import * as LineUtil from './LineUtil'; import {toLatLng} from '../geo/LatLng'; import {toPoint} from './Point'; import {toLatLngBounds} from '../geo/LatLngBounds'; /* * @namespace PolyUtil * Various utility functions for polygon geometries. */ /* @function clipPolygon(points: Point[], bounds: Bounds, round?: Boolean): Point[] * Clips the polygon geometry defined by the given `points` by the given bounds (using the [Sutherland-Hodgman algorithm](https://en.wikipedia.org/wiki/Sutherland%E2%80%93Hodgman_algorithm)). * Used by Leaflet to only show polygon points that are on the screen or near, increasing * performance. Note that polygon points needs different algorithm for clipping * than polyline, so there's a separate method for it. */ export function clipPolygon(points, bounds, round) { var clippedPoints, edges = [1, 4, 2, 8], i, j, k, a, b, len, edge, p; for (i = 0, len = points.length; i < len; i++) { points[i]._code = LineUtil._getBitCode(points[i], bounds); } // for each edge (left, bottom, right, top) for (k = 0; k < 4; k++) { edge = edges[k]; clippedPoints = []; for (i = 0, len = points.length, j = len - 1; i < len; j = i++) { a = points[i]; b = points[j]; // if a is inside the clip window if (!(a._code & edge)) { // if b is outside the clip window (a->b goes out of screen) if (b._code & edge) { p = LineUtil._getEdgeIntersection(b, a, edge, bounds, round); p._code = LineUtil._getBitCode(p, bounds); clippedPoints.push(p); } clippedPoints.push(a); // else if b is inside the clip window (a->b enters the screen) } else if (!(b._code & edge)) { p = LineUtil._getEdgeIntersection(b, a, edge, bounds, round); p._code = LineUtil._getBitCode(p, bounds); clippedPoints.push(p); } } points = clippedPoints; } return points; } /* @function polygonCenter(latlngs: LatLng[], crs: CRS): LatLng * Returns the center ([centroid](http://en.wikipedia.org/wiki/Centroid)) of the passed LatLngs (first ring) from a polygon. */ export function polygonCenter(latlngs, crs) { var i, j, p1, p2, f, area, x, y, center; if (!latlngs || latlngs.length === 0) { throw new Error('latlngs not passed'); } if (!LineUtil.isFlat(latlngs)) { console.warn('latlngs are not flat! Only the first ring will be used'); latlngs = latlngs[0]; } var centroidLatLng = toLatLng([0, 0]); var bounds = toLatLngBounds(latlngs); var areaBounds = bounds.getNorthWest().distanceTo(bounds.getSouthWest()) * bounds.getNorthEast().distanceTo(bounds.getNorthWest()); // tests showed that below 1700 rounding errors are happening if (areaBounds < 1700) { // getting a inexact center, to move the latlngs near to [0, 0] to prevent rounding errors centroidLatLng = centroid(latlngs); } var len = latlngs.length; var points = []; for (i = 0; i < len; i++) { var latlng = toLatLng(latlngs[i]); points.push(crs.project(toLatLng([latlng.lat - centroidLatLng.lat, latlng.lng - centroidLatLng.lng]))); } area = x = y = 0; // polygon centroid algorithm; for (i = 0, j = len - 1; i < len; j = i++) { p1 = points[i]; p2 = points[j]; f = p1.y * p2.x - p2.y * p1.x; x += (p1.x + p2.x) * f; y += (p1.y + p2.y) * f; area += f * 3; } if (area === 0) { // Polygon is so small that all points are on same pixel. center = points[0]; } else { center = [x / area, y / area]; } var latlngCenter = crs.unproject(toPoint(center)); return toLatLng([latlngCenter.lat + centroidLatLng.lat, latlngCenter.lng + centroidLatLng.lng]); } /* @function centroid(latlngs: LatLng[]): LatLng * Returns the 'center of mass' of the passed LatLngs. */ export function centroid(coords) { var latSum = 0; var lngSum = 0; var len = 0; for (var i = 0; i < coords.length; i++) { var latlng = toLatLng(coords[i]); latSum += latlng.lat; lngSum += latlng.lng; len++; } return toLatLng([latSum / len, lngSum / len]); }