455 lines
21 KiB
JavaScript
455 lines
21 KiB
JavaScript
/**
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* Cesium - https://github.com/AnalyticalGraphicsInc/cesium
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*
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* Copyright 2011-2017 Cesium Contributors
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*
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* Columbus View (Pat. Pend.)
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*
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* Portions licensed separately.
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* See https://github.com/AnalyticalGraphicsInc/cesium/blob/master/LICENSE.md for full licensing details.
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*/
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define(['exports', './when-8d13db60', './Check-70bec281', './Math-61ede240', './Cartographic-fe4be337', './Cartesian2-85064f09', './WebGLConstants-4c11ee5f', './ComponentDatatype-5862616f', './GeometryAttribute-91704ebb', './PrimitiveType-97893bc7', './EllipsoidRhumbLine-f161e674', './earcut-2.2.1-b404d9e6'], function (exports, when, Check, _Math, Cartographic, Cartesian2, WebGLConstants, ComponentDatatype, GeometryAttribute, PrimitiveType, EllipsoidRhumbLine, earcut2_2_1) { 'use strict';
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/**
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* Winding order defines the order of vertices for a triangle to be considered front-facing.
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*
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* @exports WindingOrder
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*/
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var WindingOrder = {
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/**
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* Vertices are in clockwise order.
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*
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* @type {Number}
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* @constant
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*/
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CLOCKWISE : WebGLConstants.WebGLConstants.CW,
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/**
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* Vertices are in counter-clockwise order.
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*
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* @type {Number}
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* @constant
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*/
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COUNTER_CLOCKWISE : WebGLConstants.WebGLConstants.CCW,
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/**
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* @private
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*/
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validate : function(windingOrder) {
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return windingOrder === WindingOrder.CLOCKWISE ||
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windingOrder === WindingOrder.COUNTER_CLOCKWISE;
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}
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};
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var WindingOrder$1 = Object.freeze(WindingOrder);
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var scaleToGeodeticHeightN = new Cartographic.Cartesian3();
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var scaleToGeodeticHeightP = new Cartographic.Cartesian3();
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/**
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* @private
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*/
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var PolygonPipeline = {};
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/**
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* @exception {DeveloperError} At least three positions are required.
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*/
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PolygonPipeline.computeArea2D = function(positions) {
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//>>includeStart('debug', pragmas.debug);
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Check.Check.defined('positions', positions);
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Check.Check.typeOf.number.greaterThanOrEquals('positions.length', positions.length, 3);
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//>>includeEnd('debug');
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var length = positions.length;
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var area = 0.0;
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for ( var i0 = length - 1, i1 = 0; i1 < length; i0 = i1++) {
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var v0 = positions[i0];
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var v1 = positions[i1];
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area += (v0.x * v1.y) - (v1.x * v0.y);
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}
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return area * 0.5;
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};
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/**
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* @returns {WindingOrder} The winding order.
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*
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* @exception {DeveloperError} At least three positions are required.
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*/
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PolygonPipeline.computeWindingOrder2D = function(positions) {
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var area = PolygonPipeline.computeArea2D(positions);
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return (area > 0.0) ? WindingOrder$1.COUNTER_CLOCKWISE : WindingOrder$1.CLOCKWISE;
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};
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/**
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* Triangulate a polygon.
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*
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* @param {Cartesian2[]} positions Cartesian2 array containing the vertices of the polygon
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* @param {Number[]} [holes] An array of the staring indices of the holes.
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* @returns {Number[]} Index array representing triangles that fill the polygon
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*/
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PolygonPipeline.triangulate = function(positions, holes) {
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//>>includeStart('debug', pragmas.debug);
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Check.Check.defined('positions', positions);
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//>>includeEnd('debug');
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var flattenedPositions = Cartesian2.Cartesian2.packArray(positions);
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return earcut2_2_1.earcut(flattenedPositions, holes, 2);
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};
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var subdivisionV0Scratch = new Cartographic.Cartesian3();
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var subdivisionV1Scratch = new Cartographic.Cartesian3();
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var subdivisionV2Scratch = new Cartographic.Cartesian3();
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var subdivisionS0Scratch = new Cartographic.Cartesian3();
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var subdivisionS1Scratch = new Cartographic.Cartesian3();
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var subdivisionS2Scratch = new Cartographic.Cartesian3();
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var subdivisionMidScratch = new Cartographic.Cartesian3();
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/**
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* Subdivides positions and raises points to the surface of the ellipsoid.
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*
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* @param {Ellipsoid} ellipsoid The ellipsoid the polygon in on.
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* @param {Cartesian3[]} positions An array of {@link Cartesian3} positions of the polygon.
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* @param {Number[]} indices An array of indices that determines the triangles in the polygon.
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* @param {Number} [granularity=CesiumMath.RADIANS_PER_DEGREE] The distance, in radians, between each latitude and longitude. Determines the number of positions in the buffer.
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*
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* @exception {DeveloperError} At least three indices are required.
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* @exception {DeveloperError} The number of indices must be divisable by three.
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* @exception {DeveloperError} Granularity must be greater than zero.
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*/
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PolygonPipeline.computeSubdivision = function(ellipsoid, positions, indices, granularity, hasHeight) {
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hasHeight = when.defaultValue(hasHeight, false);
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granularity = when.defaultValue(granularity, _Math.CesiumMath.RADIANS_PER_DEGREE);
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//>>includeStart('debug', pragmas.debug);
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Check.Check.typeOf.object('ellipsoid', ellipsoid);
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Check.Check.defined('positions', positions);
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Check.Check.defined('indices', indices);
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Check.Check.typeOf.number.greaterThanOrEquals('indices.length', indices.length, 3);
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Check.Check.typeOf.number.equals('indices.length % 3', '0', indices.length % 3, 0);
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Check.Check.typeOf.number.greaterThan('granularity', granularity, 0.0);
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//>>includeEnd('debug');
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// triangles that need (or might need) to be subdivided.
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var triangles = indices.slice(0);
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// New positions due to edge splits are appended to the positions list.
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var i;
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var length = positions.length;
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var subdividedPositions = new Array(length * 3);
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var q = 0;
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for (i = 0; i < length; i++) {
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var item = positions[i];
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subdividedPositions[q++] = item.x;
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subdividedPositions[q++] = item.y;
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subdividedPositions[q++] = item.z;
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}
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var subdividedIndices = [];
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// Used to make sure shared edges are not split more than once.
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var edges = {};
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var radius = ellipsoid.maximumRadius;
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var minDistance = _Math.CesiumMath.chordLength(granularity, radius);
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var minDistanceSqrd = minDistance * minDistance;
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while (triangles.length > 0) {
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var i2 = triangles.pop();
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var i1 = triangles.pop();
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var i0 = triangles.pop();
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var v0 = Cartographic.Cartesian3.fromArray(subdividedPositions, i0 * 3, subdivisionV0Scratch);
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var v1 = Cartographic.Cartesian3.fromArray(subdividedPositions, i1 * 3, subdivisionV1Scratch);
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var v2 = Cartographic.Cartesian3.fromArray(subdividedPositions, i2 * 3, subdivisionV2Scratch);
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var s0 = hasHeight ? v0 : Cartographic.Cartesian3.multiplyByScalar(Cartographic.Cartesian3.normalize(v0, subdivisionS0Scratch), radius, subdivisionS0Scratch);
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var s1 = hasHeight ? v1 : Cartographic.Cartesian3.multiplyByScalar(Cartographic.Cartesian3.normalize(v1, subdivisionS1Scratch), radius, subdivisionS1Scratch);
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var s2 = hasHeight ? v2 : Cartographic.Cartesian3.multiplyByScalar(Cartographic.Cartesian3.normalize(v2, subdivisionS2Scratch), radius, subdivisionS2Scratch);
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var g0 = Cartographic.Cartesian3.magnitudeSquared(Cartographic.Cartesian3.subtract(s0, s1, subdivisionMidScratch));
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var g1 = Cartographic.Cartesian3.magnitudeSquared(Cartographic.Cartesian3.subtract(s1, s2, subdivisionMidScratch));
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var g2 = Cartographic.Cartesian3.magnitudeSquared(Cartographic.Cartesian3.subtract(s2, s0, subdivisionMidScratch));
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var max = Math.max(g0, g1, g2);
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var edge;
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var mid;
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// if the max length squared of a triangle edge is greater than the chord length of squared
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// of the granularity, subdivide the triangle
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if (max > minDistanceSqrd) {
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if (g0 === max) {
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edge = Math.min(i0, i1) + ' ' + Math.max(i0, i1);
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i = edges[edge];
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if (!when.defined(i)) {
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mid = Cartographic.Cartesian3.add(v0, v1, subdivisionMidScratch);
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Cartographic.Cartesian3.multiplyByScalar(mid, 0.5, mid);
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subdividedPositions.push(mid.x, mid.y, mid.z);
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i = subdividedPositions.length / 3 - 1;
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edges[edge] = i;
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}
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triangles.push(i0, i, i2);
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triangles.push(i, i1, i2);
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} else if (g1 === max) {
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edge = Math.min(i1, i2) + ' ' + Math.max(i1, i2);
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i = edges[edge];
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if (!when.defined(i)) {
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mid = Cartographic.Cartesian3.add(v1, v2, subdivisionMidScratch);
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Cartographic.Cartesian3.multiplyByScalar(mid, 0.5, mid);
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subdividedPositions.push(mid.x, mid.y, mid.z);
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i = subdividedPositions.length / 3 - 1;
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edges[edge] = i;
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}
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triangles.push(i1, i, i0);
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triangles.push(i, i2, i0);
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} else if (g2 === max) {
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edge = Math.min(i2, i0) + ' ' + Math.max(i2, i0);
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i = edges[edge];
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if (!when.defined(i)) {
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mid = Cartographic.Cartesian3.add(v2, v0, subdivisionMidScratch);
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Cartographic.Cartesian3.multiplyByScalar(mid, 0.5, mid);
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subdividedPositions.push(mid.x, mid.y, mid.z);
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i = subdividedPositions.length / 3 - 1;
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edges[edge] = i;
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}
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triangles.push(i2, i, i1);
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triangles.push(i, i0, i1);
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}
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} else {
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subdividedIndices.push(i0);
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subdividedIndices.push(i1);
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subdividedIndices.push(i2);
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}
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}
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return new GeometryAttribute.Geometry({
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attributes : {
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position : new GeometryAttribute.GeometryAttribute({
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componentDatatype : ComponentDatatype.ComponentDatatype.DOUBLE,
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componentsPerAttribute : 3,
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values : subdividedPositions
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})
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},
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indices : subdividedIndices,
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primitiveType : PrimitiveType.PrimitiveType.TRIANGLES
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});
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};
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var subdivisionC0Scratch = new Cartographic.Cartographic();
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var subdivisionC1Scratch = new Cartographic.Cartographic();
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var subdivisionC2Scratch = new Cartographic.Cartographic();
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var subdivisionCartographicScratch = new Cartographic.Cartographic();
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/**
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* Subdivides positions on rhumb lines and raises points to the surface of the ellipsoid.
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*
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* @param {Ellipsoid} ellipsoid The ellipsoid the polygon in on.
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* @param {Cartesian3[]} positions An array of {@link Cartesian3} positions of the polygon.
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* @param {Number[]} indices An array of indices that determines the triangles in the polygon.
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* @param {Number} [granularity=CesiumMath.RADIANS_PER_DEGREE] The distance, in radians, between each latitude and longitude. Determines the number of positions in the buffer.
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*
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* @exception {DeveloperError} At least three indices are required.
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* @exception {DeveloperError} The number of indices must be divisable by three.
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* @exception {DeveloperError} Granularity must be greater than zero.
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*/
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PolygonPipeline.computeRhumbLineSubdivision = function(ellipsoid, positions, indices, granularity) {
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granularity = when.defaultValue(granularity, _Math.CesiumMath.RADIANS_PER_DEGREE);
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//>>includeStart('debug', pragmas.debug);
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Check.Check.typeOf.object('ellipsoid', ellipsoid);
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Check.Check.defined('positions', positions);
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Check.Check.defined('indices', indices);
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Check.Check.typeOf.number.greaterThanOrEquals('indices.length', indices.length, 3);
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Check.Check.typeOf.number.equals('indices.length % 3', '0', indices.length % 3, 0);
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Check.Check.typeOf.number.greaterThan('granularity', granularity, 0.0);
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//>>includeEnd('debug');
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// triangles that need (or might need) to be subdivided.
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var triangles = indices.slice(0);
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// New positions due to edge splits are appended to the positions list.
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var i;
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var length = positions.length;
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var subdividedPositions = new Array(length * 3);
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var q = 0;
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for (i = 0; i < length; i++) {
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var item = positions[i];
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subdividedPositions[q++] = item.x;
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subdividedPositions[q++] = item.y;
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subdividedPositions[q++] = item.z;
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}
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var subdividedIndices = [];
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// Used to make sure shared edges are not split more than once.
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var edges = {};
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var radius = ellipsoid.maximumRadius;
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var minDistance = _Math.CesiumMath.chordLength(granularity, radius);
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var rhumb0 = new EllipsoidRhumbLine.EllipsoidRhumbLine(undefined, undefined, ellipsoid);
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var rhumb1 = new EllipsoidRhumbLine.EllipsoidRhumbLine(undefined, undefined, ellipsoid);
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var rhumb2 = new EllipsoidRhumbLine.EllipsoidRhumbLine(undefined, undefined, ellipsoid);
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while (triangles.length > 0) {
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var i2 = triangles.pop();
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var i1 = triangles.pop();
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var i0 = triangles.pop();
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var v0 = Cartographic.Cartesian3.fromArray(subdividedPositions, i0 * 3, subdivisionV0Scratch);
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var v1 = Cartographic.Cartesian3.fromArray(subdividedPositions, i1 * 3, subdivisionV1Scratch);
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var v2 = Cartographic.Cartesian3.fromArray(subdividedPositions, i2 * 3, subdivisionV2Scratch);
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var c0 = ellipsoid.cartesianToCartographic(v0, subdivisionC0Scratch);
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var c1 = ellipsoid.cartesianToCartographic(v1, subdivisionC1Scratch);
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var c2 = ellipsoid.cartesianToCartographic(v2, subdivisionC2Scratch);
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rhumb0.setEndPoints(c0, c1);
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var g0 = rhumb0.surfaceDistance;
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rhumb1.setEndPoints(c1, c2);
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var g1 = rhumb1.surfaceDistance;
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rhumb2.setEndPoints(c2, c0);
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var g2 = rhumb2.surfaceDistance;
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var max = Math.max(g0, g1, g2);
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var edge;
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var mid;
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var midHeight;
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var midCartesian3;
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// if the max length squared of a triangle edge is greater than granularity, subdivide the triangle
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if (max > minDistance) {
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if (g0 === max) {
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edge = Math.min(i0, i1) + ' ' + Math.max(i0, i1);
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i = edges[edge];
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if (!when.defined(i)) {
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mid = rhumb0.interpolateUsingFraction(0.5, subdivisionCartographicScratch);
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midHeight = (c0.height + c1.height) * 0.5;
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midCartesian3 = Cartographic.Cartesian3.fromRadians(mid.longitude, mid.latitude, midHeight, ellipsoid, subdivisionMidScratch);
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subdividedPositions.push(midCartesian3.x, midCartesian3.y, midCartesian3.z);
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i = subdividedPositions.length / 3 - 1;
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edges[edge] = i;
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}
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triangles.push(i0, i, i2);
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triangles.push(i, i1, i2);
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} else if (g1 === max) {
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edge = Math.min(i1, i2) + ' ' + Math.max(i1, i2);
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i = edges[edge];
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if (!when.defined(i)) {
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mid = rhumb1.interpolateUsingFraction(0.5, subdivisionCartographicScratch);
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midHeight = (c1.height + c2.height) * 0.5;
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midCartesian3 = Cartographic.Cartesian3.fromRadians(mid.longitude, mid.latitude, midHeight, ellipsoid, subdivisionMidScratch);
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subdividedPositions.push(midCartesian3.x, midCartesian3.y, midCartesian3.z);
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i = subdividedPositions.length / 3 - 1;
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edges[edge] = i;
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}
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triangles.push(i1, i, i0);
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triangles.push(i, i2, i0);
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} else if (g2 === max) {
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edge = Math.min(i2, i0) + ' ' + Math.max(i2, i0);
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i = edges[edge];
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if (!when.defined(i)) {
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mid = rhumb2.interpolateUsingFraction(0.5, subdivisionCartographicScratch);
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midHeight = (c2.height + c0.height) * 0.5;
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midCartesian3 = Cartographic.Cartesian3.fromRadians(mid.longitude, mid.latitude, midHeight, ellipsoid, subdivisionMidScratch);
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subdividedPositions.push(midCartesian3.x, midCartesian3.y, midCartesian3.z);
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i = subdividedPositions.length / 3 - 1;
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edges[edge] = i;
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}
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triangles.push(i2, i, i1);
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triangles.push(i, i0, i1);
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}
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} else {
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subdividedIndices.push(i0);
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subdividedIndices.push(i1);
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subdividedIndices.push(i2);
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}
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}
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return new GeometryAttribute.Geometry({
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attributes : {
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position : new GeometryAttribute.GeometryAttribute({
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componentDatatype : ComponentDatatype.ComponentDatatype.DOUBLE,
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componentsPerAttribute : 3,
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values : subdividedPositions
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})
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},
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indices : subdividedIndices,
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primitiveType : PrimitiveType.PrimitiveType.TRIANGLES
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});
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};
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/**
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* Scales each position of a geometry's position attribute to a height, in place.
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*
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* @param {Number[]} positions The array of numbers representing the positions to be scaled
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* @param {Number} [height=0.0] The desired height to add to the positions
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* @param {Ellipsoid} [ellipsoid=Ellipsoid.WGS84] The ellipsoid on which the positions lie.
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* @param {Boolean} [scaleToSurface=true] <code>true</code> if the positions need to be scaled to the surface before the height is added.
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* @returns {Number[]} The input array of positions, scaled to height
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*/
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PolygonPipeline.scaleToGeodeticHeight = function(positions, height, ellipsoid, scaleToSurface) {
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ellipsoid = when.defaultValue(ellipsoid, Cartesian2.Ellipsoid.WGS84);
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var n = scaleToGeodeticHeightN;
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var p = scaleToGeodeticHeightP;
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height = when.defaultValue(height, 0.0);
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scaleToSurface = when.defaultValue(scaleToSurface, true);
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if (when.defined(positions)) {
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var length = positions.length;
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for ( var i = 0; i < length; i += 3) {
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Cartographic.Cartesian3.fromArray(positions, i, p);
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if (scaleToSurface) {
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p = ellipsoid.scaleToGeodeticSurface(p, p);
|
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}
|
|
|
|
if (height !== 0) {
|
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n = ellipsoid.geodeticSurfaceNormal(p, n);
|
|
|
|
Cartographic.Cartesian3.multiplyByScalar(n, height, n);
|
|
Cartographic.Cartesian3.add(p, n, p);
|
|
}
|
|
|
|
positions[i] = p.x;
|
|
positions[i + 1] = p.y;
|
|
positions[i + 2] = p.z;
|
|
}
|
|
}
|
|
|
|
return positions;
|
|
};
|
|
|
|
exports.PolygonPipeline = PolygonPipeline;
|
|
exports.WindingOrder = WindingOrder$1;
|
|
|
|
});
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