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bytev-charts

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基于echarts和JavaScript及ES6封装的一个可以直接调用的图表组件库，内置主题设计，简单快捷，且支持用户自定义配置； npm 安装方式: npm install bytev-charts 若启动提示还需额外install插件,则运行 npm install @babel/runtime-corejs2 即可;

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JavaScript

import _Array$isArray from "@babel/runtime-corejs2/core-js/array/is-array"; import _parseInt from "@babel/runtime-corejs2/core-js/parse-int"; import _Object$assign from "@babel/runtime-corejs2/core-js/object/assign"; import _Object$create from "@babel/runtime-corejs2/core-js/object/create"; import _parseFloat from "@babel/runtime-corejs2/core-js/parse-float"; import "core-js/modules/es.function.name.js"; import "core-js/modules/es.array.splice.js"; import "core-js/modules/es.function.bind.js"; import "core-js/modules/es.array.index-of.js"; import "core-js/modules/es.regexp.exec.js"; import "core-js/modules/es.string.replace.js"; import "core-js/modules/es.string.split.js"; import "core-js/modules/es.string.trim-start.js"; import "core-js/modules/es.string.trim.js"; import "core-js/modules/es.array.concat.js"; import "core-js/modules/es.array.map.js"; console.warn("THREE.OBJLoader: As part of the transition to ES6 Modules, the files in 'examples/js' were deprecated in May 2020 (r117) and will be deleted in December 2020 (r124). You can find more information about developing using ES6 Modules in https://threejs.org/docs/#manual/en/introduction/Installation."); THREE.OBJLoader = function () { // o object_name | g group_name var object_pattern = /^[og]\s*(.+)?/; // mtllib file_reference var material_library_pattern = /^mtllib /; // usemtl material_name var material_use_pattern = /^usemtl /; // usemap map_name var map_use_pattern = /^usemap /; var vA = new THREE.Vector3(); var vB = new THREE.Vector3(); var vC = new THREE.Vector3(); var ab = new THREE.Vector3(); var cb = new THREE.Vector3(); function ParserState() { var state = { objects: [], object: {}, vertices: [], normals: [], colors: [], uvs: [], materials: {}, materialLibraries: [], startObject: function startObject(name, fromDeclaration) { // If the current object (initial from reset) is not from a g/o declaration in the parsed // file. We need to use it for the first parsed g/o to keep things in sync. if (this.object && this.object.fromDeclaration === false) { this.object.name = name; this.object.fromDeclaration = fromDeclaration !== false; return; } var previousMaterial = this.object && typeof this.object.currentMaterial === 'function' ? this.object.currentMaterial() : undefined; if (this.object && typeof this.object._finalize === 'function') { this.object._finalize(true); } this.object = { name: name || '', fromDeclaration: fromDeclaration !== false, geometry: { vertices: [], normals: [], colors: [], uvs: [], hasNormalIndices: false, hasUVIndices: false }, materials: [], smooth: true, startMaterial: function startMaterial(name, libraries) { var previous = this._finalize(false); // New usemtl declaration overwrites an inherited material, except if faces were declared // after the material, then it must be preserved for proper MultiMaterial continuation. if (previous && (previous.inherited || previous.groupCount <= 0)) { this.materials.splice(previous.index, 1); } var material = { index: this.materials.length, name: name || '', mtllib: _Array$isArray(libraries) && libraries.length > 0 ? libraries[libraries.length - 1] : '', smooth: previous !== undefined ? previous.smooth : this.smooth, groupStart: previous !== undefined ? previous.groupEnd : 0, groupEnd: -1, groupCount: -1, inherited: false, clone: function clone(index) { var cloned = { index: typeof index === 'number' ? index : this.index, name: this.name, mtllib: this.mtllib, smooth: this.smooth, groupStart: 0, groupEnd: -1, groupCount: -1, inherited: false }; cloned.clone = this.clone.bind(cloned); return cloned; } }; this.materials.push(material); return material; }, currentMaterial: function currentMaterial() { if (this.materials.length > 0) { return this.materials[this.materials.length - 1]; } return undefined; }, _finalize: function _finalize(end) { var lastMultiMaterial = this.currentMaterial(); if (lastMultiMaterial && lastMultiMaterial.groupEnd === -1) { lastMultiMaterial.groupEnd = this.geometry.vertices.length / 3; lastMultiMaterial.groupCount = lastMultiMaterial.groupEnd - lastMultiMaterial.groupStart; lastMultiMaterial.inherited = false; } // Ignore objects tail materials if no face declarations followed them before a new o/g started. if (end && this.materials.length > 1) { for (var mi = this.materials.length - 1; mi >= 0; mi--) { if (this.materials[mi].groupCount <= 0) { this.materials.splice(mi, 1); } } } // Guarantee at least one empty material, this makes the creation later more straight forward. if (end && this.materials.length === 0) { this.materials.push({ name: '', smooth: this.smooth }); } return lastMultiMaterial; } }; // Inherit previous objects material. // Spec tells us that a declared material must be set to all objects until a new material is declared. // If a usemtl declaration is encountered while this new object is being parsed, it will // overwrite the inherited material. Exception being that there was already face declarations // to the inherited material, then it will be preserved for proper MultiMaterial continuation. if (previousMaterial && previousMaterial.name && typeof previousMaterial.clone === 'function') { var declared = previousMaterial.clone(0); declared.inherited = true; this.object.materials.push(declared); } this.objects.push(this.object); }, finalize: function finalize() { if (this.object && typeof this.object._finalize === 'function') { this.object._finalize(true); } }, parseVertexIndex: function parseVertexIndex(value, len) { var index = _parseInt(value, 10); return (index >= 0 ? index - 1 : index + len / 3) * 3; }, parseNormalIndex: function parseNormalIndex(value, len) { var index = _parseInt(value, 10); return (index >= 0 ? index - 1 : index + len / 3) * 3; }, parseUVIndex: function parseUVIndex(value, len) { var index = _parseInt(value, 10); return (index >= 0 ? index - 1 : index + len / 2) * 2; }, addVertex: function addVertex(a, b, c) { var src = this.vertices; var dst = this.object.geometry.vertices; dst.push(src[a + 0], src[a + 1], src[a + 2]); dst.push(src[b + 0], src[b + 1], src[b + 2]); dst.push(src[c + 0], src[c + 1], src[c + 2]); }, addVertexPoint: function addVertexPoint(a) { var src = this.vertices; var dst = this.object.geometry.vertices; dst.push(src[a + 0], src[a + 1], src[a + 2]); }, addVertexLine: function addVertexLine(a) { var src = this.vertices; var dst = this.object.geometry.vertices; dst.push(src[a + 0], src[a + 1], src[a + 2]); }, addNormal: function addNormal(a, b, c) { var src = this.normals; var dst = this.object.geometry.normals; dst.push(src[a + 0], src[a + 1], src[a + 2]); dst.push(src[b + 0], src[b + 1], src[b + 2]); dst.push(src[c + 0], src[c + 1], src[c + 2]); }, addFaceNormal: function addFaceNormal(a, b, c) { var src = this.vertices; var dst = this.object.geometry.normals; vA.fromArray(src, a); vB.fromArray(src, b); vC.fromArray(src, c); cb.subVectors(vC, vB); ab.subVectors(vA, vB); cb.cross(ab); cb.normalize(); dst.push(cb.x, cb.y, cb.z); dst.push(cb.x, cb.y, cb.z); dst.push(cb.x, cb.y, cb.z); }, addColor: function addColor(a, b, c) { var src = this.colors; var dst = this.object.geometry.colors; if (src[a] !== undefined) dst.push(src[a + 0], src[a + 1], src[a + 2]); if (src[b] !== undefined) dst.push(src[b + 0], src[b + 1], src[b + 2]); if (src[c] !== undefined) dst.push(src[c + 0], src[c + 1], src[c + 2]); }, addUV: function addUV(a, b, c) { var src = this.uvs; var dst = this.object.geometry.uvs; dst.push(src[a + 0], src[a + 1]); dst.push(src[b + 0], src[b + 1]); dst.push(src[c + 0], src[c + 1]); }, addDefaultUV: function addDefaultUV() { var dst = this.object.geometry.uvs; dst.push(0, 0); dst.push(0, 0); dst.push(0, 0); }, addUVLine: function addUVLine(a) { var src = this.uvs; var dst = this.object.geometry.uvs; dst.push(src[a + 0], src[a + 1]); }, addFace: function addFace(a, b, c, ua, ub, uc, na, nb, nc) { var vLen = this.vertices.length; var ia = this.parseVertexIndex(a, vLen); var ib = this.parseVertexIndex(b, vLen); var ic = this.parseVertexIndex(c, vLen); this.addVertex(ia, ib, ic); this.addColor(ia, ib, ic); // normals if (na !== undefined && na !== '') { var nLen = this.normals.length; ia = this.parseNormalIndex(na, nLen); ib = this.parseNormalIndex(nb, nLen); ic = this.parseNormalIndex(nc, nLen); this.addNormal(ia, ib, ic); this.object.geometry.hasNormalIndices = true; } else { this.addFaceNormal(ia, ib, ic); } // uvs if (ua !== undefined && ua !== '') { var uvLen = this.uvs.length; ia = this.parseUVIndex(ua, uvLen); ib = this.parseUVIndex(ub, uvLen); ic = this.parseUVIndex(uc, uvLen); this.addUV(ia, ib, ic); this.object.geometry.hasUVIndices = true; } else { // add placeholder values (for inconsistent face definitions) this.addDefaultUV(); } }, addPointGeometry: function addPointGeometry(vertices) { this.object.geometry.type = 'Points'; var vLen = this.vertices.length; for (var vi = 0, l = vertices.length; vi < l; vi++) { this.addVertexPoint(this.parseVertexIndex(vertices[vi], vLen)); } }, addLineGeometry: function addLineGeometry(vertices, uvs) { this.object.geometry.type = 'Line'; var vLen = this.vertices.length; var uvLen = this.uvs.length; for (var vi = 0, l = vertices.length; vi < l; vi++) { this.addVertexLine(this.parseVertexIndex(vertices[vi], vLen)); } for (var uvi = 0, l = uvs.length; uvi < l; uvi++) { this.addUVLine(this.parseUVIndex(uvs[uvi], uvLen)); } } }; state.startObject('', false); return state; } // function OBJLoader(manager) { THREE.Loader.call(this, manager); this.materials = null; } OBJLoader.prototype = _Object$assign(_Object$create(THREE.Loader.prototype), { constructor: OBJLoader, load: function load(url, onLoad, onProgress, onError) { var scope = this; var loader = new THREE.FileLoader(scope.manager); loader.setPath(this.path); loader.setRequestHeader(this.requestHeader); 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); }, setMaterials: function setMaterials(materials) { this.materials = materials; return this; }, parse: function parse(text) { var state = new ParserState(); if (text.indexOf('\r\n') !== -1) { // This is faster than String.split with regex that splits on both text = text.replace(/\r\n/g, '\n'); } if (text.indexOf('\\\n') !== -1) { // join lines separated by a line continuation character (\) text = text.replace(/\\\n/g, ''); } var lines = text.split('\n'); var line = '', lineFirstChar = ''; var lineLength = 0; var result = []; // Faster to just trim left side of the line. Use if available. var trimLeft = typeof ''.trimLeft === 'function'; for (var i = 0, l = lines.length; i < l; i++) { line = lines[i]; line = trimLeft ? line.trimLeft() : line.trim(); lineLength = line.length; if (lineLength === 0) continue; lineFirstChar = line.charAt(0); // @todo invoke passed in handler if any if (lineFirstChar === '#') continue; if (lineFirstChar === 'v') { var data = line.split(/\s+/); switch (data[0]) { case 'v': state.vertices.push(_parseFloat(data[1]), _parseFloat(data[2]), _parseFloat(data[3])); if (data.length >= 7) { state.colors.push(_parseFloat(data[4]), _parseFloat(data[5]), _parseFloat(data[6])); } else { // if no colors are defined, add placeholders so color and vertex indices match state.colors.push(undefined, undefined, undefined); } break; case 'vn': state.normals.push(_parseFloat(data[1]), _parseFloat(data[2]), _parseFloat(data[3])); break; case 'vt': state.uvs.push(_parseFloat(data[1]), _parseFloat(data[2])); break; } } else if (lineFirstChar === 'f') { var lineData = line.substr(1).trim(); var vertexData = lineData.split(/\s+/); var faceVertices = []; // Parse the face vertex data into an easy to work with format for (var j = 0, jl = vertexData.length; j < jl; j++) { var vertex = vertexData[j]; if (vertex.length > 0) { var vertexParts = vertex.split('/'); faceVertices.push(vertexParts); } } // Draw an edge between the first vertex and all subsequent vertices to form an n-gon var v1 = faceVertices[0]; for (var j = 1, jl = faceVertices.length - 1; j < jl; j++) { var v2 = faceVertices[j]; var v3 = faceVertices[j + 1]; state.addFace(v1[0], v2[0], v3[0], v1[1], v2[1], v3[1], v1[2], v2[2], v3[2]); } } else if (lineFirstChar === 'l') { var lineParts = line.substring(1).trim().split(" "); var lineVertices = [], lineUVs = []; if (line.indexOf("/") === -1) { lineVertices = lineParts; } else { for (var li = 0, llen = lineParts.length; li < llen; li++) { var parts = lineParts[li].split("/"); if (parts[0] !== "") lineVertices.push(parts[0]); if (parts[1] !== "") lineUVs.push(parts[1]); } } state.addLineGeometry(lineVertices, lineUVs); } else if (lineFirstChar === 'p') { var lineData = line.substr(1).trim(); var pointData = lineData.split(" "); state.addPointGeometry(pointData); } else if ((result = object_pattern.exec(line)) !== null) { // o object_name // or // g group_name // WORKAROUND: https://bugs.chromium.org/p/v8/issues/detail?id=2869 // var name = result[ 0 ].substr( 1 ).trim(); var name = (" " + result[0].substr(1).trim()).substr(1); state.startObject(name); } else if (material_use_pattern.test(line)) { // material state.object.startMaterial(line.substring(7).trim(), state.materialLibraries); } else if (material_library_pattern.test(line)) { // mtl file state.materialLibraries.push(line.substring(7).trim()); } else if (map_use_pattern.test(line)) { // the line is parsed but ignored since the loader assumes textures are defined MTL files // (according to https://www.okino.com/conv/imp_wave.htm, 'usemap' is the old-style Wavefront texture reference method) console.warn('THREE.OBJLoader: Rendering identifier "usemap" not supported. Textures must be defined in MTL files.'); } else if (lineFirstChar === 's') { result = line.split(' '); // smooth shading // @todo Handle files that have varying smooth values for a set of faces inside one geometry, // but does not define a usemtl for each face set. // This should be detected and a dummy material created (later MultiMaterial and geometry groups). // This requires some care to not create extra material on each smooth value for "normal" obj files. // where explicit usemtl defines geometry groups. // Example asset: examples/models/obj/cerberus/Cerberus.obj /* * http://paulbourke.net/dataformats/obj/ * or * http://www.cs.utah.edu/~boulos/cs3505/obj_spec.pdf * * From chapter "Grouping" Syntax explanation "s group_number": * "group_number is the smoothing group number. To turn off smoothing groups, use a value of 0 or off. * Polygonal elements use group numbers to put elements in different smoothing groups. For free-form * surfaces, smoothing groups are either turned on or off; there is no difference between values greater * than 0." */ if (result.length > 1) { var value = result[1].trim().toLowerCase(); state.object.smooth = value !== '0' && value !== 'off'; } else { // ZBrush can produce "s" lines #11707 state.object.smooth = true; } var material = state.object.currentMaterial(); if (material) material.smooth = state.object.smooth; } else { // Handle null terminated files without exception if (line === '\0') continue; console.warn('THREE.OBJLoader: Unexpected line: "' + line + '"'); } } state.finalize(); var container = new THREE.Group(); container.materialLibraries = [].concat(state.materialLibraries); for (var i = 0, l = state.objects.length; i < l; i++) { var object = state.objects[i]; var geometry = object.geometry; var materials = object.materials; var isLine = geometry.type === 'Line'; var isPoints = geometry.type === 'Points'; var hasVertexColors = false; // Skip o/g line declarations that did not follow with any faces if (geometry.vertices.length === 0) continue; var buffergeometry = new THREE.BufferGeometry(); buffergeometry.setAttribute('position', new THREE.Float32BufferAttribute(geometry.vertices, 3)); if (geometry.hasNormalIndices === true) { buffergeometry.setAttribute('normal', new THREE.Float32BufferAttribute(geometry.normals, 3)); } if (geometry.colors.length > 0) { hasVertexColors = true; buffergeometry.setAttribute('color', new THREE.Float32BufferAttribute(geometry.colors, 3)); } if (geometry.hasUVIndices === true) { buffergeometry.setAttribute('uv', new THREE.Float32BufferAttribute(geometry.uvs, 2)); } // Create materials var createdMaterials = []; for (var mi = 0, miLen = materials.length; mi < miLen; mi++) { var sourceMaterial = materials[mi]; var materialHash = sourceMaterial.name + '_' + sourceMaterial.smooth + '_' + hasVertexColors; var material = state.materials[materialHash]; if (this.materials !== null) { material = this.materials.create(sourceMaterial.name); // mtl etc. loaders probably can't create line materials correctly, copy properties to a line material. if (isLine && material && !(material instanceof THREE.LineBasicMaterial)) { var materialLine = new THREE.LineBasicMaterial(); THREE.Material.prototype.copy.call(materialLine, material); materialLine.color.copy(material.color); material = materialLine; } else if (isPoints && material && !(material instanceof THREE.PointsMaterial)) { var materialPoints = new THREE.PointsMaterial({ size: 10, sizeAttenuation: false }); THREE.Material.prototype.copy.call(materialPoints, material); materialPoints.color.copy(material.color); materialPoints.map = material.map; material = materialPoints; } } if (material === undefined) { if (isLine) { material = new THREE.LineBasicMaterial(); } else if (isPoints) { material = new THREE.PointsMaterial({ size: 1, sizeAttenuation: false }); } else { material = new THREE.MeshPhongMaterial(); } material.name = sourceMaterial.name; material.flatShading = sourceMaterial.smooth ? false : true; material.vertexColors = hasVertexColors; state.materials[materialHash] = material; } createdMaterials.push(material); } // Create mesh var mesh; if (createdMaterials.length > 1) { for (var mi = 0, miLen = materials.length; mi < miLen; mi++) { var sourceMaterial = materials[mi]; buffergeometry.addGroup(sourceMaterial.groupStart, sourceMaterial.groupCount, mi); } if (isLine) { mesh = new THREE.LineSegments(buffergeometry, createdMaterials); } else if (isPoints) { mesh = new THREE.Points(buffergeometry, createdMaterials); } else { mesh = new THREE.Mesh(buffergeometry, createdMaterials); } } else { if (isLine) { mesh = new THREE.LineSegments(buffergeometry, createdMaterials[0]); } else if (isPoints) { mesh = new THREE.Points(buffergeometry, createdMaterials[0]); } else { mesh = new THREE.Mesh(buffergeometry, createdMaterials[0]); } } mesh.name = object.name; container.add(mesh); } return container; } }); return OBJLoader; }();