176 lines
7.0 KiB
TypeScript
176 lines
7.0 KiB
TypeScript
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/* Generated from Java with JSweet 3.0.0 - http://www.jsweet.org */
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/**
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* Constructor taking a longitude and a latitude
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*
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* @param {number} longitude
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* @param {number} latitude
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* @class
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* @author Linus Helgesson
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*/
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var Coordinate = /** @class */ (function () {
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function Coordinate(longitude, latitude) {
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if (((typeof longitude === 'number') || longitude === null) && ((typeof latitude === 'number') || latitude === null)) {
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var __args = arguments;
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this.mLongitude = 0;
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this.mLatitude = 0;
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this.mResults = [0, 0];
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this.mLongitude = longitude;
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this.mLatitude = latitude;
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}
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else if (longitude === undefined && latitude === undefined) {
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var __args = arguments;
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this.mLongitude = 0;
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this.mLatitude = 0;
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this.mResults = [0, 0];
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}
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else
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throw new Error('invalid overload');
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}
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/**
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* Get the longitude part of this coordinate
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*
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* @return {number} The longitude part of this coordinate
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*/
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Coordinate.prototype.getLongitude = function () {
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return this.mLongitude;
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};
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/**
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* Set the longitude part of this coordinate
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*
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* @param {number} longitude The longitude part of this coordinate
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*/
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Coordinate.prototype.setLongitude = function (longitude) {
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this.mLongitude = longitude;
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};
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/**
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* Get the latitude part of this coordinate
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*
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* @return {number} The latitude part of this coordinate
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*/
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Coordinate.prototype.getLatitude = function () {
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return this.mLatitude;
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};
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/**
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* Set the latitude part of this coordinate
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*
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* @param {number} latitude The latitude part of this coordinate
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*/
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Coordinate.prototype.setLatitude = function (latitude) {
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this.mLatitude = latitude;
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};
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/**
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* Calculates a bounding box of a certain size arund a coordinate. This is mainly used for a quick check
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* in the database for cameras that are close to a coordinate. This function takes a size ion meters as
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* a parameter and returns an array of two Coordinate objects. The first Coordinate is the upper left corner
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* while the last coordinate is the bottom right corner.
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*
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* @param {number} side The length of the square side in meters
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*
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* @return {Coordinate[]} Two cordinates where the first is smaller than the second.
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*/
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Coordinate.prototype.getBoundingBox = function (side: number) {
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var ret = [null, null];
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var degLatM:number , degLatM:number, degLongM:number, deltaLat:number, deltaLong:number;
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degLatM = 110574.235;
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degLongM = 110572.833 * Math.cos(this.mLatitude * this.PI_OVER_180);
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deltaLat = side / degLatM;
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deltaLong = side / degLongM;
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ret[0] = new Coordinate(this.getLongitude() - deltaLong, this.getLatitude() - deltaLat);
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ret[1] = new Coordinate(this.getLongitude() + deltaLong, this.getLatitude() + deltaLat);
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return ret;
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};
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/**
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* Calculates the distance between two Coordinate objects using the Spherical law of cosines found at:
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*
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* http://www.movable-type.co.uk/scripts/latlong.html
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*
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* @param coordinate The coordinate to measure the distance to.
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* @return {number} the distance in meters
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* @param {Coordinate} dest
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*/
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Coordinate.prototype.distanceTo = function (dest) {
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Coordinate.computeDistanceAndBearing(this.mLatitude, this.mLongitude, dest.getLatitude(), dest.getLongitude(), this.mResults);
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return this.mResults[0];
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};
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/*private*/ Coordinate.computeDistanceAndBearing = function (lat1, lon1, lat2, lon2, results) {
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var MAXITERS = 20;
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lat1 *= Math.PI / 180.0;
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lat2 *= Math.PI / 180.0;
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lon1 *= Math.PI / 180.0;
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lon2 *= Math.PI / 180.0;
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var a = 6378137.0;
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var b = 6356752.3142;
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var f = (a - b) / a;
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var aSqMinusBSqOverBSq = (a * a - b * b) / (b * b);
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var L = lon2 - lon1;
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var A = 0.0;
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var U1 = Math.atan((1.0 - f) * Math.tan(lat1));
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var U2 = Math.atan((1.0 - f) * Math.tan(lat2));
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var cosU1 = Math.cos(U1);
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var cosU2 = Math.cos(U2);
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var sinU1 = Math.sin(U1);
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var sinU2 = Math.sin(U2);
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var cosU1cosU2 = cosU1 * cosU2;
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var sinU1sinU2 = sinU1 * sinU2;
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var sigma = 0.0;
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var deltaSigma = 0.0;
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var cosSqAlpha = 0.0;
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var cos2SM = 0.0;
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var cosSigma = 0.0;
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var sinSigma = 0.0;
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var cosLambda = 0.0;
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var sinLambda = 0.0;
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var lambda = L;
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for (var iter = 0; iter < MAXITERS; iter++) {
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{
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var lambdaOrig = lambda;
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cosLambda = Math.cos(lambda);
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sinLambda = Math.sin(lambda);
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var t1 = cosU2 * sinLambda;
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var t2 = cosU1 * sinU2 - sinU1 * cosU2 * cosLambda;
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var sinSqSigma = t1 * t1 + t2 * t2;
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sinSigma = Math.sqrt(sinSqSigma);
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cosSigma = sinU1sinU2 + cosU1cosU2 * cosLambda;
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sigma = Math.atan2(sinSigma, cosSigma);
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var sinAlpha = (sinSigma === 0) ? 0.0 : cosU1cosU2 * sinLambda / sinSigma;
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cosSqAlpha = 1.0 - sinAlpha * sinAlpha;
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cos2SM = (cosSqAlpha === 0) ? 0.0 : cosSigma - 2.0 * sinU1sinU2 / cosSqAlpha;
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var uSquared = cosSqAlpha * aSqMinusBSqOverBSq;
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A = 1 + (uSquared / 16384.0) * (4096.0 + uSquared * (-768 + uSquared * (320.0 - 175.0 * uSquared)));
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var B = (uSquared / 1024.0) * (256.0 + uSquared * (-128.0 + uSquared * (74.0 - 47.0 * uSquared)));
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var C = (f / 16.0) * cosSqAlpha * (4.0 + f * (4.0 - 3.0 * cosSqAlpha));
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var cos2SMSq = cos2SM * cos2SM;
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deltaSigma = B * sinSigma * (cos2SM + (B / 4.0) * (cosSigma * (-1.0 + 2.0 * cos2SMSq) - (B / 6.0) * cos2SM * (-3.0 + 4.0 * sinSigma * sinSigma) * (-3.0 + 4.0 * cos2SMSq)));
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lambda = L + (1.0 - C) * f * sinAlpha * (sigma + C * sinSigma * (cos2SM + C * cosSigma * (-1.0 + 2.0 * cos2SM * cos2SM)));
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var delta = (lambda - lambdaOrig) / lambda;
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if (Math.abs(delta) < 1.0E-12) {
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break;
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}
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}
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;
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}
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var distance = (b * A * (sigma - deltaSigma));
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results[0] = distance;
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if (results.length > 1) {
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var initialBearing = Math.atan2(cosU2 * sinLambda, cosU1 * sinU2 - sinU1 * cosU2 * cosLambda);
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initialBearing *= 180.0 / Math.PI;
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results[1] = initialBearing;
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if (results.length > 2) {
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var finalBearing = Math.atan2(cosU1 * sinLambda, -sinU1 * cosU2 + cosU1 * sinU2 * cosLambda);
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finalBearing *= 180.0 / Math.PI;
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results[2] = finalBearing;
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}
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}
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};
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Coordinate.PI_OVER_180 = 0.017453292;
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Coordinate.EARTH_RADIUS = 6371009;
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return Coordinate;
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}());
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Coordinate["__class"] = "Coordinate";
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