380 lines
12 KiB
TypeScript
380 lines
12 KiB
TypeScript
import * as turf from '@turf/turf'
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import {BBox} from "./BBox";
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export class GeoOperations {
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static surfaceAreaInSqMeters(feature: any) {
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return turf.area(feature);
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}
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/**
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* Converts a GeoJson feature to a point GeoJson feature
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* @param feature
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*/
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static centerpoint(feature: any) {
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const newFeature = turf.center(feature);
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newFeature.properties = feature.properties;
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newFeature.id = feature.id;
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return newFeature;
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}
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static centerpointCoordinates(feature: any): [number, number] {
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// @ts-ignore
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return turf.center(feature).geometry.coordinates;
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}
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/**
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* Returns the distance between the two points in kilometers
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* @param lonlat0
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* @param lonlat1
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*/
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static distanceBetween(lonlat0: [number, number], lonlat1: [number, number]) {
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return turf.distance(lonlat0, lonlat1)
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}
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/**
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* Calculates the overlap of 'feature' with every other specified feature.
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* The features with which 'feature' overlaps, are returned together with their overlap area in m²
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*
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* If 'feature' is a LineString, the features in which this feature is (partly) embedded is returned, the overlap length in meter is given
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*
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* If 'feature' is a point, it will return every feature the point is embedded in. Overlap will be undefined
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*/
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static calculateOverlap(feature: any, otherFeatures: any[]): { feat: any, overlap: number }[] {
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const featureBBox = BBox.get(feature);
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const result: { feat: any, overlap: number }[] = [];
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if (feature.geometry.type === "Point") {
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const coor = feature.geometry.coordinates;
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for (const otherFeature of otherFeatures) {
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if (feature.id !== undefined && feature.id === otherFeature.id) {
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continue;
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}
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if (otherFeature.geometry === undefined) {
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console.error("No geometry for feature ", feature)
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throw "List of other features contains a feature without geometry an undefined"
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}
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if (GeoOperations.inside(coor, otherFeature)) {
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result.push({feat: otherFeature, overlap: undefined})
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}
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}
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return result;
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}
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if (feature.geometry.type === "LineString") {
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for (const otherFeature of otherFeatures) {
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if (feature.id !== undefined && feature.id === otherFeature.id) {
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continue;
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}
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const intersection = this.calculateInstersection(feature, otherFeature, featureBBox)
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if (intersection === null) {
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continue
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}
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result.push({feat: otherFeature, overlap: intersection})
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}
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return result;
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}
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if (feature.geometry.type === "Polygon" || feature.geometry.type === "MultiPolygon") {
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for (const otherFeature of otherFeatures) {
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if (feature.id === otherFeature.id) {
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continue;
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}
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if (otherFeature.geometry.type === "Point") {
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if (this.inside(otherFeature, feature)) {
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result.push({feat: otherFeature, overlap: undefined})
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}
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continue;
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}
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// Calculate the surface area of the intersection
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const intersection = this.calculateInstersection(feature, otherFeature, featureBBox)
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if (intersection === null) {
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continue;
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}
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result.push({feat: otherFeature, overlap: intersection})
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}
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return result;
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}
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console.error("Could not correctly calculate the overlap of ", feature, ": unsupported type")
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return result;
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}
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public static inside(pointCoordinate, feature): boolean {
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// ray-casting algorithm based on
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// http://www.ecse.rpi.edu/Homepages/wrf/Research/Short_Notes/pnpoly.html
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if (feature.geometry.type === "Point") {
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return false;
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}
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if (pointCoordinate.geometry !== undefined) {
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pointCoordinate = pointCoordinate.geometry.coordinates
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}
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if (feature.geometry.type === "MultiPolygon") {
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const coordinates = feature.geometry.coordinates[0];
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const outerPolygon = coordinates[0];
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const inside = GeoOperations.inside(pointCoordinate, {
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geometry: {
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type: 'Polygon',
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coordinates: [outerPolygon]
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}
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})
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if (!inside) {
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return false;
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}
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for (let i = 1; i < coordinates.length; i++) {
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const inHole = GeoOperations.inside(pointCoordinate, {
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geometry: {
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type: 'Polygon',
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coordinates: [coordinates[i]]
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}
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})
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if (inHole) {
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return false;
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}
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}
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return true;
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}
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const x: number = pointCoordinate[0];
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const y: number = pointCoordinate[1];
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for (let i = 0; i < feature.geometry.coordinates.length; i++) {
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let poly = feature.geometry.coordinates[i];
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let inside = false;
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for (let i = 0, j = poly.length - 1; i < poly.length; j = i++) {
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const coori = poly[i];
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const coorj = poly[j];
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const xi = coori[0];
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const yi = coori[1];
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const xj = coorj[0];
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const yj = coorj[1];
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const intersect = ((yi > y) != (yj > y))
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&& (x < (xj - xi) * (y - yi) / (yj - yi) + xi);
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if (intersect) {
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inside = !inside;
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}
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}
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if (inside) {
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return true;
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}
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}
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return false;
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};
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static lengthInMeters(feature: any) {
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return turf.length(feature) * 1000
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}
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static buffer(feature: any, bufferSizeInMeter: number) {
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return turf.buffer(feature, bufferSizeInMeter / 1000, {
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units: 'kilometers'
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})
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}
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static bbox(feature: any) {
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const [lon, lat, lon0, lat0] = turf.bbox(feature)
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return {
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"type": "Feature",
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"geometry": {
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"type": "LineString",
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"coordinates": [
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[
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lon,
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lat
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],
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[
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lon0,
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lat
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],
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[
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lon0,
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lat0
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],
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[
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lon,
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lat0
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],
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[
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lon,
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lat
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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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* Generates the closest point on a way from a given point
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*
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* The properties object will contain three values:
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// - `index`: closest point was found on nth line part,
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// - `dist`: distance between pt and the closest point (in kilometer),
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// `location`: distance along the line between start and the closest point.
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* @param way The road on which you want to find a point
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* @param point Point defined as [lon, lat]
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*/
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public static nearestPoint(way, point: [number, number]) {
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return turf.nearestPointOnLine(way, point, {units: "kilometers"});
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}
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public static toCSV(features: any[]): string {
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const headerValuesSeen = new Set<string>();
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const headerValuesOrdered: string[] = []
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function addH(key) {
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if (!headerValuesSeen.has(key)) {
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headerValuesSeen.add(key)
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headerValuesOrdered.push(key)
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}
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}
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addH("_lat")
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addH("_lon")
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const lines: string[] = []
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for (const feature of features) {
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const properties = feature.properties;
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for (const key in properties) {
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if (!properties.hasOwnProperty(key)) {
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continue;
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}
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addH(key)
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}
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}
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headerValuesOrdered.sort()
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for (const feature of features) {
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const properties = feature.properties;
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let line = ""
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for (const key of headerValuesOrdered) {
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const value = properties[key]
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if (value === undefined) {
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line += ","
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} else {
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line += JSON.stringify(value) + ","
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}
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}
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lines.push(line)
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}
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return headerValuesOrdered.map(v => JSON.stringify(v)).join(",") + "\n" + lines.join("\n")
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}
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/**
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* Calculates the intersection between two features.
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* Returns the length if intersecting a linestring and a (multi)polygon (in meters), returns a surface area (in m²) if intersecting two (multi)polygons
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* Returns 0 if both are linestrings
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* Returns null if the features are not intersecting
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*/
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private static calculateInstersection(feature, otherFeature, featureBBox: BBox, otherFeatureBBox?: BBox): number {
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try {
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if (feature.geometry.type === "LineString") {
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otherFeatureBBox = otherFeatureBBox ?? BBox.get(otherFeature);
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const overlaps = featureBBox.overlapsWith(otherFeatureBBox)
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if (!overlaps) {
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return null;
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}
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// Calculate the length of the intersection
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let intersectionPoints = turf.lineIntersect(feature, otherFeature);
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if (intersectionPoints.features.length == 0) {
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// No intersections.
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// If one point is inside of the polygon, all points are
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const coors = feature.geometry.coordinates;
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const startCoor = coors[0]
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if (this.inside(startCoor, otherFeature)) {
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return this.lengthInMeters(feature)
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}
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return null;
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}
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let intersectionPointsArray = intersectionPoints.features.map(d => {
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return d.geometry.coordinates
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});
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if (otherFeature.geometry.type === "LineString") {
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if (intersectionPointsArray.length > 0) {
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return 0
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}
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return null;
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}
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if (intersectionPointsArray.length == 1) {
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// We need to add the start- or endpoint of the current feature, depending on which one is embedded
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const coors = feature.geometry.coordinates;
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const startCoor = coors[0]
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if (this.inside(startCoor, otherFeature)) {
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// The startpoint is embedded
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intersectionPointsArray.push(startCoor)
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} else {
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intersectionPointsArray.push(coors[coors.length - 1])
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}
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}
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let intersection = turf.lineSlice(turf.point(intersectionPointsArray[0]), turf.point(intersectionPointsArray[1]), feature);
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if (intersection == null) {
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return null;
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}
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const intersectionSize = turf.length(intersection); // in km
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return intersectionSize * 1000
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}
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if (feature.geometry.type === "Polygon" || feature.geometry.type === "MultiPolygon") {
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const otherFeatureBBox = BBox.get(otherFeature);
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const overlaps = featureBBox.overlapsWith(otherFeatureBBox)
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if (!overlaps) {
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return null;
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}
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if (otherFeature.geometry.type === "LineString") {
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return this.calculateInstersection(otherFeature, feature, otherFeatureBBox, featureBBox)
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}
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const intersection = turf.intersect(feature, otherFeature);
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if (intersection == null) {
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return null;
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}
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return turf.area(intersection); // in m²
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}
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} catch (exception) {
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console.warn("EXCEPTION CAUGHT WHILE INTERSECTING: ", exception);
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return undefined
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}
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return undefined;
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}
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}
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