320 lines
9.3 KiB
JavaScript
320 lines
9.3 KiB
JavaScript
// Copyright IBM Corp. 2013,2016. All Rights Reserved.
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// Node module: loopback-datasource-juggler
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// This file is licensed under the MIT License.
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// License text available at https://opensource.org/licenses/MIT
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'use strict';
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const assert = require('assert');
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/*!
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* Get a near filter from a given where object. For connector use only.
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*/
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exports.nearFilter = function nearFilter(where) {
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const nearResults = [];
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nearSearch(where);
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return (!nearResults.length ? false : nearResults);
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function nearSearch(clause, parentKeys) {
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if (typeof clause !== 'object') {
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return false;
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}
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parentKeys = parentKeys || [];
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Object.keys(clause).forEach(function(clauseKey) {
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if (typeof clause[clauseKey] !== 'object' || !clause[clauseKey]) return;
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if (Array.isArray(clause[clauseKey])) {
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clause[clauseKey].forEach(function(el, index) {
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const ret = nearSearch(el, parentKeys.concat(clauseKey).concat(index));
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if (ret) return ret;
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});
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} else {
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if (clause[clauseKey].hasOwnProperty('near')) {
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const result = clause[clauseKey];
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nearResults.push({
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near: result.near,
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maxDistance: result.maxDistance,
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minDistance: result.minDistance,
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unit: result.unit,
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// If key is at root, define a single string, otherwise append it to the full path array
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mongoKey: parentKeys.length ? parentKeys.concat(clauseKey) : clauseKey,
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key: clauseKey,
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});
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}
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}
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});
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}
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};
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/*!
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* Filter a set of results using the given filters returned by `nearFilter()`.
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* Can support multiple locations, but will include results from all of them.
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*
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* WARNING: "or" operator with GeoPoint does not work as expected, eg:
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* {where: {or: [{location: {near: (29,-90)}},{name:'Sean'}]}}
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* Will actually work as if you had used "and". This is because geo filtering
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* takes place outside of the SQL query, so the result set of "name = Sean" is
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* returned by the database, and then the location filtering happens in the app
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* logic. So the "near" operator is always an "and" of the SQL filters, and "or"
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* of other GeoPoint filters.
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*
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* Additionally, since this step occurs after the SQL result set is returned,
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* if using GeoPoints with pagination the result set may be smaller than the
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* page size. The page size is enforced at the DB level, and then we may
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* remove results at the Geo-app level. If we "limit: 25", but 4 of those results
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* do not have a matching geopoint field, the request will only return 21 results.
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* This may make it erroneously look like a given page is the end of the result set.
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*/
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exports.filter = function(rawResults, filters) {
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const distances = {};
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const results = [];
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filters.forEach(function(filter) {
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const origin = filter.near;
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const max = filter.maxDistance > 0 ? filter.maxDistance : false;
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const min = filter.minDistance > 0 ? filter.minDistance : false;
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const unit = filter.unit;
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const key = filter.key;
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// create distance index
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rawResults.forEach(function(result) {
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let loc = result[key];
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// filter out results without locations
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if (!loc) return;
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if (!(loc instanceof GeoPoint)) loc = GeoPoint(loc);
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if (typeof loc.lat !== 'number') return;
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if (typeof loc.lng !== 'number') return;
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const d = GeoPoint.distanceBetween(origin, loc, {type: unit});
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// filter result if distance is either < minDistance or > maxDistance
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if ((min && d < min) || (max && d > max)) return;
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distances[result.id] = d;
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results.push(result);
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});
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results.sort(function(resA, resB) {
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const a = resA[key];
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const b = resB[key];
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if (a && b) {
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const da = distances[resA.id];
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const db = distances[resB.id];
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if (db === da) return 0;
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return da > db ? 1 : -1;
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} else {
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return 0;
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}
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});
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});
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return results;
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};
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exports.GeoPoint = GeoPoint;
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/**
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* The GeoPoint object represents a physical location.
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*
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* For example:
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*
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* ```js
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* var loopback = require(‘loopback’);
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* var here = new loopback.GeoPoint({lat: 10.32424, lng: 5.84978});
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* ```
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*
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* Embed a latitude / longitude point in a model.
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*
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* ```js
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* var CoffeeShop = loopback.createModel('coffee-shop', {
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* location: 'GeoPoint'
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* });
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* ```
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*
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* You can query LoopBack models with a GeoPoint property and an attached data source using geo-spatial filters and
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* sorting. For example, the following code finds the three nearest coffee shops.
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*
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* ```js
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* CoffeeShop.attachTo(oracle);
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* var here = new GeoPoint({lat: 10.32424, lng: 5.84978});
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* CoffeeShop.find( {where: {location: {near: here}}, limit:3}, function(err, nearbyShops) {
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* console.info(nearbyShops); // [CoffeeShop, ...]
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* });
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* ```
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* @class GeoPoint
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* @property {Number} lat The latitude in degrees.
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* @property {Number} lng The longitude in degrees.
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*
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* @options {Object} Options Object with two Number properties: lat and long.
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* @property {Number} lat The latitude point in degrees. Range: -90 to 90.
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* @property {Number} lng The longitude point in degrees. Range: -180 to 180.
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*
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* @options {Array} Options Array with two Number entries: [lat,long].
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* @property {Number} lat The latitude point in degrees. Range: -90 to 90.
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* @property {Number} lng The longitude point in degrees. Range: -180 to 180.
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*/
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function GeoPoint(data) {
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if (!(this instanceof GeoPoint)) {
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return new GeoPoint(data);
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}
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if (arguments.length === 2) {
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data = {
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lat: arguments[0],
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lng: arguments[1],
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};
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}
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assert(Array.isArray(data) || typeof data === 'object' || typeof data === 'string',
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'must provide valid geo-coordinates array [lat, lng] or object or a "lat, lng" string');
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if (typeof data === 'string') {
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try {
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data = JSON.parse(data);
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} catch (err) {
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data = data.split(/,\s*/);
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assert(data.length === 2, 'must provide a string "lat,lng" creating a GeoPoint with a string');
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}
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}
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if (Array.isArray(data)) {
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data = {
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lat: Number(data[0]),
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lng: Number(data[1]),
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};
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} else {
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data.lng = Number(data.lng);
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data.lat = Number(data.lat);
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}
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assert(typeof data === 'object', 'must provide a lat and lng object when creating a GeoPoint');
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assert(typeof data.lat === 'number' && !isNaN(data.lat), 'lat must be a number when creating a GeoPoint');
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assert(typeof data.lng === 'number' && !isNaN(data.lng), 'lng must be a number when creating a GeoPoint');
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assert(data.lng <= 180, 'lng must be <= 180');
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assert(data.lng >= -180, 'lng must be >= -180');
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assert(data.lat <= 90, 'lat must be <= 90');
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assert(data.lat >= -90, 'lat must be >= -90');
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this.lat = data.lat;
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this.lng = data.lng;
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}
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/**
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* Determine the spherical distance between two GeoPoints.
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*
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* @param {GeoPoint} pointA Point A
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* @param {GeoPoint} pointB Point B
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* @options {Object} options Options object with one key, 'type'. See below.
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* @property {String} type Unit of measurement, one of:
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*
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* - `miles` (default)
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* - `radians`
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* - `kilometers`
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* - `meters`
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* - `miles`
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* - `feet`
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* - `degrees`
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*/
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GeoPoint.distanceBetween = function distanceBetween(a, b, options) {
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if (!(a instanceof GeoPoint)) {
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a = GeoPoint(a);
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}
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if (!(b instanceof GeoPoint)) {
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b = GeoPoint(b);
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}
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const x1 = a.lat;
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const y1 = a.lng;
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const x2 = b.lat;
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const y2 = b.lng;
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return geoDistance(x1, y1, x2, y2, options);
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};
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/**
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* Determine the spherical distance to the given point.
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* Example:
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* ```js
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* var loopback = require(‘loopback’);
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*
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* var here = new loopback.GeoPoint({lat: 10, lng: 10});
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* var there = new loopback.GeoPoint({lat: 5, lng: 5});
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*
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* loopback.GeoPoint.distanceBetween(here, there, {type: 'miles'}) // 438
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* ```
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* @param {Object} point GeoPoint object to which to measure distance.
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* @options {Object} options Options object with one key, 'type'. See below.
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* @property {String} type Unit of measurement, one of:
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*
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* - `miles` (default)
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* - `radians`
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* - `kilometers`
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* - `meters`
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* - `miles`
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* - `feet`
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* - `degrees`
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*/
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GeoPoint.prototype.distanceTo = function(point, options) {
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return GeoPoint.distanceBetween(this, point, options);
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};
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/**
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* Simple serialization.
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*/
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GeoPoint.prototype.toString = function() {
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return this.lat + ',' + this.lng;
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};
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/**
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* @property {Number} DEG2RAD - Factor to convert degrees to radians.
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* @property {Number} RAD2DEG - Factor to convert radians to degrees.
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* @property {Object} EARTH_RADIUS - Radius of the earth.
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*/
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// factor to convert degrees to radians
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const DEG2RAD = 0.01745329252;
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// factor to convert radians degrees to degrees
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const RAD2DEG = 57.29577951308;
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// radius of the earth
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const EARTH_RADIUS = {
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kilometers: 6370.99056,
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meters: 6370990.56,
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miles: 3958.75,
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feet: 20902200,
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radians: 1,
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degrees: RAD2DEG,
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};
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function geoDistance(x1, y1, x2, y2, options) {
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const type = (options && options.type) || 'miles';
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// Convert to radians
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x1 = x1 * DEG2RAD;
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y1 = y1 * DEG2RAD;
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x2 = x2 * DEG2RAD;
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y2 = y2 * DEG2RAD;
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// use the haversine formula to calculate distance for any 2 points on a sphere.
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// ref http://en.wikipedia.org/wiki/Haversine_formula
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const haversine = function(a) {
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return Math.pow(Math.sin(a / 2.0), 2);
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};
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const f = Math.sqrt(haversine(x2 - x1) + Math.cos(x2) * Math.cos(x1) * haversine(y2 - y1));
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return 2 * Math.asin(f) * EARTH_RADIUS[type];
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}
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