Doodle3D-Slicer/three.js-master/examples/js/loaders/STLLoader.js
2017-06-22 13:21:07 +02:00

434 lines
11 KiB
JavaScript
Executable File

/**
* @author aleeper / http://adamleeper.com/
* @author mrdoob / http://mrdoob.com/
* @author gero3 / https://github.com/gero3
*
* Description: A THREE loader for STL ASCII files, as created by Solidworks and other CAD programs.
*
* Supports both binary and ASCII encoded files, with automatic detection of type.
*
* Limitations:
* Binary decoding supports "Magics" color format (http://en.wikipedia.org/wiki/STL_(file_format)#Color_in_binary_STL).
* There is perhaps some question as to how valid it is to always assume little-endian-ness.
* ASCII decoding assumes file is UTF-8. Seems to work for the examples...
*
* Usage:
* var loader = new THREE.STLLoader();
* loader.load( './models/stl/slotted_disk.stl', function ( geometry ) {
* scene.add( new THREE.Mesh( geometry ) );
* });
*
* For binary STLs geometry might contain colors for vertices. To use it:
* // use the same code to load STL as above
* if (geometry.hasColors) {
* material = new THREE.MeshPhongMaterial({ opacity: geometry.alpha, vertexColors: THREE.VertexColors });
* } else { .... }
* var mesh = new THREE.Mesh( geometry, material );
*/
THREE.STLLoader = function ( manager ) {
this.manager = ( manager !== undefined ) ? manager : THREE.DefaultLoadingManager;
};
THREE.STLLoader.prototype = {
constructor: THREE.STLLoader,
load: function ( url, onLoad, onProgress, onError ) {
var scope = this;
var loader = new THREE.XHRLoader( scope.manager );
loader.setCrossOrigin( this.crossOrigin );
loader.setResponseType('arraybuffer');
loader.load( url, function ( text ) {
onLoad( scope.parse( text ) );
}, onProgress, onError );
},
parse: function ( data ) {
var isBinary = function () {
var expect, face_size, n_faces, reader;
reader = new DataView( binData );
face_size = (32 / 8 * 3) + ((32 / 8 * 3) * 3) + (16 / 8);
n_faces = reader.getUint32(80, true);
expect = 80 + (32 / 8) + (n_faces * face_size);
if ( expect === reader.byteLength ) {
return true;
}
// some binary files will have different size from expected,
// checking characters higher than ASCII to confirm is binary
var fileLength = reader.byteLength;
for ( var index = 0; index < fileLength; index ++ ) {
if ( reader.getUint8(index, false) > 127 ) {
return true;
}
}
return false;
};
var binData = this.ensureBinary( data );
return isBinary()
? this.parseBinary( binData )
: this.parseASCII( this.ensureString( data ) );
},
parseBinary: function ( data ) {
var reader = new DataView( data );
var faces = reader.getUint32( 80, true );
var r, g, b, hasColors = false, colors;
var defaultR, defaultG, defaultB, alpha;
// process STL header
// check for default color in header ("COLOR=rgba" sequence).
for ( var index = 0; index < 80 - 10; index ++ ) {
if ((reader.getUint32(index, false) == 0x434F4C4F /*COLO*/) &&
(reader.getUint8(index + 4) == 0x52 /*'R'*/) &&
(reader.getUint8(index + 5) == 0x3D /*'='*/)) {
hasColors = true;
colors = new Float32Array( faces * 3 * 3);
defaultR = reader.getUint8(index + 6) / 255;
defaultG = reader.getUint8(index + 7) / 255;
defaultB = reader.getUint8(index + 8) / 255;
alpha = reader.getUint8(index + 9) / 255;
}
}
var dataOffset = 84;
var faceLength = 12 * 4 + 2;
var offset = 0;
var geometry = new THREE.BufferGeometry();
var vertices = new Float32Array( faces * 3 * 3 );
var normals = new Float32Array( faces * 3 * 3 );
for ( var face = 0; face < faces; face ++ ) {
var start = dataOffset + face * faceLength;
var normalX = reader.getFloat32(start, true);
var normalY = reader.getFloat32(start + 4, true);
var normalZ = reader.getFloat32(start + 8, true);
if (hasColors) {
var packedColor = reader.getUint16(start + 48, true);
if ((packedColor & 0x8000) === 0) { // facet has its own unique color
r = (packedColor & 0x1F) / 31;
g = ((packedColor >> 5) & 0x1F) / 31;
b = ((packedColor >> 10) & 0x1F) / 31;
} else {
r = defaultR;
g = defaultG;
b = defaultB;
}
}
for ( var i = 1; i <= 3; i ++ ) {
var vertexstart = start + i * 12;
vertices[ offset ] = reader.getFloat32( vertexstart, true );
vertices[ offset + 1 ] = reader.getFloat32( vertexstart + 4, true );
vertices[ offset + 2 ] = reader.getFloat32( vertexstart + 8, true );
normals[ offset ] = normalX;
normals[ offset + 1 ] = normalY;
normals[ offset + 2 ] = normalZ;
if (hasColors) {
colors[ offset ] = r;
colors[ offset + 1 ] = g;
colors[ offset + 2 ] = b;
}
offset += 3;
}
}
geometry.addAttribute( 'position', new THREE.BufferAttribute( vertices, 3 ) );
geometry.addAttribute( 'normal', new THREE.BufferAttribute( normals, 3 ) );
if (hasColors) {
geometry.addAttribute( 'color', new THREE.BufferAttribute( colors, 3 ) );
geometry.hasColors = true;
geometry.alpha = alpha;
}
return geometry;
},
parseASCII: function ( data ) {
var geometry, length, normal, patternFace, patternNormal, patternVertex, result, text;
geometry = new THREE.Geometry();
patternFace = /facet([\s\S]*?)endfacet/g;
while ( ( result = patternFace.exec( data ) ) !== null ) {
text = result[0];
patternNormal = /normal[\s]+([\-+]?[0-9]+\.?[0-9]*([eE][\-+]?[0-9]+)?)+[\s]+([\-+]?[0-9]*\.?[0-9]+([eE][\-+]?[0-9]+)?)+[\s]+([\-+]?[0-9]*\.?[0-9]+([eE][\-+]?[0-9]+)?)+/g;
while ( ( result = patternNormal.exec( text ) ) !== null ) {
normal = new THREE.Vector3( parseFloat( result[ 1 ] ), parseFloat( result[ 3 ] ), parseFloat( result[ 5 ] ) );
}
patternVertex = /vertex[\s]+([\-+]?[0-9]+\.?[0-9]*([eE][\-+]?[0-9]+)?)+[\s]+([\-+]?[0-9]*\.?[0-9]+([eE][\-+]?[0-9]+)?)+[\s]+([\-+]?[0-9]*\.?[0-9]+([eE][\-+]?[0-9]+)?)+/g;
while ( ( result = patternVertex.exec( text ) ) !== null ) {
geometry.vertices.push( new THREE.Vector3( parseFloat( result[ 1 ] ), parseFloat( result[ 3 ] ), parseFloat( result[ 5 ] ) ) );
}
length = geometry.vertices.length;
geometry.faces.push( new THREE.Face3( length - 3, length - 2, length - 1, normal ) );
}
geometry.computeBoundingBox();
geometry.computeBoundingSphere();
return geometry;
},
ensureString: function ( buf ) {
if (typeof buf !== "string") {
var array_buffer = new Uint8Array(buf);
var str = '';
for (var i = 0; i < buf.byteLength; i ++) {
str += String.fromCharCode(array_buffer[i]); // implicitly assumes little-endian
}
return str;
} else {
return buf;
}
},
ensureBinary: function ( buf ) {
if (typeof buf === "string") {
var array_buffer = new Uint8Array(buf.length);
for (var i = 0; i < buf.length; i ++) {
array_buffer[i] = buf.charCodeAt(i) & 0xff; // implicitly assumes little-endian
}
return array_buffer.buffer || array_buffer;
} else {
return buf;
}
}
};
if ( typeof DataView === 'undefined') {
DataView = function(buffer, byteOffset, byteLength) {
this.buffer = buffer;
this.byteOffset = byteOffset || 0;
this.byteLength = byteLength || buffer.byteLength || buffer.length;
this._isString = typeof buffer === "string";
}
DataView.prototype = {
_getCharCodes:function(buffer,start,length) {
start = start || 0;
length = length || buffer.length;
var end = start + length;
var codes = [];
for (var i = start; i < end; i ++) {
codes.push(buffer.charCodeAt(i) & 0xff);
}
return codes;
},
_getBytes: function (length, byteOffset, littleEndian) {
var result;
// Handle the lack of endianness
if (littleEndian === undefined) {
littleEndian = this._littleEndian;
}
// Handle the lack of byteOffset
if (byteOffset === undefined) {
byteOffset = this.byteOffset;
} else {
byteOffset = this.byteOffset + byteOffset;
}
if (length === undefined) {
length = this.byteLength - byteOffset;
}
// Error Checking
if (typeof byteOffset !== 'number') {
throw new TypeError('DataView byteOffset is not a number');
}
if (length < 0 || byteOffset + length > this.byteLength) {
throw new Error('DataView length or (byteOffset+length) value is out of bounds');
}
if (this.isString) {
result = this._getCharCodes(this.buffer, byteOffset, byteOffset + length);
} else {
result = this.buffer.slice(byteOffset, byteOffset + length);
}
if (!littleEndian && length > 1) {
if (!(result instanceof Array)) {
result = Array.prototype.slice.call(result);
}
result.reverse();
}
return result;
},
// Compatibility functions on a String Buffer
getFloat64: function (byteOffset, littleEndian) {
var b = this._getBytes(8, byteOffset, littleEndian),
sign = 1 - (2 * (b[7] >> 7)),
exponent = ((((b[7] << 1) & 0xff) << 3) | (b[6] >> 4)) - ((1 << 10) - 1),
// Binary operators such as | and << operate on 32 bit values, using + and Math.pow(2) instead
mantissa = ((b[6] & 0x0f) * Math.pow(2, 48)) + (b[5] * Math.pow(2, 40)) + (b[4] * Math.pow(2, 32)) +
(b[3] * Math.pow(2, 24)) + (b[2] * Math.pow(2, 16)) + (b[1] * Math.pow(2, 8)) + b[0];
if (exponent === 1024) {
if (mantissa !== 0) {
return NaN;
} else {
return sign * Infinity;
}
}
if (exponent === -1023) { // Denormalized
return sign * mantissa * Math.pow(2, -1022 - 52);
}
return sign * (1 + mantissa * Math.pow(2, -52)) * Math.pow(2, exponent);
},
getFloat32: function (byteOffset, littleEndian) {
var b = this._getBytes(4, byteOffset, littleEndian),
sign = 1 - (2 * (b[3] >> 7)),
exponent = (((b[3] << 1) & 0xff) | (b[2] >> 7)) - 127,
mantissa = ((b[2] & 0x7f) << 16) | (b[1] << 8) | b[0];
if (exponent === 128) {
if (mantissa !== 0) {
return NaN;
} else {
return sign * Infinity;
}
}
if (exponent === -127) { // Denormalized
return sign * mantissa * Math.pow(2, -126 - 23);
}
return sign * (1 + mantissa * Math.pow(2, -23)) * Math.pow(2, exponent);
},
getInt32: function (byteOffset, littleEndian) {
var b = this._getBytes(4, byteOffset, littleEndian);
return (b[3] << 24) | (b[2] << 16) | (b[1] << 8) | b[0];
},
getUint32: function (byteOffset, littleEndian) {
return this.getInt32(byteOffset, littleEndian) >>> 0;
},
getInt16: function (byteOffset, littleEndian) {
return (this.getUint16(byteOffset, littleEndian) << 16) >> 16;
},
getUint16: function (byteOffset, littleEndian) {
var b = this._getBytes(2, byteOffset, littleEndian);
return (b[1] << 8) | b[0];
},
getInt8: function (byteOffset) {
return (this.getUint8(byteOffset) << 24) >> 24;
},
getUint8: function (byteOffset) {
return this._getBytes(1, byteOffset)[0];
}
};
}