/** * @author fernandojsg / http://fernandojsg.com * @author Don McCurdy / https://www.donmccurdy.com * @author Takahiro / https://github.com/takahirox */ (function() { let BufferAttribute = THREE.BufferAttribute; let BufferGeometry = THREE.BufferGeometry; let ClampToEdgeWrapping = THREE.ClampToEdgeWrapping; let DoubleSide = THREE.DoubleSide; let InterpolateDiscrete = THREE.InterpolateDiscrete; let InterpolateLinear = THREE.InterpolateLinear; let LinearFilter = THREE.LinearFilter; let LinearMipmapLinearFilter = THREE.LinearMipmapLinearFilter; let LinearMipmapNearestFilter = THREE.LinearMipmapNearestFilter; let MathUtils = THREE.Math; let MirroredRepeatWrapping = THREE.MirroredRepeatWrapping; let NearestFilter = THREE.NearestFilter; let NearestMipmapLinearFilter = THREE.NearestMipmapLinearFilter; let NearestMipmapNearestFilter = THREE.NearestMipmapNearestFilter; let PropertyBinding = THREE.PropertyBinding; let RGBAFormat = THREE.RGBAFormat; let RepeatWrapping = THREE.RepeatWrapping; let Scene = THREE.Scene; let Vector3 = THREE.Vector3; //------------------------------------------------------------------------------ // Constants //------------------------------------------------------------------------------ var WEBGL_CONSTANTS = { POINTS: 0x0000, LINES: 0x0001, LINE_LOOP: 0x0002, LINE_STRIP: 0x0003, TRIANGLES: 0x0004, TRIANGLE_STRIP: 0x0005, TRIANGLE_FAN: 0x0006, UNSIGNED_BYTE: 0x1401, UNSIGNED_SHORT: 0x1403, FLOAT: 0x1406, UNSIGNED_INT: 0x1405, ARRAY_BUFFER: 0x8892, ELEMENT_ARRAY_BUFFER: 0x8893, NEAREST: 0x2600, LINEAR: 0x2601, NEAREST_MIPMAP_NEAREST: 0x2700, LINEAR_MIPMAP_NEAREST: 0x2701, NEAREST_MIPMAP_LINEAR: 0x2702, LINEAR_MIPMAP_LINEAR: 0x2703, CLAMP_TO_EDGE: 33071, MIRRORED_REPEAT: 33648, REPEAT: 10497 }; var img = this.img = new Image() img.src = 'data:image/png;base64,iVBORw0KGgoAAAANSUhEUgAAAAEAAAABCAYAAAAfFcSJAAAAC0lEQVQYV2NgAAIAAAUAAarVyFEAAAAASUVORK5CYII=' var tex = new THREE.Texture(img) img.tex = tex; img.tex.magFilter = THREE.NearestFilter img.tex.minFilter = THREE.NearestFilter var invisibleMaterial = new THREE.MeshLambertMaterial({ color: 0xffffff, map: tex, transparent: true, alphaTest: 0.2 }); var THREE_TO_WEBGL = {}; THREE_TO_WEBGL[ NearestFilter ] = WEBGL_CONSTANTS.NEAREST; THREE_TO_WEBGL[ NearestMipmapNearestFilter ] = WEBGL_CONSTANTS.NEAREST_MIPMAP_NEAREST; THREE_TO_WEBGL[ NearestMipmapLinearFilter ] = WEBGL_CONSTANTS.NEAREST_MIPMAP_LINEAR; THREE_TO_WEBGL[ LinearFilter ] = WEBGL_CONSTANTS.LINEAR; THREE_TO_WEBGL[ LinearMipmapNearestFilter ] = WEBGL_CONSTANTS.LINEAR_MIPMAP_NEAREST; THREE_TO_WEBGL[ LinearMipmapLinearFilter ] = WEBGL_CONSTANTS.LINEAR_MIPMAP_LINEAR; THREE_TO_WEBGL[ ClampToEdgeWrapping ] = WEBGL_CONSTANTS.CLAMP_TO_EDGE; THREE_TO_WEBGL[ RepeatWrapping ] = WEBGL_CONSTANTS.REPEAT; THREE_TO_WEBGL[ MirroredRepeatWrapping ] = WEBGL_CONSTANTS.MIRRORED_REPEAT; var PATH_PROPERTIES = { scale: 'scale', position: 'translation', quaternion: 'rotation', morphTargetInfluences: 'weights' }; //------------------------------------------------------------------------------ // GLTF Exporter //------------------------------------------------------------------------------ var GLTFExporter = function () {}; GLTFExporter.prototype = { constructor: GLTFExporter, /** * Parse scenes and generate GLTF output * @param {Scene or [THREE.Scenes]} input Scene or Array of THREE.Scenes * @param {Function} onDone Callback on completed * @param {Object} options options */ parse: function ( input, onDone, options ) { var DEFAULT_OPTIONS = { binary: false, trs: false, onlyVisible: true, truncateDrawRange: true, embedImages: true, maxTextureSize: Infinity, exportFaceColors: true, animations: [], forceIndices: false, forcePowerOfTwoTextures: false, includeCustomExtensions: false }; options = Object.assign( {}, DEFAULT_OPTIONS, options ); if ( options.animations.length > 0 ) { // Only TRS properties, and not matrices, may be targeted by animation. options.trs = true; } var outputJSON = { asset: { version: `2.0`, generator: `Blockbench ${appVersion} glTF exporter` } }; var byteOffset = 0; var buffers = []; var pending = []; var nodeMap = new Map(); var skins = []; var extensionsUsed = {}; var cachedData = { meshes: new Map(), attributes: new Map(), attributesNormalized: new Map(), materials: new Map(), textures: new Map(), images: new Map() }; var cachedCanvas; var uids = new Map(); var uid = 0; /** * Assign and return a temporal unique id for an object * especially which doesn't have .uuid * @param {Object} object * @return {Integer} */ function getUID( object ) { if ( ! uids.has( object ) ) uids.set( object, uid ++ ); return uids.get( object ); } /** * Compare two arrays * @param {Array} array1 Array 1 to compare * @param {Array} array2 Array 2 to compare * @return {Boolean} Returns true if both arrays are equal */ function equalArray( array1, array2 ) { return ( array1.length === array2.length ) && array1.every( function ( element, index ) { return element === array2[ index ]; } ); } /** * Converts a string to an ArrayBuffer. * @param {string} text * @return {ArrayBuffer} */ function stringToArrayBuffer( text ) { if ( window.TextEncoder !== undefined ) { return new TextEncoder().encode( text ).buffer; } var array = new Uint8Array( new ArrayBuffer( text.length ) ); for ( var i = 0, il = text.length; i < il; i ++ ) { var value = text.charCodeAt( i ); // Replacing multi-byte character with space(0x20). array[ i ] = value > 0xFF ? 0x20 : value; } return array.buffer; } /** * Get the min and max vectors from the given attribute * @param {BufferAttribute} attribute Attribute to find the min/max in range from start to start + count * @param {Integer} start * @param {Integer} count * @return {Object} Object containing the `min` and `max` values (As an array of attribute.itemSize components) */ function getMinMax( attribute, start, count ) { var output = { min: new Array( attribute.itemSize ).fill( Number.POSITIVE_INFINITY ), max: new Array( attribute.itemSize ).fill( Number.NEGATIVE_INFINITY ) }; for ( var i = start; i < start + count; i ++ ) { for ( var a = 0; a < attribute.itemSize; a ++ ) { var value = attribute.array[ i * attribute.itemSize + a ]; output.min[ a ] = Math.min( output.min[ a ], value ); output.max[ a ] = Math.max( output.max[ a ], value ); } } return output; } /** * Checks if image size is POT. * * @param {Image} image The image to be checked. * @returns {Boolean} Returns true if image size is POT. * */ function isPowerOfTwo( image ) { return MathUtils.isPowerOfTwo( image.width ) && MathUtils.isPowerOfTwo( image.height ); } /** * Checks if normal attribute values are normalized. * * @param {BufferAttribute} normal * @returns {Boolean} * */ function isNormalizedNormalAttribute( normal ) { if ( cachedData.attributesNormalized.has( normal ) ) { return false; } var v = new Vector3(); for ( var i = 0, il = normal.count; i < il; i ++ ) { // 0.0005 is from glTF-validator if ( Math.abs( v.fromArray( normal.array, i * 3 ).length() - 1.0 ) > 0.0005 ) return false; } return true; } /** * Creates normalized normal buffer attribute. * * @param {BufferAttribute} normal * @returns {BufferAttribute} * */ function createNormalizedNormalAttribute( normal ) { if ( cachedData.attributesNormalized.has( normal ) ) { return cachedData.attributesNormalized.get( normal ); } var attribute = normal.clone(); var v = new Vector3(); for ( var i = 0, il = attribute.count; i < il; i ++ ) { v.fromArray( attribute.array, i * 3 ); if ( v.x === 0 && v.y === 0 && v.z === 0 ) { // if values can't be normalized set (1, 0, 0) v.setX( 1.0 ); } else { v.normalize(); } v.toArray( attribute.array, i * 3 ); } cachedData.attributesNormalized.set( normal, attribute ); return attribute; } /** * Get the required size + padding for a buffer, rounded to the next 4-byte boundary. * https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#data-alignment * * @param {Integer} bufferSize The size the original buffer. * @returns {Integer} new buffer size with required padding. * */ function getPaddedBufferSize( bufferSize ) { return Math.ceil( bufferSize / 4 ) * 4; } /** * Returns a buffer aligned to 4-byte boundary. * * @param {ArrayBuffer} arrayBuffer Buffer to pad * @param {Integer} paddingByte (Optional) * @returns {ArrayBuffer} The same buffer if it's already aligned to 4-byte boundary or a new buffer */ function getPaddedArrayBuffer( arrayBuffer, paddingByte ) { paddingByte = paddingByte || 0; var paddedLength = getPaddedBufferSize( arrayBuffer.byteLength ); if ( paddedLength !== arrayBuffer.byteLength ) { var array = new Uint8Array( paddedLength ); array.set( new Uint8Array( arrayBuffer ) ); if ( paddingByte !== 0 ) { for ( var i = arrayBuffer.byteLength; i < paddedLength; i ++ ) { array[ i ] = paddingByte; } } return array.buffer; } return arrayBuffer; } /** * Serializes a userData. * * @param {THREE.Object3D|THREE.Material} object * @param {Object} gltfProperty */ function serializeUserData( object, gltfProperty ) { if ( Object.keys( object.userData ).length === 0 ) { return; } try { var json = JSON.parse( JSON.stringify( object.userData ) ); if ( options.includeCustomExtensions && json.gltfExtensions ) { if ( gltfProperty.extensions === undefined ) { gltfProperty.extensions = {}; } for ( var extensionName in json.gltfExtensions ) { gltfProperty.extensions[ extensionName ] = json.gltfExtensions[ extensionName ]; extensionsUsed[ extensionName ] = true; } delete json.gltfExtensions; } if ( Object.keys( json ).length > 0 ) { gltfProperty.extras = json; } } catch ( error ) { console.warn( 'THREE.GLTFExporter: userData of \'' + object.name + '\' ' + 'won\'t be serialized because of JSON.stringify error - ' + error.message ); } } /** * Applies a texture transform, if present, to the map definition. Requires * the KHR_texture_transform extension. */ function applyTextureTransform( mapDef, texture ) { var didTransform = false; var transformDef = {}; if ( texture.offset.x !== 0 || texture.offset.y !== 0 ) { transformDef.offset = texture.offset.toArray(); didTransform = true; } if ( texture.rotation !== 0 ) { transformDef.rotation = texture.rotation; didTransform = true; } if ( texture.repeat.x !== 1 || texture.repeat.y !== 1 ) { transformDef.scale = texture.repeat.toArray(); didTransform = true; } if ( didTransform ) { mapDef.extensions = mapDef.extensions || {}; mapDef.extensions[ 'KHR_texture_transform' ] = transformDef; extensionsUsed[ 'KHR_texture_transform' ] = true; } } /** * Process a buffer to append to the default one. * @param {ArrayBuffer} buffer * @return {Integer} */ function processBuffer( buffer ) { if ( ! outputJSON.buffers ) { outputJSON.buffers = [ { byteLength: 0 } ]; } // All buffers are merged before export. buffers.push( buffer ); return 0; } /** * Process and generate a BufferView * @param {BufferAttribute} attribute * @param {number} componentType * @param {number} start * @param {number} count * @param {number} target (Optional) Target usage of the BufferView * @return {Object} */ function processBufferView( attribute, componentType, start, count, target ) { if ( ! outputJSON.bufferViews ) { outputJSON.bufferViews = []; } // Create a new dataview and dump the attribute's array into it var componentSize; if ( componentType === WEBGL_CONSTANTS.UNSIGNED_BYTE ) { componentSize = 1; } else if ( componentType === WEBGL_CONSTANTS.UNSIGNED_SHORT ) { componentSize = 2; } else { componentSize = 4; } var byteLength = getPaddedBufferSize( count * attribute.itemSize * componentSize ); var dataView = new DataView( new ArrayBuffer( byteLength ) ); var offset = 0; for ( var i = start; i < start + count; i ++ ) { for ( var a = 0; a < attribute.itemSize; a ++ ) { // @TODO Fails on InterleavedBufferAttribute, and could probably be // optimized for normal BufferAttribute. var value = attribute.array[ i * attribute.itemSize + a ]; if ( componentType === WEBGL_CONSTANTS.FLOAT ) { dataView.setFloat32( offset, value, true ); } else if ( componentType === WEBGL_CONSTANTS.UNSIGNED_INT ) { dataView.setUint32( offset, value, true ); } else if ( componentType === WEBGL_CONSTANTS.UNSIGNED_SHORT ) { dataView.setUint16( offset, value, true ); } else if ( componentType === WEBGL_CONSTANTS.UNSIGNED_BYTE ) { dataView.setUint8( offset, value ); } offset += componentSize; } } var gltfBufferView = { buffer: processBuffer( dataView.buffer ), byteOffset: byteOffset, byteLength: byteLength }; if ( target !== undefined ) gltfBufferView.target = target; if ( target === WEBGL_CONSTANTS.ARRAY_BUFFER ) { // Only define byteStride for vertex attributes. gltfBufferView.byteStride = attribute.itemSize * componentSize; } byteOffset += byteLength; outputJSON.bufferViews.push( gltfBufferView ); // @TODO Merge bufferViews where possible. var output = { id: outputJSON.bufferViews.length - 1, byteLength: 0 }; return output; } /** * Process and generate a BufferView from an image Blob. * @param {Blob} blob * @return {Promise} */ function processBufferViewImage( blob ) { if ( ! outputJSON.bufferViews ) { outputJSON.bufferViews = []; } return new Promise( function ( resolve ) { var reader = new window.FileReader(); reader.readAsArrayBuffer( blob ); reader.onloadend = function () { var buffer = getPaddedArrayBuffer( reader.result ); var bufferView = { buffer: processBuffer( buffer ), byteOffset: byteOffset, byteLength: buffer.byteLength }; byteOffset += buffer.byteLength; outputJSON.bufferViews.push( bufferView ); resolve( outputJSON.bufferViews.length - 1 ); }; } ); } /** * Process attribute to generate an accessor * @param {BufferAttribute} attribute Attribute to process * @param {BufferGeometry} geometry (Optional) Geometry used for truncated draw range * @param {Integer} start (Optional) * @param {Integer} count (Optional) * @return {Integer} Index of the processed accessor on the "accessors" array */ function processAccessor( attribute, geometry, start, count ) { var types = { 1: 'SCALAR', 2: 'VEC2', 3: 'VEC3', 4: 'VEC4', 16: 'MAT4' }; var componentType; // Detect the component type of the attribute array (float, uint or ushort) if ( attribute.array.constructor === Float32Array ) { componentType = WEBGL_CONSTANTS.FLOAT; } else if ( attribute.array.constructor === Uint32Array ) { componentType = WEBGL_CONSTANTS.UNSIGNED_INT; } else if ( attribute.array.constructor === Uint16Array ) { componentType = WEBGL_CONSTANTS.UNSIGNED_SHORT; } else if ( attribute.array.constructor === Uint8Array ) { componentType = WEBGL_CONSTANTS.UNSIGNED_BYTE; } else { throw new Error( 'THREE.GLTFExporter: Unsupported bufferAttribute component type.' ); } if ( start === undefined ) start = 0; if ( count === undefined ) count = attribute.count; // @TODO Indexed buffer geometry with drawRange not supported yet if ( options.truncateDrawRange && geometry !== undefined && geometry.index === null ) { var end = start + count; var end2 = geometry.drawRange.count === Infinity ? attribute.count : geometry.drawRange.start + geometry.drawRange.count; start = Math.max( start, geometry.drawRange.start ); count = Math.min( end, end2 ) - start; if ( count < 0 ) count = 0; } // Skip creating an accessor if the attribute doesn't have data to export if ( count === 0 ) { return null; } var minMax = getMinMax( attribute, start, count ); var bufferViewTarget; // If geometry isn't provided, don't infer the target usage of the bufferView. For // animation samplers, target must not be set. if ( geometry !== undefined ) { bufferViewTarget = attribute === geometry.index ? WEBGL_CONSTANTS.ELEMENT_ARRAY_BUFFER : WEBGL_CONSTANTS.ARRAY_BUFFER; } var bufferView = processBufferView( attribute, componentType, start, count, bufferViewTarget ); var gltfAccessor = { bufferView: bufferView.id, byteOffset: bufferView.byteOffset, componentType: componentType, count: count, max: minMax.max, min: minMax.min, type: types[ attribute.itemSize ] }; if ( ! outputJSON.accessors ) { outputJSON.accessors = []; } outputJSON.accessors.push( gltfAccessor ); return outputJSON.accessors.length - 1; } /** * Process image * @param {Image} image to process * @param {Integer} format of the image (e.g. THREE.RGBFormat, RGBAFormat etc) * @param {Boolean} flipY before writing out the image * @return {Integer} Index of the processed texture in the "images" array */ function processImage( image, format, flipY ) { if ( ! cachedData.images.has( image ) ) { cachedData.images.set( image, {} ); } var cachedImages = cachedData.images.get( image ); var mimeType = format === RGBAFormat ? 'image/png' : 'image/jpeg'; var key = mimeType + ":flipY/" + flipY.toString(); if ( cachedImages[ key ] !== undefined ) { return cachedImages[ key ]; } if ( ! outputJSON.images ) { outputJSON.images = []; } var gltfImage = { mimeType: mimeType }; if ( options.embedImages ) { var canvas = cachedCanvas = cachedCanvas || document.createElement( 'canvas' ); canvas.width = Math.min( image.width, options.maxTextureSize ); canvas.height = Math.min( image.height, options.maxTextureSize ); if ( options.forcePowerOfTwoTextures && ! isPowerOfTwo( canvas ) ) { canvas.width = MathUtils.ceilPowerOfTwo( canvas.width ); canvas.height = MathUtils.ceilPowerOfTwo( canvas.height ); } var ctx = canvas.getContext( '2d' ); if ( flipY === true ) { ctx.translate( 0, canvas.height ); ctx.scale( 1, - 1 ); } ctx.drawImage( image, 0, 0, image.width, image.height ); if ( options.binary === true ) { pending.push( new Promise( function ( resolve ) { canvas.toBlob( function ( blob ) { processBufferViewImage( blob ).then( function ( bufferViewIndex ) { gltfImage.bufferView = bufferViewIndex; resolve(); } ); }, mimeType ); } ) ); } else { gltfImage.uri = canvas.toDataURL( mimeType ); } } else { gltfImage.uri = image.src; } outputJSON.images.push( gltfImage ); var index = outputJSON.images.length - 1; cachedImages[ key ] = index; return index; } /** * Process sampler * @param {Texture} map Texture to process * @return {Integer} Index of the processed texture in the "samplers" array */ function processSampler( map ) { if ( ! outputJSON.samplers ) { outputJSON.samplers = []; } var gltfSampler = { magFilter: THREE_TO_WEBGL[ map.magFilter ], minFilter: THREE_TO_WEBGL[ map.minFilter ], wrapS: THREE_TO_WEBGL[ map.wrapS ], wrapT: THREE_TO_WEBGL[ map.wrapT ] }; outputJSON.samplers.push( gltfSampler ); return outputJSON.samplers.length - 1; } /** * Process texture * @param {Texture} map Map to process * @return {Integer} Index of the processed texture in the "textures" array */ function processTexture( map ) { if ( cachedData.textures.has( map ) ) { return cachedData.textures.get( map ); } if ( ! outputJSON.textures ) { outputJSON.textures = []; } var gltfTexture = { sampler: processSampler( map ), source: processImage( map.image, map.format, map.flipY ) }; if ( map.name ) { gltfTexture.name = map.name; } outputJSON.textures.push( gltfTexture ); var index = outputJSON.textures.length - 1; cachedData.textures.set( map, index ); return index; } /** * Process material * @param {THREE.Material} material Material to process * @return {Integer} Index of the processed material in the "materials" array */ function processMaterial( material ) { // blockbench custom material if ( material == Canvas.transparentMaterial ) { material = invisibleMaterial; } if ( cachedData.materials.has( material ) ) { return cachedData.materials.get( material ); } if ( ! outputJSON.materials ) { outputJSON.materials = []; } if ( material.isShaderMaterial && ! material.isGLTFSpecularGlossinessMaterial ) { console.warn( 'GLTFExporter: THREE.ShaderMaterial not supported.' ); return null; } // @QUESTION Should we avoid including any attribute that has the default value? var gltfMaterial = { pbrMetallicRoughness: {} }; if ( material.isMeshBasicMaterial ) { gltfMaterial.extensions = { KHR_materials_unlit: {} }; extensionsUsed[ 'KHR_materials_unlit' ] = true; } else if ( material.isGLTFSpecularGlossinessMaterial ) { gltfMaterial.extensions = { KHR_materials_pbrSpecularGlossiness: {} }; extensionsUsed[ 'KHR_materials_pbrSpecularGlossiness' ] = true; } // pbrMetallicRoughness.baseColorFactor var color = material.color.toArray().concat( [ material.opacity ] ); if ( ! equalArray( color, [ 1, 1, 1, 1 ] ) ) { gltfMaterial.pbrMetallicRoughness.baseColorFactor = color; } if ( material.isMeshStandardMaterial ) { gltfMaterial.pbrMetallicRoughness.metallicFactor = material.metalness; gltfMaterial.pbrMetallicRoughness.roughnessFactor = material.roughness; } else if ( material.isMeshBasicMaterial ) { gltfMaterial.pbrMetallicRoughness.metallicFactor = 0.0; gltfMaterial.pbrMetallicRoughness.roughnessFactor = 0.9; } else { gltfMaterial.pbrMetallicRoughness.metallicFactor = 0; gltfMaterial.pbrMetallicRoughness.roughnessFactor = 1; } // pbrSpecularGlossiness diffuse, specular and glossiness factor if ( material.isGLTFSpecularGlossinessMaterial ) { if ( gltfMaterial.pbrMetallicRoughness.baseColorFactor ) { gltfMaterial.extensions.KHR_materials_pbrSpecularGlossiness.diffuseFactor = gltfMaterial.pbrMetallicRoughness.baseColorFactor; } var specularFactor = [ 1, 1, 1 ]; material.specular.toArray( specularFactor, 0 ); gltfMaterial.extensions.KHR_materials_pbrSpecularGlossiness.specularFactor = specularFactor; gltfMaterial.extensions.KHR_materials_pbrSpecularGlossiness.glossinessFactor = material.glossiness; } // pbrMetallicRoughness.metallicRoughnessTexture if ( material.metalnessMap || material.roughnessMap ) { if ( material.metalnessMap === material.roughnessMap ) { var metalRoughMapDef = { index: processTexture( material.metalnessMap ) }; applyTextureTransform( metalRoughMapDef, material.metalnessMap ); gltfMaterial.pbrMetallicRoughness.metallicRoughnessTexture = metalRoughMapDef; } else { console.warn( 'THREE.GLTFExporter: Ignoring metalnessMap and roughnessMap because they are not the same Texture.' ); } } // pbrMetallicRoughness.baseColorTexture or pbrSpecularGlossiness diffuseTexture if ( material.map ) { var baseColorMapDef = { index: processTexture( material.map ) }; applyTextureTransform( baseColorMapDef, material.map ); if ( material.isGLTFSpecularGlossinessMaterial ) { gltfMaterial.extensions.KHR_materials_pbrSpecularGlossiness.diffuseTexture = baseColorMapDef; } gltfMaterial.pbrMetallicRoughness.baseColorTexture = baseColorMapDef; } // pbrSpecularGlossiness specular map if ( material.isGLTFSpecularGlossinessMaterial && material.specularMap ) { var specularMapDef = { index: processTexture( material.specularMap ) }; applyTextureTransform( specularMapDef, material.specularMap ); gltfMaterial.extensions.KHR_materials_pbrSpecularGlossiness.specularGlossinessTexture = specularMapDef; } if ( material.emissive ) { // emissiveFactor var emissive = material.emissive.clone().multiplyScalar( material.emissiveIntensity ).toArray(); if ( ! equalArray( emissive, [ 0, 0, 0 ] ) ) { gltfMaterial.emissiveFactor = emissive; } // emissiveTexture if ( material.emissiveMap ) { var emissiveMapDef = { index: processTexture( material.emissiveMap ) }; applyTextureTransform( emissiveMapDef, material.emissiveMap ); gltfMaterial.emissiveTexture = emissiveMapDef; } } // normalTexture if ( material.normalMap ) { var normalMapDef = { index: processTexture( material.normalMap ) }; if ( material.normalScale && material.normalScale.x !== - 1 ) { if ( material.normalScale.x !== material.normalScale.y ) { console.warn( 'THREE.GLTFExporter: Normal scale components are different, ignoring Y and exporting X.' ); } normalMapDef.scale = material.normalScale.x; } applyTextureTransform( normalMapDef, material.normalMap ); gltfMaterial.normalTexture = normalMapDef; } // occlusionTexture if ( material.aoMap ) { var occlusionMapDef = { index: processTexture( material.aoMap ), texCoord: 1 }; if ( material.aoMapIntensity !== 1.0 ) { occlusionMapDef.strength = material.aoMapIntensity; } applyTextureTransform( occlusionMapDef, material.aoMap ); gltfMaterial.occlusionTexture = occlusionMapDef; } // alphaMode if ( material.alphaTest > 0.0 ) { gltfMaterial.alphaMode = 'MASK'; gltfMaterial.alphaCutoff = material.alphaTest; } else if ( material.transparent ) { gltfMaterial.alphaMode = 'BLEND'; } // doubleSided if ( material.side === DoubleSide ) { gltfMaterial.doubleSided = true; } if ( material.name !== '' ) { gltfMaterial.name = material.name; } serializeUserData( material, gltfMaterial ); outputJSON.materials.push( gltfMaterial ); var index = outputJSON.materials.length - 1; cachedData.materials.set( material, index ); return index; } /** * Process mesh * @param {THREE.Mesh} mesh Mesh to process * @return {Integer} Index of the processed mesh in the "meshes" array */ function processMesh( mesh ) { var cacheKey = mesh.geometry.uuid + ':' + mesh.material.uuid; if ( cachedData.meshes.has( cacheKey ) ) { return cachedData.meshes.get( cacheKey ); } var geometry = mesh.geometry; if (!geometry.isBufferGeometry && geometry._bufferGeometry) { geometry = geometry._bufferGeometry; } var mode; // Use the correct mode if ( mesh.isLineSegments ) { mode = WEBGL_CONSTANTS.LINES; } else if ( mesh.isLineLoop ) { mode = WEBGL_CONSTANTS.LINE_LOOP; } else if ( mesh.isLine ) { mode = WEBGL_CONSTANTS.LINE_STRIP; } else if ( mesh.isPoints ) { mode = WEBGL_CONSTANTS.POINTS; } else { if ( ! geometry.isBufferGeometry ) { console.warn( 'GLTFExporter: Exporting THREE.Geometry will increase file size. Use BufferGeometry instead.' ); var geometryTemp = new BufferGeometry(); geometryTemp.fromGeometry( geometry ); geometry = geometryTemp; } mode = mesh.material.wireframe ? WEBGL_CONSTANTS.LINES : WEBGL_CONSTANTS.TRIANGLES; } var gltfMesh = {}; var attributes = {}; var primitives = []; var targets = []; // Conversion between attributes names in threejs and gltf spec var nameConversion = { uv: 'TEXCOORD_0', uv2: 'TEXCOORD_1', color: 'COLOR_0', skinWeight: 'WEIGHTS_0', skinIndex: 'JOINTS_0' }; var originalNormal = geometry.getAttribute instanceof Function ? geometry.getAttribute( 'normal' ) : undefined; if ( originalNormal !== undefined && ! isNormalizedNormalAttribute( originalNormal ) && typeof geometry.setAttribute == 'function' ) { console.warn( 'THREE.GLTFExporter: Creating normalized normal attribute from the non-normalized one.' ); geometry.setAttribute( 'normal', createNormalizedNormalAttribute( originalNormal ) ); } // @QUESTION Detect if .vertexColors = THREE.VertexColors? // For every attribute create an accessor var modifiedAttribute = null; for ( var attributeName in geometry.attributes ) { // Ignore morph target attributes, which are exported later. if ( attributeName.substr( 0, 5 ) === 'morph' ) continue; var attribute = geometry.attributes[ attributeName ]; attributeName = nameConversion[ attributeName ] || attributeName.toUpperCase(); if (!options.exportFaceColors && attributeName === 'COLOR_0' ) continue; // Prefix all geometry attributes except the ones specifically // listed in the spec; non-spec attributes are considered custom. var validVertexAttributes = /^(POSITION|NORMAL|TANGENT|TEXCOORD_\d+|COLOR_\d+|JOINTS_\d+|WEIGHTS_\d+)$/; if ( ! validVertexAttributes.test( attributeName ) ) { attributeName = '_' + attributeName; } if ( cachedData.attributes.has( getUID( attribute ) ) ) { attributes[ attributeName ] = cachedData.attributes.get( getUID( attribute ) ); continue; } // JOINTS_0 must be UNSIGNED_BYTE or UNSIGNED_SHORT. modifiedAttribute = null; var array = attribute.array; if ( attributeName === 'JOINTS_0' && ! ( array instanceof Uint16Array ) && ! ( array instanceof Uint8Array ) ) { console.warn( 'GLTFExporter: Attribute "skinIndex" converted to type UNSIGNED_SHORT.' ); modifiedAttribute = new BufferAttribute( new Uint16Array( array ), attribute.itemSize, attribute.normalized ); } if ( options.forcePowerOfTwoTextures && attributeName.substr(0, 8) === 'TEXCOORD' ) { // Blockbench: Modify UV mapping for poweroftwo texture conversion modifiedAttribute = new BufferAttribute( new Float32Array( array ), attribute.itemSize, attribute.normalized ); let isCube = mesh.type == 'cube'; if (!isCube) { var map = mesh.material.map; } modifiedAttribute.array.forEach((v, i) => { if (isCube) { var map = mesh.material[Math.floor(i / 12)].map; } if (map && map.image) { if (i%2 == 0) { modifiedAttribute.array[i] = v * (map.image.width / THREE.Math.ceilPowerOfTwo(map.image.width)); } else { modifiedAttribute.array[i] = 1-(1-v) * (map.image.height / THREE.Math.ceilPowerOfTwo(map.image.height)); } } }) } var accessor = processAccessor( modifiedAttribute || attribute, geometry ); if ( accessor !== null ) { attributes[ attributeName ] = accessor; cachedData.attributes.set( getUID( attribute ), accessor ); } } if ( originalNormal !== undefined && typeof geometry.setAttribute == 'function' ) geometry.setAttribute( 'normal', originalNormal ); // Skip if no exportable attributes found if ( Object.keys( attributes ).length === 0 ) { return null; } // Morph targets if ( mesh.morphTargetInfluences !== undefined && mesh.morphTargetInfluences.length > 0 ) { var weights = []; var targetNames = []; var reverseDictionary = {}; if ( mesh.morphTargetDictionary !== undefined ) { for ( var key in mesh.morphTargetDictionary ) { reverseDictionary[ mesh.morphTargetDictionary[ key ] ] = key; } } for ( var i = 0; i < mesh.morphTargetInfluences.length; ++ i ) { var target = {}; var warned = false; for ( var attributeName in geometry.morphAttributes ) { // glTF 2.0 morph supports only POSITION/NORMAL/TANGENT. // Three.js doesn't support TANGENT yet. if ( attributeName !== 'position' && attributeName !== 'normal' ) { if ( ! warned ) { console.warn( 'GLTFExporter: Only POSITION and NORMAL morph are supported.' ); warned = true; } continue; } var attribute = geometry.morphAttributes[ attributeName ][ i ]; var gltfAttributeName = attributeName.toUpperCase(); // Three.js morph attribute has absolute values while the one of glTF has relative values. // // glTF 2.0 Specification: // https://github.com/KhronosGroup/glTF/tree/master/specification/2.0#morph-targets var baseAttribute = geometry.attributes[ attributeName ]; if ( cachedData.attributes.has( getUID( attribute ) ) ) { target[ gltfAttributeName ] = cachedData.attributes.get( getUID( attribute ) ); continue; } // Clones attribute not to override var relativeAttribute = attribute.clone(); if ( ! geometry.morphTargetsRelative ) { for ( var j = 0, jl = attribute.count; j < jl; j ++ ) { relativeAttribute.setXYZ( j, attribute.getX( j ) - baseAttribute.getX( j ), attribute.getY( j ) - baseAttribute.getY( j ), attribute.getZ( j ) - baseAttribute.getZ( j ) ); } } target[ gltfAttributeName ] = processAccessor( relativeAttribute, geometry ); cachedData.attributes.set( getUID( baseAttribute ), target[ gltfAttributeName ] ); } targets.push( target ); weights.push( mesh.morphTargetInfluences[ i ] ); if ( mesh.morphTargetDictionary !== undefined ) targetNames.push( reverseDictionary[ i ] ); } gltfMesh.weights = weights; if ( targetNames.length > 0 ) { gltfMesh.extras = {}; gltfMesh.extras.targetNames = targetNames; } } var forceIndices = options.forceIndices; var isMultiMaterial = Array.isArray( mesh.material ); if ( isMultiMaterial && geometry.groups.length === 0 ) return null; if ( ! forceIndices && geometry.index === null && isMultiMaterial ) { // temporal workaround. // console.warn( 'THREE.GLTFExporter: Creating index for non-indexed multi-material mesh.' ); forceIndices = true; } var didForceIndices = false; if ( geometry.index === null && forceIndices ) { var indices = []; for ( var i = 0, il = geometry.attributes.position.count; i < il; i ++ ) { indices[ i ] = i; } geometry.setIndex( indices ); didForceIndices = true; } var materials = isMultiMaterial ? mesh.material : [ mesh.material ]; var groups = isMultiMaterial ? geometry.groups : [ { materialIndex: 0, start: undefined, count: undefined } ]; for ( var i = 0, il = groups.length; i < il; i ++ ) { var primitive = { mode: mode, attributes: attributes, }; serializeUserData( geometry, primitive ); if ( targets.length > 0 ) primitive.targets = targets; if ( geometry.index !== null ) { var cacheKey = getUID( geometry.index ); if ( groups[ i ].start !== undefined || groups[ i ].count !== undefined ) { cacheKey += ':' + groups[ i ].start + ':' + groups[ i ].count; } if ( cachedData.attributes.has( cacheKey ) ) { primitive.indices = cachedData.attributes.get( cacheKey ); } else { primitive.indices = processAccessor( geometry.index, geometry, groups[ i ].start, groups[ i ].count ); cachedData.attributes.set( cacheKey, primitive.indices ); } if ( primitive.indices === null ) delete primitive.indices; } var material = processMaterial( materials[ groups[ i ].materialIndex ] ); if ( material !== null ) { primitive.material = material; } primitives.push( primitive ); } if ( didForceIndices ) { geometry.setIndex( null ); } gltfMesh.primitives = primitives; if ( ! outputJSON.meshes ) { outputJSON.meshes = []; } outputJSON.meshes.push( gltfMesh ); var index = outputJSON.meshes.length - 1; cachedData.meshes.set( cacheKey, index ); return index; } /** * Process camera * @param {THREE.Camera} camera Camera to process * @return {Integer} Index of the processed mesh in the "camera" array */ function processCamera( camera ) { if ( ! outputJSON.cameras ) { outputJSON.cameras = []; } var isOrtho = camera.isOrthographicCamera; var gltfCamera = { type: isOrtho ? 'orthographic' : 'perspective' }; if ( isOrtho ) { gltfCamera.orthographic = { xmag: camera.right * 2, ymag: camera.top * 2, zfar: camera.far <= 0 ? 0.001 : camera.far, znear: camera.near < 0 ? 0 : camera.near }; } else { gltfCamera.perspective = { aspectRatio: camera.aspect, yfov: MathUtils.degToRad( camera.fov ), zfar: camera.far <= 0 ? 0.001 : camera.far, znear: camera.near < 0 ? 0 : camera.near }; } if ( camera.name !== '' ) { gltfCamera.name = camera.type; } outputJSON.cameras.push( gltfCamera ); return outputJSON.cameras.length - 1; } /** * Creates glTF animation entry from AnimationClip object. * * Status: * - Only properties listed in PATH_PROPERTIES may be animated. * * @param {THREE.AnimationClip} clip * @param {THREE.Object3D} root * @return {number} */ function processAnimation( clip, root ) { if ( ! outputJSON.animations ) { outputJSON.animations = []; } clip = GLTFExporter.Utils.mergeMorphTargetTracks( clip.clone(), root ); var tracks = clip.tracks; var channels = []; var samplers = []; for ( var i = 0; i < tracks.length; ++ i ) { var track = tracks[ i ]; var trackBinding = PropertyBinding.parseTrackName( track.name ); var trackNode = PropertyBinding.findNode( root, trackBinding.nodeName ); var trackProperty = PATH_PROPERTIES[ trackBinding.propertyName ]; if ( trackBinding.objectName === 'bones' ) { if ( trackNode.isSkinnedMesh === true ) { trackNode = trackNode.skeleton.getBoneByName( trackBinding.objectIndex ); } else { trackNode = undefined; } } if ( ! trackNode || ! trackProperty ) { console.warn( 'THREE.GLTFExporter: Could not export animation track "%s".', track.name ); return null; } var inputItemSize = 1; var outputItemSize = track.values.length / track.times.length; if ( trackProperty === PATH_PROPERTIES.morphTargetInfluences ) { outputItemSize /= trackNode.morphTargetInfluences.length; } var interpolation; // @TODO export CubicInterpolant(InterpolateSmooth) as CUBICSPLINE // Detecting glTF cubic spline interpolant by checking factory method's special property // GLTFCubicSplineInterpolant is a custom interpolant and track doesn't return // valid value from .getInterpolation(). if ( track.createInterpolant.isInterpolantFactoryMethodGLTFCubicSpline === true ) { interpolation = 'CUBICSPLINE'; // itemSize of CUBICSPLINE keyframe is 9 // (VEC3 * 3: inTangent, splineVertex, and outTangent) // but needs to be stored as VEC3 so dividing by 3 here. outputItemSize /= 3; } else if ( track.getInterpolation() === InterpolateDiscrete ) { interpolation = 'STEP'; } else { interpolation = 'LINEAR'; } samplers.push( { input: processAccessor( new BufferAttribute( track.times, inputItemSize ) ), output: processAccessor( new BufferAttribute( track.values, outputItemSize ) ), interpolation: interpolation } ); channels.push( { sampler: samplers.length - 1, target: { node: nodeMap.get( trackNode ), path: trackProperty } } ); } outputJSON.animations.push( { name: clip.name || 'clip_' + outputJSON.animations.length, samplers: samplers, channels: channels } ); return outputJSON.animations.length - 1; } function processSkin( object ) { var node = outputJSON.nodes[ nodeMap.get( object ) ]; var skeleton = object.skeleton; if ( skeleton === undefined ) return null; var rootJoint = object.skeleton.bones[ 0 ]; if ( rootJoint === undefined ) return null; var joints = []; var inverseBindMatrices = new Float32Array( skeleton.bones.length * 16 ); for ( var i = 0; i < skeleton.bones.length; ++ i ) { joints.push( nodeMap.get( skeleton.bones[ i ] ) ); skeleton.boneInverses[ i ].toArray( inverseBindMatrices, i * 16 ); } if ( outputJSON.skins === undefined ) { outputJSON.skins = []; } outputJSON.skins.push( { inverseBindMatrices: processAccessor( new BufferAttribute( inverseBindMatrices, 16 ) ), joints: joints, skeleton: nodeMap.get( rootJoint ) } ); var skinIndex = node.skin = outputJSON.skins.length - 1; return skinIndex; } function processLight( light ) { var lightDef = {}; if ( light.name ) lightDef.name = light.name; lightDef.color = light.color.toArray(); lightDef.intensity = light.intensity; if ( light.isDirectionalLight ) { lightDef.type = 'directional'; } else if ( light.isPointLight ) { lightDef.type = 'point'; if ( light.distance > 0 ) lightDef.range = light.distance; } else if ( light.isSpotLight ) { lightDef.type = 'spot'; if ( light.distance > 0 ) lightDef.range = light.distance; lightDef.spot = {}; lightDef.spot.innerConeAngle = ( light.penumbra - 1.0 ) * light.angle * - 1.0; lightDef.spot.outerConeAngle = light.angle; } if ( light.decay !== undefined && light.decay !== 2 ) { console.warn( 'THREE.GLTFExporter: Light decay may be lost. glTF is physically-based, ' + 'and expects light.decay=2.' ); } if ( light.target && ( light.target.parent !== light || light.target.position.x !== 0 || light.target.position.y !== 0 || light.target.position.z !== - 1 ) ) { console.warn( 'THREE.GLTFExporter: Light direction may be lost. For best results, ' + 'make light.target a child of the light with position 0,0,-1.' ); } var lights = outputJSON.extensions[ 'KHR_lights_punctual' ].lights; lights.push( lightDef ); return lights.length - 1; } /** * Process Object3D node * @param {THREE.Object3D} node Object3D to processNode * @return {Integer} Index of the node in the nodes list */ function processNode( object ) { if (object.no_export) return null; if (OutlinerElement.uuids[object.name] && OutlinerElement.uuids[object.name].export == false) return null; if ( ! outputJSON.nodes ) { outputJSON.nodes = []; } var gltfNode = {}; if ( options.trs ) { var rotation = object.quaternion.toArray(); var position = object.position.toArray(); var scale = object.scale.toArray(); if ( ! equalArray( rotation, [ 0, 0, 0, 1 ] ) ) { gltfNode.rotation = rotation; } if ( ! equalArray( position, [ 0, 0, 0 ] ) ) { gltfNode.translation = position; } if ( ! equalArray( scale, [ 1, 1, 1 ] ) ) { gltfNode.scale = scale; } } else { if ( object.matrixAutoUpdate ) { object.updateMatrix(); } if ( ! equalArray( object.matrix.elements, [ 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1 ] ) ) { gltfNode.matrix = object.matrix.elements; } } // We don't export empty strings name because it represents no-name in Three.js. if ( object.name !== '' ) { gltfNode.name = String( object.name ); } serializeUserData( object, gltfNode ); if ( object.isMesh || object.isLine || object.isPoints ) { var mesh = processMesh( object ); if ( mesh !== null ) { gltfNode.mesh = mesh; } } else if ( object.isCamera ) { gltfNode.camera = processCamera( object ); } else if ( object.isDirectionalLight || object.isPointLight || object.isSpotLight ) { if ( ! extensionsUsed[ 'KHR_lights_punctual' ] ) { outputJSON.extensions = outputJSON.extensions || {}; outputJSON.extensions[ 'KHR_lights_punctual' ] = { lights: [] }; extensionsUsed[ 'KHR_lights_punctual' ] = true; } gltfNode.extensions = gltfNode.extensions || {}; gltfNode.extensions[ 'KHR_lights_punctual' ] = { light: processLight( object ) }; } else if ( object.isLight ) { console.warn( 'THREE.GLTFExporter: Only directional, point, and spot lights are supported.', object ); return null; } if ( object.isSkinnedMesh ) { skins.push( object ); } if ( object.children.length > 0 ) { var children = []; for ( var i = 0, l = object.children.length; i < l; i ++ ) { var child = object.children[ i ]; if ( child.visible || options.onlyVisible === false ) { var node = processNode( child ); if ( node !== null ) { children.push( node ); } } } if ( children.length > 0 ) { gltfNode.children = children; } } outputJSON.nodes.push( gltfNode ); var nodeIndex = outputJSON.nodes.length - 1; nodeMap.set( object, nodeIndex ); return nodeIndex; } /** * Process Scene * @param {Scene} node Scene to process */ function processScene( scene ) { if ( ! outputJSON.scenes ) { outputJSON.scenes = []; outputJSON.scene = 0; } var gltfScene = { nodes: [] }; if ( scene.name !== '' ) { gltfScene.name = scene.name; } if ( scene.userData && Object.keys( scene.userData ).length > 0 ) { gltfScene.extras = serializeUserData( scene ); } outputJSON.scenes.push( gltfScene ); var nodes = []; for ( var i = 0, l = scene.children.length; i < l; i ++ ) { var child = scene.children[ i ]; if ( child.visible || options.onlyVisible === false ) { var node = processNode( child ); if ( node !== null ) { nodes.push( node ); } } } if ( nodes.length > 0 ) { gltfScene.nodes = nodes; } serializeUserData( scene, gltfScene ); } /** * Creates a Scene to hold a list of objects and parse it * @param {Array} objects List of objects to process */ function processObjects( objects ) { var scene = new Scene(); scene.name = 'AuxScene'; for ( var i = 0; i < objects.length; i ++ ) { // We push directly to children instead of calling `add` to prevent // modify the .parent and break its original scene and hierarchy scene.children.push( objects[ i ] ); } processScene( scene ); } function processInput( input ) { input = input instanceof Array ? input : [ input ]; var objectsWithoutScene = []; for ( var i = 0; i < input.length; i ++ ) { if ( input[ i ] instanceof Scene ) { processScene( input[ i ] ); } else { objectsWithoutScene.push( input[ i ] ); } } if ( objectsWithoutScene.length > 0 ) { processObjects( objectsWithoutScene ); } for ( var i = 0; i < skins.length; ++ i ) { processSkin( skins[ i ] ); } for ( var i = 0; i < options.animations.length; ++ i ) { processAnimation( options.animations[ i ], input[ 0 ] ); } } processInput( input ); Promise.all( pending ).then( function () { // Merge buffers. var blob = new Blob( buffers, { type: 'application/octet-stream' } ); // Declare extensions. var extensionsUsedList = Object.keys( extensionsUsed ); if ( extensionsUsedList.length > 0 ) outputJSON.extensionsUsed = extensionsUsedList; if ( outputJSON.buffers && outputJSON.buffers.length > 0 ) { // Update bytelength of the single buffer. outputJSON.buffers[ 0 ].byteLength = blob.size; var reader = new window.FileReader(); if ( options.binary === true ) { // https://github.com/KhronosGroup/glTF/blob/master/specification/2.0/README.md#glb-file-format-specification var GLB_HEADER_BYTES = 12; var GLB_HEADER_MAGIC = 0x46546C67; var GLB_VERSION = 2; var GLB_CHUNK_PREFIX_BYTES = 8; var GLB_CHUNK_TYPE_JSON = 0x4E4F534A; var GLB_CHUNK_TYPE_BIN = 0x004E4942; reader.readAsArrayBuffer( blob ); reader.onloadend = function () { // Binary chunk. var binaryChunk = getPaddedArrayBuffer( reader.result ); var binaryChunkPrefix = new DataView( new ArrayBuffer( GLB_CHUNK_PREFIX_BYTES ) ); binaryChunkPrefix.setUint32( 0, binaryChunk.byteLength, true ); binaryChunkPrefix.setUint32( 4, GLB_CHUNK_TYPE_BIN, true ); // JSON chunk. var jsonChunk = getPaddedArrayBuffer( stringToArrayBuffer( JSON.stringify( outputJSON ) ), 0x20 ); var jsonChunkPrefix = new DataView( new ArrayBuffer( GLB_CHUNK_PREFIX_BYTES ) ); jsonChunkPrefix.setUint32( 0, jsonChunk.byteLength, true ); jsonChunkPrefix.setUint32( 4, GLB_CHUNK_TYPE_JSON, true ); // GLB header. var header = new ArrayBuffer( GLB_HEADER_BYTES ); var headerView = new DataView( header ); headerView.setUint32( 0, GLB_HEADER_MAGIC, true ); headerView.setUint32( 4, GLB_VERSION, true ); var totalByteLength = GLB_HEADER_BYTES + jsonChunkPrefix.byteLength + jsonChunk.byteLength + binaryChunkPrefix.byteLength + binaryChunk.byteLength; headerView.setUint32( 8, totalByteLength, true ); var glbBlob = new Blob( [ header, jsonChunkPrefix, jsonChunk, binaryChunkPrefix, binaryChunk ], { type: 'application/octet-stream' } ); var glbReader = new window.FileReader(); glbReader.readAsArrayBuffer( glbBlob ); glbReader.onloadend = function () { onDone( glbReader.result ); }; }; } else { reader.readAsDataURL( blob ); reader.onloadend = function () { var base64data = reader.result; outputJSON.buffers[ 0 ].uri = base64data; onDone( outputJSON ); }; } } else { onDone( outputJSON ); } } ); } }; GLTFExporter.Utils = { insertKeyframe: function ( track, time ) { var tolerance = 0.001; // 1ms var valueSize = track.getValueSize(); var times = new track.TimeBufferType( track.times.length + 1 ); var values = new track.ValueBufferType( track.values.length + valueSize ); var interpolant = track.createInterpolant( new track.ValueBufferType( valueSize ) ); var index; if ( track.times.length === 0 ) { times[ 0 ] = time; for ( var i = 0; i < valueSize; i ++ ) { values[ i ] = 0; } index = 0; } else if ( time < track.times[ 0 ] ) { if ( Math.abs( track.times[ 0 ] - time ) < tolerance ) return 0; times[ 0 ] = time; times.set( track.times, 1 ); values.set( interpolant.evaluate( time ), 0 ); values.set( track.values, valueSize ); index = 0; } else if ( time > track.times[ track.times.length - 1 ] ) { if ( Math.abs( track.times[ track.times.length - 1 ] - time ) < tolerance ) { return track.times.length - 1; } times[ times.length - 1 ] = time; times.set( track.times, 0 ); values.set( track.values, 0 ); values.set( interpolant.evaluate( time ), track.values.length ); index = times.length - 1; } else { for ( var i = 0; i < track.times.length; i ++ ) { if ( Math.abs( track.times[ i ] - time ) < tolerance ) return i; if ( track.times[ i ] < time && track.times[ i + 1 ] > time ) { times.set( track.times.slice( 0, i + 1 ), 0 ); times[ i + 1 ] = time; times.set( track.times.slice( i + 1 ), i + 2 ); values.set( track.values.slice( 0, ( i + 1 ) * valueSize ), 0 ); values.set( interpolant.evaluate( time ), ( i + 1 ) * valueSize ); values.set( track.values.slice( ( i + 1 ) * valueSize ), ( i + 2 ) * valueSize ); index = i + 1; break; } } } track.times = times; track.values = values; return index; }, mergeMorphTargetTracks: function ( clip, root ) { var tracks = []; var mergedTracks = {}; var sourceTracks = clip.tracks; for ( var i = 0; i < sourceTracks.length; ++ i ) { var sourceTrack = sourceTracks[ i ]; var sourceTrackBinding = PropertyBinding.parseTrackName( sourceTrack.name ); var sourceTrackNode = PropertyBinding.findNode( root, sourceTrackBinding.nodeName ); if ( sourceTrackBinding.propertyName !== 'morphTargetInfluences' || sourceTrackBinding.propertyIndex === undefined ) { // Tracks that don't affect morph targets, or that affect all morph targets together, can be left as-is. tracks.push( sourceTrack ); continue; } if ( sourceTrack.createInterpolant !== sourceTrack.InterpolantFactoryMethodDiscrete && sourceTrack.createInterpolant !== sourceTrack.InterpolantFactoryMethodLinear ) { if ( sourceTrack.createInterpolant.isInterpolantFactoryMethodGLTFCubicSpline ) { // This should never happen, because glTF morph target animations // affect all targets already. throw new Error( 'THREE.GLTFExporter: Cannot merge tracks with glTF CUBICSPLINE interpolation.' ); } console.warn( 'THREE.GLTFExporter: Morph target interpolation mode not yet supported. Using LINEAR instead.' ); sourceTrack = sourceTrack.clone(); sourceTrack.setInterpolation( InterpolateLinear ); } var targetCount = sourceTrackNode.morphTargetInfluences.length; var targetIndex = sourceTrackNode.morphTargetDictionary[ sourceTrackBinding.propertyIndex ]; if ( targetIndex === undefined ) { throw new Error( 'THREE.GLTFExporter: Morph target name not found: ' + sourceTrackBinding.propertyIndex ); } var mergedTrack; // If this is the first time we've seen this object, create a new // track to store merged keyframe data for each morph target. if ( mergedTracks[ sourceTrackNode.uuid ] === undefined ) { mergedTrack = sourceTrack.clone(); var values = new mergedTrack.ValueBufferType( targetCount * mergedTrack.times.length ); for ( var j = 0; j < mergedTrack.times.length; j ++ ) { values[ j * targetCount + targetIndex ] = mergedTrack.values[ j ]; } mergedTrack.name = '.morphTargetInfluences'; mergedTrack.values = values; mergedTracks[ sourceTrackNode.uuid ] = mergedTrack; tracks.push( mergedTrack ); continue; } var sourceInterpolant = sourceTrack.createInterpolant( new sourceTrack.ValueBufferType( 1 ) ); mergedTrack = mergedTracks[ sourceTrackNode.uuid ]; // For every existing keyframe of the merged track, write a (possibly // interpolated) value from the source track. for ( var j = 0; j < mergedTrack.times.length; j ++ ) { mergedTrack.values[ j * targetCount + targetIndex ] = sourceInterpolant.evaluate( mergedTrack.times[ j ] ); } // For every existing keyframe of the source track, write a (possibly // new) keyframe to the merged track. Values from the previous loop may // be written again, but keyframes are de-duplicated. for ( var j = 0; j < sourceTrack.times.length; j ++ ) { var keyframeIndex = this.insertKeyframe( mergedTrack, sourceTrack.times[ j ] ); mergedTrack.values[ keyframeIndex * targetCount + targetIndex ] = sourceTrack.values[ j ]; } } clip.tracks = tracks; return clip; } }; THREE.GLTFExporter = GLTFExporter; })()