import { BufferGeometry, Color, FileLoader, Float32BufferAttribute, Group, Loader, LoaderUtils, Mesh, MeshPhongMaterial } from 'three'; import * as fflate from '../libs/fflate.module.js'; /** * Description: Early release of an AMF Loader following the pattern of the * example loaders in the three.js project. * * More information about the AMF format: http://amf.wikispaces.com * * Usage: * const loader = new AMFLoader(); * loader.load('/path/to/project.amf', function(objecttree) { * scene.add(objecttree); * }); * * Materials now supported, material colors supported * Zip support, requires fflate * No constellation support (yet)! * */ class AMFLoader extends Loader { constructor( manager ) { super( manager ); } load( url, onLoad, onProgress, onError ) { const scope = this; const loader = new FileLoader( scope.manager ); loader.setPath( scope.path ); loader.setResponseType( 'arraybuffer' ); loader.setRequestHeader( scope.requestHeader ); loader.setWithCredentials( scope.withCredentials ); loader.load( url, function ( text ) { try { onLoad( scope.parse( text ) ); } catch ( e ) { if ( onError ) { onError( e ); } else { console.error( e ); } scope.manager.itemError( url ); } }, onProgress, onError ); } parse( data ) { function loadDocument( data ) { let view = new DataView( data ); const magic = String.fromCharCode( view.getUint8( 0 ), view.getUint8( 1 ) ); if ( magic === 'PK' ) { let zip = null; let file = null; console.log( 'THREE.AMFLoader: Loading Zip' ); try { zip = fflate.unzipSync( new Uint8Array( data ) ); // eslint-disable-line no-undef } catch ( e ) { if ( e instanceof ReferenceError ) { console.log( 'THREE.AMFLoader: fflate missing and file is compressed.' ); return null; } } for ( file in zip ) { if ( file.toLowerCase().substr( - 4 ) === '.amf' ) { break; } } console.log( 'THREE.AMFLoader: Trying to load file asset: ' + file ); view = new DataView( zip[ file ].buffer ); } const fileText = LoaderUtils.decodeText( view ); const xmlData = new DOMParser().parseFromString( fileText, 'application/xml' ); if ( xmlData.documentElement.nodeName.toLowerCase() !== 'amf' ) { console.log( 'THREE.AMFLoader: Error loading AMF - no AMF document found.' ); return null; } return xmlData; } function loadDocumentScale( node ) { let scale = 1.0; let unit = 'millimeter'; if ( node.documentElement.attributes.unit !== undefined ) { unit = node.documentElement.attributes.unit.value.toLowerCase(); } const scaleUnits = { millimeter: 1.0, inch: 25.4, feet: 304.8, meter: 1000.0, micron: 0.001 }; if ( scaleUnits[ unit ] !== undefined ) { scale = scaleUnits[ unit ]; } console.log( 'THREE.AMFLoader: Unit scale: ' + scale ); return scale; } function loadMaterials( node ) { let matName = 'AMF Material'; const matId = node.attributes.id.textContent; let color = { r: 1.0, g: 1.0, b: 1.0, a: 1.0 }; let loadedMaterial = null; for ( let i = 0; i < node.childNodes.length; i ++ ) { const matChildEl = node.childNodes[ i ]; if ( matChildEl.nodeName === 'metadata' && matChildEl.attributes.type !== undefined ) { if ( matChildEl.attributes.type.value === 'name' ) { matName = matChildEl.textContent; } } else if ( matChildEl.nodeName === 'color' ) { color = loadColor( matChildEl ); } } loadedMaterial = new MeshPhongMaterial( { flatShading: true, color: new Color( color.r, color.g, color.b ), name: matName } ); if ( color.a !== 1.0 ) { loadedMaterial.transparent = true; loadedMaterial.opacity = color.a; } return { id: matId, material: loadedMaterial }; } function loadColor( node ) { const color = { r: 1.0, g: 1.0, b: 1.0, a: 1.0 }; for ( let i = 0; i < node.childNodes.length; i ++ ) { const matColor = node.childNodes[ i ]; if ( matColor.nodeName === 'r' ) { color.r = matColor.textContent; } else if ( matColor.nodeName === 'g' ) { color.g = matColor.textContent; } else if ( matColor.nodeName === 'b' ) { color.b = matColor.textContent; } else if ( matColor.nodeName === 'a' ) { color.a = matColor.textContent; } } return color; } function loadMeshVolume( node ) { const volume = { name: '', triangles: [], materialid: null }; let currVolumeNode = node.firstElementChild; if ( node.attributes.materialid !== undefined ) { volume.materialId = node.attributes.materialid.nodeValue; } while ( currVolumeNode ) { if ( currVolumeNode.nodeName === 'metadata' ) { if ( currVolumeNode.attributes.type !== undefined ) { if ( currVolumeNode.attributes.type.value === 'name' ) { volume.name = currVolumeNode.textContent; } } } else if ( currVolumeNode.nodeName === 'triangle' ) { const v1 = currVolumeNode.getElementsByTagName( 'v1' )[ 0 ].textContent; const v2 = currVolumeNode.getElementsByTagName( 'v2' )[ 0 ].textContent; const v3 = currVolumeNode.getElementsByTagName( 'v3' )[ 0 ].textContent; volume.triangles.push( v1, v2, v3 ); } currVolumeNode = currVolumeNode.nextElementSibling; } return volume; } function loadMeshVertices( node ) { const vertArray = []; const normalArray = []; let currVerticesNode = node.firstElementChild; while ( currVerticesNode ) { if ( currVerticesNode.nodeName === 'vertex' ) { let vNode = currVerticesNode.firstElementChild; while ( vNode ) { if ( vNode.nodeName === 'coordinates' ) { const x = vNode.getElementsByTagName( 'x' )[ 0 ].textContent; const y = vNode.getElementsByTagName( 'y' )[ 0 ].textContent; const z = vNode.getElementsByTagName( 'z' )[ 0 ].textContent; vertArray.push( x, y, z ); } else if ( vNode.nodeName === 'normal' ) { const nx = vNode.getElementsByTagName( 'nx' )[ 0 ].textContent; const ny = vNode.getElementsByTagName( 'ny' )[ 0 ].textContent; const nz = vNode.getElementsByTagName( 'nz' )[ 0 ].textContent; normalArray.push( nx, ny, nz ); } vNode = vNode.nextElementSibling; } } currVerticesNode = currVerticesNode.nextElementSibling; } return { 'vertices': vertArray, 'normals': normalArray }; } function loadObject( node ) { const objId = node.attributes.id.textContent; const loadedObject = { name: 'amfobject', meshes: [] }; let currColor = null; let currObjNode = node.firstElementChild; while ( currObjNode ) { if ( currObjNode.nodeName === 'metadata' ) { if ( currObjNode.attributes.type !== undefined ) { if ( currObjNode.attributes.type.value === 'name' ) { loadedObject.name = currObjNode.textContent; } } } else if ( currObjNode.nodeName === 'color' ) { currColor = loadColor( currObjNode ); } else if ( currObjNode.nodeName === 'mesh' ) { let currMeshNode = currObjNode.firstElementChild; const mesh = { vertices: [], normals: [], volumes: [], color: currColor }; while ( currMeshNode ) { if ( currMeshNode.nodeName === 'vertices' ) { const loadedVertices = loadMeshVertices( currMeshNode ); mesh.normals = mesh.normals.concat( loadedVertices.normals ); mesh.vertices = mesh.vertices.concat( loadedVertices.vertices ); } else if ( currMeshNode.nodeName === 'volume' ) { mesh.volumes.push( loadMeshVolume( currMeshNode ) ); } currMeshNode = currMeshNode.nextElementSibling; } loadedObject.meshes.push( mesh ); } currObjNode = currObjNode.nextElementSibling; } return { 'id': objId, 'obj': loadedObject }; } const xmlData = loadDocument( data ); let amfName = ''; let amfAuthor = ''; const amfScale = loadDocumentScale( xmlData ); const amfMaterials = {}; const amfObjects = {}; const childNodes = xmlData.documentElement.childNodes; let i, j; for ( i = 0; i < childNodes.length; i ++ ) { const child = childNodes[ i ]; if ( child.nodeName === 'metadata' ) { if ( child.attributes.type !== undefined ) { if ( child.attributes.type.value === 'name' ) { amfName = child.textContent; } else if ( child.attributes.type.value === 'author' ) { amfAuthor = child.textContent; } } } else if ( child.nodeName === 'material' ) { const loadedMaterial = loadMaterials( child ); amfMaterials[ loadedMaterial.id ] = loadedMaterial.material; } else if ( child.nodeName === 'object' ) { const loadedObject = loadObject( child ); amfObjects[ loadedObject.id ] = loadedObject.obj; } } const sceneObject = new Group(); const defaultMaterial = new MeshPhongMaterial( { color: 0xaaaaff, flatShading: true } ); sceneObject.name = amfName; sceneObject.userData.author = amfAuthor; sceneObject.userData.loader = 'AMF'; for ( const id in amfObjects ) { const part = amfObjects[ id ]; const meshes = part.meshes; const newObject = new Group(); newObject.name = part.name || ''; for ( i = 0; i < meshes.length; i ++ ) { let objDefaultMaterial = defaultMaterial; const mesh = meshes[ i ]; const vertices = new Float32BufferAttribute( mesh.vertices, 3 ); let normals = null; if ( mesh.normals.length ) { normals = new Float32BufferAttribute( mesh.normals, 3 ); } if ( mesh.color ) { const color = mesh.color; objDefaultMaterial = defaultMaterial.clone(); objDefaultMaterial.color = new Color( color.r, color.g, color.b ); if ( color.a !== 1.0 ) { objDefaultMaterial.transparent = true; objDefaultMaterial.opacity = color.a; } } const volumes = mesh.volumes; for ( j = 0; j < volumes.length; j ++ ) { const volume = volumes[ j ]; const newGeometry = new BufferGeometry(); let material = objDefaultMaterial; newGeometry.setIndex( volume.triangles ); newGeometry.setAttribute( 'position', vertices.clone() ); if ( normals ) { newGeometry.setAttribute( 'normal', normals.clone() ); } if ( amfMaterials[ volume.materialId ] !== undefined ) { material = amfMaterials[ volume.materialId ]; } newGeometry.scale( amfScale, amfScale, amfScale ); newObject.add( new Mesh( newGeometry, material.clone() ) ); } } sceneObject.add( newObject ); } return sceneObject; } } export { AMFLoader };