODES.BLEND) {
 materialParams.transparent = true;
 materialParams.depthWrite = false;
 } else {
 materialParams.transparent = false;
 if (alphaMode === ALPHA_MODES.MASK) {
 materialParams.alphaTest = materialDef.alphaCutoff !== void 0 ? materialDef.alphaCutoff : 0.5;
 }
 }
 if (materialDef.normalTexture !== void 0 && materialType !== THREE.MeshBasicMaterial) {
 pending.push(parser.assignTexture(materialParams, "normalMap", materialDef.normalTexture));
 materialParams.normalScale = new THREE.Vector2(1, 1);
 if (materialDef.normalTexture.scale !== void 0) {
 const scale = materialDef.normalTexture.scale;
 materialParams.normalScale.set(scale, scale);
 }
 }
 if (materialDef.occlusionTexture !== void 0 && materialType !== THREE.MeshBasicMaterial) {
 pending.push(parser.assignTexture(materialParams, "aoMap", materialDef.occlusionTexture));
 if (materialDef.occlusionTexture.strength !== void 0) {
 materialParams.aoMapIntensity = materialDef.occlusionTexture.strength;
 }
 }
 if (materialDef.emissiveFactor !== void 0 && materialType !== THREE.MeshBasicMaterial) {
 const emissiveFactor = materialDef.emissiveFactor;
 materialParams.emissive = new THREE.Color().setRGB(
 emissiveFactor[0],
 emissiveFactor[1],
 emissiveFactor[2],
 LinearSRGBColorSpace
 );
 }
 if (materialDef.emissiveTexture !== void 0 && materialType !== THREE.MeshBasicMaterial) {
 pending.push(parser.assignTexture(materialParams, "emissiveMap", materialDef.emissiveTexture, SRGBColorSpace));
 }
 return Promise.all(pending).then(function() {
 const material = new materialType(materialParams);
 if (materialDef.name)
 material.name = materialDef.name;
 assignExtrasToUserData(material, materialDef);
 parser.associations.set(material, { materials: materialIndex });
 if (materialDef.extensions)
 addUnknownExtensionsToUserData(extensions, material, materialDef);
 return material;
 });
 }
 /** When Object3D instances are targeted by animation, they need unique names. */
 createUniqueName(originalName) {
 const sanitizedName = THREE.PropertyBinding.sanitizeNodeName(originalName || "");
 if (sanitizedName in this.nodeNamesUsed) {
 return sanitizedName + "_" + ++this.nodeNamesUsed[sanitizedName];
 } else {
 this.nodeNamesUsed[sanitizedName] = 0;
 return sanitizedName;
 }
 }
 /**
 * 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>>}
 */
 loadGeometries(primitives) {
 const parser = this;
 const extensions = this.extensions;
 const cache = this.primitiveCache;
 function createDracoPrimitive(primitive) {
 return extensions[EXTENSIONS.KHR_DRACO_MESH_COMPRESSION].decodePrimitive(primitive, parser).then(function(geometry) {
 return addPrimitiveAttributes(geometry, primitive, parser);
 });
 }
 const pending = [];
 for (let i = 0, il = primitives.length; i < il; i++) {
 const primitive = primitives[i];
 const cacheKey = createPrimitiveKey(primitive);
 const cached = cache[cacheKey];
 if (cached) {
 pending.push(cached.promise);
 } else {
 let geometryPromise;
 if (primitive.extensions && primitive.extensions[EXTENSIONS.KHR_DRACO_MESH_COMPRESSION]) {
 geometryPromise = createDracoPrimitive(primitive);
 } else {
 geometryPromise = addPrimitiveAttributes(new THREE.BufferGeometry(), primitive, parser);
 }
 cache[cacheKey] = { 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>}
 */
 loadMesh(meshIndex) {
 const parser = this;
 const json = this.json;
 const extensions = this.extensions;
 const meshDef = json.meshes[meshIndex];
 const primitives = meshDef.primitives;
 const pending = [];
 for (let i = 0, il = primitives.length; i < il; i++) {
 const material = primitives[i].material === void 0 ? createDefaultMaterial(this.cache) : this.getDependency("material", primitives[i].material);
 pending.push(material);
 }
 pending.push(parser.loadGeometries(primitives));
 return Promise.all(pending).then(function(results) {
 const materials = results.slice(0, results.length - 1);
 const geometries = results[results.length - 1];
 const meshes = [];
 for (let i = 0, il = geometries.length; i < il; i++) {
 const geometry = geometries[i];
 const primitive = primitives[i];
 let mesh;
 const material = materials[i];
 if (primitive.mode === WEBGL_CONSTANTS.TRIANGLES || primitive.mode === WEBGL_CONSTANTS.TRIANGLE_STRIP || primitive.mode === WEBGL_CONSTANTS.TRIANGLE_FAN || primitive.mode === void 0) {
 mesh = meshDef.isSkinnedMesh === true ? new THREE.SkinnedMesh(geometry, material) : new THREE.Mesh(geometry, material);
 if (mesh.isSkinnedMesh === true) {
 mesh.normalizeSkinWeights();
 }
 if (primitive.mode === WEBGL_CONSTANTS.TRIANGLE_STRIP) {
 mesh.geometry = BufferGeometryUtils.toTrianglesDrawMode(mesh.geometry, THREE.TriangleStripDrawMode);
 } else if (primitive.mode === WEBGL_CONSTANTS.TRIANGLE_FAN) {
 mesh.geometry = BufferGeometryUtils.toTrianglesDrawMode(mesh.geometry, THREE.TriangleFanDrawMode);
 }
 } else if (primitive.mode === WEBGL_CONSTANTS.LINES) {
 mesh = new THREE.LineSegments(geometry, material);
 } else if (primitive.mode === WEBGL_CONSTANTS.LINE_STRIP) {
 mesh = new THREE.Line(geometry, material);
 } else if (primitive.mode === WEBGL_CONSTANTS.LINE_LOOP) {
 mesh = new THREE.LineLoop(geometry, material);
 } else if (primitive.mode === WEBGL_CONSTANTS.POINTS) {
 mesh = new THREE.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 = parser.createUniqueName(meshDef.name || "mesh_" + meshIndex);
 assignExtrasToUserData(mesh, meshDef);
 if (primitive.extensions)
 addUnknownExtensionsToUserData(extensions, mesh, primitive);
 parser.assignFinalMaterial(mesh);
 meshes.push(mesh);
 }
 for (let i = 0, il = meshes.length; i < il; i++) {
 parser.associations.set(meshes[i], {
 meshes: meshIndex,
 primitives: i
 });
 }
 if (meshes.length === 1) {
 if (meshDef.extensions)
 addUnknownExtensionsToUserData(extensions, meshes[0], meshDef);
 return meshes[0];
 }
 const group = new THREE.Group();
 if (meshDef.extensions)
 addUnknownExtensionsToUserData(extensions, group, meshDef);
 parser.associations.set(group, { meshes: meshIndex });
 for (let 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>}
 */
 loadCamera(cameraIndex) {
 let camera;
 const cameraDef = this.json.cameras[cameraIndex];
 const params = cameraDef[cameraDef.type];
 if (!params) {
 console.warn("THREE.GLTFLoader: Missing camera parameters.");
 return;
 }
 if (cameraDef.type === "perspective") {
 camera = new THREE.PerspectiveCamera(
 THREE.MathUtils.radToDeg(params.yfov),
 params.aspectRatio || 1,
 params.znear || 1,
 params.zfar || 2e6
 );
 } else if (cameraDef.type === "orthographic") {
 camera = new THREE.OrthographicCamera(-params.xmag, params.xmag, params.ymag, -params.ymag, params.znear, params.zfar);
 }
 if (cameraDef.name)
 camera.name = this.createUniqueName(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<Skeleton>}
 */
 loadSkin(skinIndex) {
 const skinDef = this.json.skins[skinIndex];
 const pending = [];
 for (let i = 0, il = skinDef.joints.length; i < il; i++) {
 pending.push(this._loadNodeShallow(skinDef.joints[i]));
 }
 if (skinDef.inverseBindMatrices !== void 0) {
 pending.push(this.getDependency("accessor", skinDef.inverseBindMatrices));
 } else {
 pending.push(null);
 }
 return Promise.all(pending).then(function(results) {
 const inverseBindMatrices = results.pop();
 const jointNodes = results;
 const bones = [];
 const boneInverses = [];
 for (let i = 0, il = jointNodes.length; i < il; i++) {
 const jointNode = jointNodes[i];
 if (jointNode) {
 bones.push(jointNode);
 const mat = new THREE.Matrix4();
 if (inverseBindMatrices !== null) {
 mat.fromArray(inverseBindMatrices.array, i * 16);
 }
 boneInverses.push(mat);
 } else {
 console.warn('THREE.GLTFLoader: Joint "%s" could not be found.', skinDef.joints[i]);
 }
 }
 return new THREE.Skeleton(bones, boneInverses);
 });
 }
 /**
 * Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#animations
 * @param {number} animationIndex
 * @return {Promise<AnimationClip>}
 */
 loadAnimation(animationIndex) {
 const json = this.json;
 const parser = this;
 const animationDef = json.animations[animationIndex];
 const animationName = animationDef.name ? animationDef.name : "animation_" + animationIndex;
 const pendingNodes = [];
 const pendingInputAccessors = [];
 const pendingOutputAccessors = [];
 const pendingSamplers = [];
 const pendingTargets = [];
 for (let i = 0, il = animationDef.channels.length; i < il; i++) {
 const channel = animationDef.channels[i];
 const sampler = animationDef.samplers[channel.sampler];
 const target = channel.target;
 const name = target.node;
 const input = animationDef.parameters !== void 0 ? animationDef.parameters[sampler.input] : sampler.input;
 const output = animationDef.parameters !== void 0 ? animationDef.parameters[sampler.output] : sampler.output;
 if (target.node === void 0)
 continue;
 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) {
 const nodes = dependencies[0];
 const inputAccessors = dependencies[1];
 const outputAccessors = dependencies[2];
 const samplers = dependencies[3];
 const targets = dependencies[4];
 const tracks = [];
 for (let i = 0, il = nodes.length; i < il; i++) {
 const node = nodes[i];
 const inputAccessor = inputAccessors[i];
 const outputAccessor = outputAccessors[i];
 const sampler = samplers[i];
 const target = targets[i];
 if (node === void 0)
 continue;
 if (node.updateMatrix) {
 node.updateMatrix();
 }
 const createdTracks = parser._createAnimationTracks(node, inputAccessor, outputAccessor, sampler, target);
 if (createdTracks) {
 for (let k = 0; k < createdTracks.length; k++) {
 tracks.push(createdTracks[k]);
 }
 }
 }
 return new THREE.AnimationClip(animationName, void 0, tracks);
 });
 }
 createNodeMesh(nodeIndex) {
 const json = this.json;
 const parser = this;
 const nodeDef = json.nodes[nodeIndex];
 if (nodeDef.mesh === void 0)
 return null;
 return parser.getDependency("mesh", nodeDef.mesh).then(function(mesh) {
 const node = parser._getNodeRef(parser.meshCache, nodeDef.mesh, mesh);
 if (nodeDef.weights !== void 0) {
 node.traverse(function(o) {
 if (!o.isMesh)
 return;
 for (let i = 0, il = nodeDef.weights.length; i < il; i++) {
 o.morphTargetInfluences[i] = nodeDef.weights[i];
 }
 });
 }
 return node;
 });
 }
 /**
 * Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#nodes-and-hierarchy
 * @param {number} nodeIndex
 * @return {Promise<Object3D>}
 */
 loadNode(nodeIndex) {
 const json = this.json;
 const parser = this;
 const nodeDef = json.nodes[nodeIndex];
 const nodePending = parser._loadNodeShallow(nodeIndex);
 const childPending = [];
 const childrenDef = nodeDef.children || [];
 for (let i = 0, il = childrenDef.length; i < il; i++) {
 childPending.push(parser.getDependency("node", childrenDef[i]));
 }
 const skeletonPending = nodeDef.skin === void 0 ? Promise.resolve(null) : parser.getDependency("skin", nodeDef.skin);
 return Promise.all([nodePending, Promise.all(childPending), skeletonPending]).then(function(results) {
 const node = results[0];
 const children = results[1];
 const skeleton = results[2];
 if (skeleton !== null) {
 node.traverse(function(mesh) {
 if (!mesh.isSkinnedMesh)
 return;
 mesh.bind(skeleton, _identityMatrix);
 });
 }
 for (let i = 0, il = children.length; i < il; i++) {
 node.add(children[i]);
 }
 return node;
 });
 }
 // ._loadNodeShallow() parses a single node.
 // skin and child nodes are created and added in .loadNode() (no '_' prefix).
 _loadNodeShallow(nodeIndex) {
 const json = this.json;
 const extensions = this.extensions;
 const parser = this;
 if (this.nodeCache[nodeIndex] !== void 0) {
 return this.nodeCache[nodeIndex];
 }
 const nodeDef = json.nodes[nodeIndex];
 const nodeName = nodeDef.name ? parser.createUniqueName(nodeDef.name) : "";
 const pending = [];
 const meshPromise = parser._invokeOne(function(ext) {
 return ext.createNodeMesh && ext.createNodeMesh(nodeIndex);
 });
 if (meshPromise) {
 pending.push(meshPromise);
 }
 if (nodeDef.camera !== void 0) {
 pending.push(
 parser.getDependency("camera", nodeDef.camera).then(function(camera) {
 return parser._getNodeRef(parser.cameraCache, nodeDef.camera, camera);
 })
 );
 }
 parser._invokeAll(function(ext) {
 return ext.createNodeAttachment && ext.createNodeAttachment(nodeIndex);
 }).forEach(function(promise) {
 pending.push(promise);
 });
 this.nodeCache[nodeIndex] = Promise.all(pending).then(function(objects) {
 let node;
 if (nodeDef.isBone === true) {
 node = new THREE.Bone();
 } else if (objects.length > 1) {
 node = new THREE.Group();
 } else if (objects.length === 1) {
 node = objects[0];
 } else {
 node = new THREE.Object3D();
 }
 if (node !== objects[0]) {
 for (let i = 0, il = objects.length; i < il; i++) {
 node.add(objects[i]);
 }
 }
 if (nodeDef.name) {
 node.userData.name = nodeDef.name;
 node.name = nodeName;
 }
 assignExtrasToUserData(node, nodeDef);
 if (nodeDef.extensions)
 addUnknownExtensionsToUserData(extensions, node, nodeDef);
 if (nodeDef.matrix !== void 0) {
 const matrix = new THREE.Matrix4();
 matrix.fromArray(nodeDef.matrix);
 node.applyMatrix4(matrix);
 } else {
 if (nodeDef.translation !== void 0) {
 node.position.fromArray(nodeDef.translation);
 }
 if (nodeDef.rotation !== void 0) {
 node.quaternion.fromArray(nodeDef.rotation);
 }
 if (nodeDef.scale !== void 0) {
 node.scale.fromArray(nodeDef.scale);
 }
 }
 if (!parser.associations.has(node)) {
 parser.associations.set(node, {});
 }
 parser.associations.get(node).nodes = nodeIndex;
 return node;
 });
 return this.nodeCache[nodeIndex];
 }
 /**
 * Specification: https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#scenes
 * @param {number} sceneIndex
 * @return {Promise<Group>}
 */
 loadScene(sceneIndex) {
 const extensions = this.extensions;
 const sceneDef = this.json.scenes[sceneIndex];
 const parser = this;
 const scene = new THREE.Group();
 if (sceneDef.name)
 scene.name = parser.createUniqueName(sceneDef.name);
 assignExtrasToUserData(scene, sceneDef);
 if (sceneDef.extensions)
 addUnknownExtensionsToUserData(extensions, scene, sceneDef);
 const nodeIds = sceneDef.nodes || [];
 const pending = [];
 for (let i = 0, il = nodeIds.length; i < il; i++) {
 pending.push(parser.getDependency("node", nodeIds[i]));
 }
 return Promise.all(pending).then(function(nodes) {
 for (let i = 0, il = nodes.length; i < il; i++) {
 scene.add(nodes[i]);
 }
 const reduceAssociations = (node) => {
 const reducedAssociations = /* @__PURE__ */ new Map();
 for (const [key, value] of parser.associations) {
 if (key instanceof THREE.Material || key instanceof THREE.Texture) {
 reducedAssociations.set(key, value);
 }
 }
 node.traverse((node2) => {
 const mappings = parser.associations.get(node2);
 if (mappings != null) {
 reducedAssociations.set(node2, mappings);
 }
 });
 return reducedAssociations;
 };
 parser.associations = reduceAssociations(scene);
 return scene;
 });
 }
 _createAnimationTracks(node, inputAccessor, outputAccessor, sampler, target) {
 const tracks = [];
 const targetName = node.name ? node.name : node.uuid;
 const targetNames = [];
 if (PATH_PROPERTIES[target.path] === PATH_PROPERTIES.weights) {
 node.traverse(function(object) {
 if (object.morphTargetInfluences) {
 targetNames.push(object.name ? object.name : object.uuid);
 }
 });
 } else {
 targetNames.push(targetName);
 }
 let TypedKeyframeTrack;
 switch (PATH_PROPERTIES[target.path]) {
 case PATH_PROPERTIES.weights:
 TypedKeyframeTrack = THREE.NumberKeyframeTrack;
 break;
 case PATH_PROPERTIES.rotation:
 TypedKeyframeTrack = THREE.QuaternionKeyframeTrack;
 break;
 case PATH_PROPERTIES.position:
 case PATH_PROPERTIES.scale:
 TypedKeyframeTrack = THREE.VectorKeyframeTrack;
 break;
 default:
 switch (outputAccessor.itemSize) {
 case 1:
 TypedKeyframeTrack = THREE.NumberKeyframeTrack;
 break;
 case 2:
 case 3:
 default:
 TypedKeyframeTrack = THREE.VectorKeyframeTrack;
 break;
 }
 break;
 }
 const interpolation = sampler.interpolation !== void 0 ? INTERPOLATION[sampler.interpolation] : THREE.InterpolateLinear;
 const outputArray = this._getArrayFromAccessor(outputAccessor);
 for (let j = 0, jl = targetNames.length; j < jl; j++) {
 const track = new TypedKeyframeTrack(
 targetNames[j] + "." + PATH_PROPERTIES[target.path],
 inputAccessor.array,
 outputArray,
 interpolation
 );
 if (sampler.interpolation === "CUBICSPLINE") {
 this._createCubicSplineTrackInterpolant(track);
 }
 tracks.push(track);
 }
 return tracks;
 }
 _getArrayFromAccessor(accessor) {
 let outputArray = accessor.array;
 if (accessor.normalized) {
 const scale = getNormalizedComponentScale(outputArray.constructor);
 const scaled = new Float32Array(outputArray.length);
 for (let j = 0, jl = outputArray.length; j < jl; j++) {
 scaled[j] = outputArray[j] * scale;
 }
 outputArray = scaled;
 }
 return outputArray;
 }
 _createCubicSplineTrackInterpolant(track) {
 track.createInterpolant = function InterpolantFactoryMethodGLTFCubicSpline(result) {
 const interpolantType = this instanceof THREE.QuaternionKeyframeTrack ? GLTFCubicSplineQuaternionInterpolant : GLTFCubicSplineInterpolant;
 return new interpolantType(this.times, this.values, this.getValueSize() / 3, result);
 };
 track.createInterpolant.isInterpolantFactoryMethodGLTFCubicSpline = true;
 }
}
function computeBounds(geometry, primitiveDef, parser) {
 const attributes = primitiveDef.attributes;
 const box = new THREE.Box3();
 if (attributes.POSITION !== void 0) {
 const accessor = parser.json.accessors[attributes.POSITION];
 const min = accessor.min;
 const max = accessor.max;
 if (min !== void 0 && max !== void 0) {
 box.set(new THREE.Vector3(min[0], min[1], min[2]), new THREE.Vector3(max[0], max[1], max[2]));
 if (accessor.normalized) {
 const boxScale = getNormalizedComponentScale(WEBGL_COMPONENT_TYPES[accessor.componentType]);
 box.min.multiplyScalar(boxScale);
 box.max.multiplyScalar(boxScale);
 }
 } else {
 console.warn("THREE.GLTFLoader: Missing min/max properties for accessor POSITION.");
 return;
 }
 } else {
 return;
 }
 const targets = primitiveDef.targets;
 if (targets !== void 0) {
 const maxDisplacement = new THREE.Vector3();
 const vector = new THREE.Vector3();
 for (let i = 0, il = targets.length; i < il; i++) {
 const target = targets[i];
 if (target.POSITION !== void 0) {
 const accessor = parser.json.accessors[target.POSITION];
 const min = accessor.min;
 const max = accessor.max;
 if (min !== void 0 && max !== void 0) {
 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])));
 if (accessor.normalized) {
 const boxScale = getNormalizedComponentScale(WEBGL_COMPONENT_TYPES[accessor.componentType]);
 vector.multiplyScalar(boxScale);
 }
 maxDisplacement.max(vector);
 } else {
 console.warn("THREE.GLTFLoader: Missing min/max properties for accessor POSITION.");
 }
 }
 }
 box.expandByVector(maxDisplacement);
 }
 geometry.boundingBox = box;
 const sphere = new THREE.Sphere();
 box.getCenter(sphere.center);
 sphere.radius = box.min.distanceTo(box.max) / 2;
 geometry.boundingSphere = sphere;
}
function addPrimitiveAttributes(geometry, primitiveDef, parser) {
 const attributes = primitiveDef.attributes;
 const pending = [];
 function assignAttributeAccessor(accessorIndex, attributeName) {
 return parser.getDependency("accessor", accessorIndex).then(function(accessor) {
 geometry.setAttribute(attributeName, accessor);
 });
 }
 for (const gltfAttributeName in attributes) {
 const threeAttributeName = ATTRIBUTES[gltfAttributeName] || gltfAttributeName.toLowerCase();
 if (threeAttributeName in geometry.attributes)
 continue;
 pending.push(assignAttributeAccessor(attributes[gltfAttributeName], threeAttributeName));
 }
 if (primitiveDef.indices !== void 0 && !geometry.index) {
 const accessor = parser.getDependency("accessor", primitiveDef.indices).then(function(accessor2) {
 geometry.setIndex(accessor2);
 });
 pending.push(accessor);
 }
 assignExtrasToUserData(geometry, primitiveDef);
 computeBounds(geometry, primitiveDef, parser);
 return Promise.all(pending).then(function() {
 return primitiveDef.targets !== void 0 ? addMorphTargets(geometry, primitiveDef.targets, parser) : geometry;
 });
}
exports.GLTFLoader = GLTFLoader;
//# sourceMappingURL=GLTFLoader.cjs.map

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