// https://github.com/topojson/topojson Version 3.0.2. Copyright 2017 Mike Bostock. (function (global, factory) { typeof exports === 'object' && typeof module !== 'undefined' ? factory(exports) : typeof define === 'function' && define.amd ? define(['exports'], factory) : (factory((global.topojson = global.topojson || {}))); }(this, (function (exports) { 'use strict'; var identity = function(x) { return x; }; var transform = function(transform) { if (transform == null) return identity; var x0, y0, kx = transform.scale[0], ky = transform.scale[1], dx = transform.translate[0], dy = transform.translate[1]; return function(input, i) { if (!i) x0 = y0 = 0; var j = 2, n = input.length, output = new Array(n); output[0] = (x0 += input[0]) * kx + dx; output[1] = (y0 += input[1]) * ky + dy; while (j < n) output[j] = input[j], ++j; return output; }; }; var bbox = function(topology) { var t = transform(topology.transform), key, x0 = Infinity, y0 = x0, x1 = -x0, y1 = -x0; function bboxPoint(p) { p = t(p); if (p[0] < x0) x0 = p[0]; if (p[0] > x1) x1 = p[0]; if (p[1] < y0) y0 = p[1]; if (p[1] > y1) y1 = p[1]; } function bboxGeometry(o) { switch (o.type) { case "GeometryCollection": o.geometries.forEach(bboxGeometry); break; case "Point": bboxPoint(o.coordinates); break; case "MultiPoint": o.coordinates.forEach(bboxPoint); break; } } topology.arcs.forEach(function(arc) { var i = -1, n = arc.length, p; while (++i < n) { p = t(arc[i], i); if (p[0] < x0) x0 = p[0]; if (p[0] > x1) x1 = p[0]; if (p[1] < y0) y0 = p[1]; if (p[1] > y1) y1 = p[1]; } }); for (key in topology.objects) { bboxGeometry(topology.objects[key]); } return [x0, y0, x1, y1]; }; var reverse = function(array, n) { var t, j = array.length, i = j - n; while (i < --j) t = array[i], array[i++] = array[j], array[j] = t; }; var feature = function(topology, o) { return o.type === "GeometryCollection" ? {type: "FeatureCollection", features: o.geometries.map(function(o) { return feature$1(topology, o); })} : feature$1(topology, o); }; function feature$1(topology, o) { var id = o.id, bbox = o.bbox, properties = o.properties == null ? {} : o.properties, geometry = object(topology, o); return id == null && bbox == null ? {type: "Feature", properties: properties, geometry: geometry} : bbox == null ? {type: "Feature", id: id, properties: properties, geometry: geometry} : {type: "Feature", id: id, bbox: bbox, properties: properties, geometry: geometry}; } function object(topology, o) { var transformPoint = transform(topology.transform), arcs = topology.arcs; function arc(i, points) { if (points.length) points.pop(); for (var a = arcs[i < 0 ? ~i : i], k = 0, n = a.length; k < n; ++k) { points.push(transformPoint(a[k], k)); } if (i < 0) reverse(points, n); } function point(p) { return transformPoint(p); } function line(arcs) { var points = []; for (var i = 0, n = arcs.length; i < n; ++i) arc(arcs[i], points); if (points.length < 2) points.push(points[0]); // This should never happen per the specification. return points; } function ring(arcs) { var points = line(arcs); while (points.length < 4) points.push(points[0]); // This may happen if an arc has only two points. return points; } function polygon(arcs) { return arcs.map(ring); } function geometry(o) { var type = o.type, coordinates; switch (type) { case "GeometryCollection": return {type: type, geometries: o.geometries.map(geometry)}; case "Point": coordinates = point(o.coordinates); break; case "MultiPoint": coordinates = o.coordinates.map(point); break; case "LineString": coordinates = line(o.arcs); break; case "MultiLineString": coordinates = o.arcs.map(line); break; case "Polygon": coordinates = polygon(o.arcs); break; case "MultiPolygon": coordinates = o.arcs.map(polygon); break; default: return null; } return {type: type, coordinates: coordinates}; } return geometry(o); } var stitch = function(topology, arcs) { var stitchedArcs = {}, fragmentByStart = {}, fragmentByEnd = {}, fragments = [], emptyIndex = -1; // Stitch empty arcs first, since they may be subsumed by other arcs. arcs.forEach(function(i, j) { var arc = topology.arcs[i < 0 ? ~i : i], t; if (arc.length < 3 && !arc[1][0] && !arc[1][1]) { t = arcs[++emptyIndex], arcs[emptyIndex] = i, arcs[j] = t; } }); arcs.forEach(function(i) { var e = ends(i), start = e[0], end = e[1], f, g; if (f = fragmentByEnd[start]) { delete fragmentByEnd[f.end]; f.push(i); f.end = end; if (g = fragmentByStart[end]) { delete fragmentByStart[g.start]; var fg = g === f ? f : f.concat(g); fragmentByStart[fg.start = f.start] = fragmentByEnd[fg.end = g.end] = fg; } else { fragmentByStart[f.start] = fragmentByEnd[f.end] = f; } } else if (f = fragmentByStart[end]) { delete fragmentByStart[f.start]; f.unshift(i); f.start = start; if (g = fragmentByEnd[start]) { delete fragmentByEnd[g.end]; var gf = g === f ? f : g.concat(f); fragmentByStart[gf.start = g.start] = fragmentByEnd[gf.end = f.end] = gf; } else { fragmentByStart[f.start] = fragmentByEnd[f.end] = f; } } else { f = [i]; fragmentByStart[f.start = start] = fragmentByEnd[f.end = end] = f; } }); function ends(i) { var arc = topology.arcs[i < 0 ? ~i : i], p0 = arc[0], p1; if (topology.transform) p1 = [0, 0], arc.forEach(function(dp) { p1[0] += dp[0], p1[1] += dp[1]; }); else p1 = arc[arc.length - 1]; return i < 0 ? [p1, p0] : [p0, p1]; } function flush(fragmentByEnd, fragmentByStart) { for (var k in fragmentByEnd) { var f = fragmentByEnd[k]; delete fragmentByStart[f.start]; delete f.start; delete f.end; f.forEach(function(i) { stitchedArcs[i < 0 ? ~i : i] = 1; }); fragments.push(f); } } flush(fragmentByEnd, fragmentByStart); flush(fragmentByStart, fragmentByEnd); arcs.forEach(function(i) { if (!stitchedArcs[i < 0 ? ~i : i]) fragments.push([i]); }); return fragments; }; var mesh = function(topology) { return object(topology, meshArcs.apply(this, arguments)); }; function meshArcs(topology, object$$1, filter) { var arcs, i, n; if (arguments.length > 1) arcs = extractArcs(topology, object$$1, filter); else for (i = 0, arcs = new Array(n = topology.arcs.length); i < n; ++i) arcs[i] = i; return {type: "MultiLineString", arcs: stitch(topology, arcs)}; } function extractArcs(topology, object$$1, filter) { var arcs = [], geomsByArc = [], geom; function extract0(i) { var j = i < 0 ? ~i : i; (geomsByArc[j] || (geomsByArc[j] = [])).push({i: i, g: geom}); } function extract1(arcs) { arcs.forEach(extract0); } function extract2(arcs) { arcs.forEach(extract1); } function extract3(arcs) { arcs.forEach(extract2); } function geometry(o) { switch (geom = o, o.type) { case "GeometryCollection": o.geometries.forEach(geometry); break; case "LineString": extract1(o.arcs); break; case "MultiLineString": case "Polygon": extract2(o.arcs); break; case "MultiPolygon": extract3(o.arcs); break; } } geometry(object$$1); geomsByArc.forEach(filter == null ? function(geoms) { arcs.push(geoms[0].i); } : function(geoms) { if (filter(geoms[0].g, geoms[geoms.length - 1].g)) arcs.push(geoms[0].i); }); return arcs; } function planarRingArea(ring) { var i = -1, n = ring.length, a, b = ring[n - 1], area = 0; while (++i < n) a = b, b = ring[i], area += a[0] * b[1] - a[1] * b[0]; return Math.abs(area); // Note: doubled area! } var merge = function(topology) { return object(topology, mergeArcs.apply(this, arguments)); }; function mergeArcs(topology, objects) { var polygonsByArc = {}, polygons = [], groups = []; objects.forEach(geometry); function geometry(o) { switch (o.type) { case "GeometryCollection": o.geometries.forEach(geometry); break; case "Polygon": extract(o.arcs); break; case "MultiPolygon": o.arcs.forEach(extract); break; } } function extract(polygon) { polygon.forEach(function(ring) { ring.forEach(function(arc) { (polygonsByArc[arc = arc < 0 ? ~arc : arc] || (polygonsByArc[arc] = [])).push(polygon); }); }); polygons.push(polygon); } function area(ring) { return planarRingArea(object(topology, {type: "Polygon", arcs: [ring]}).coordinates[0]); } polygons.forEach(function(polygon) { if (!polygon._) { var group = [], neighbors = [polygon]; polygon._ = 1; groups.push(group); while (polygon = neighbors.pop()) { group.push(polygon); polygon.forEach(function(ring) { ring.forEach(function(arc) { polygonsByArc[arc < 0 ? ~arc : arc].forEach(function(polygon) { if (!polygon._) { polygon._ = 1; neighbors.push(polygon); } }); }); }); } } }); polygons.forEach(function(polygon) { delete polygon._; }); return { type: "MultiPolygon", arcs: groups.map(function(polygons) { var arcs = [], n; // Extract the exterior (unique) arcs. polygons.forEach(function(polygon) { polygon.forEach(function(ring) { ring.forEach(function(arc) { if (polygonsByArc[arc < 0 ? ~arc : arc].length < 2) { arcs.push(arc); } }); }); }); // Stitch the arcs into one or more rings. arcs = stitch(topology, arcs); // If more than one ring is returned, // at most one of these rings can be the exterior; // choose the one with the greatest absolute area. if ((n = arcs.length) > 1) { for (var i = 1, k = area(arcs[0]), ki, t; i < n; ++i) { if ((ki = area(arcs[i])) > k) { t = arcs[0], arcs[0] = arcs[i], arcs[i] = t, k = ki; } } } return arcs; }) }; } var bisect = function(a, x) { var lo = 0, hi = a.length; while (lo < hi) { var mid = lo + hi >>> 1; if (a[mid] < x) lo = mid + 1; else hi = mid; } return lo; }; var neighbors = function(objects) { var indexesByArc = {}, // arc index -> array of object indexes neighbors = objects.map(function() { return []; }); function line(arcs, i) { arcs.forEach(function(a) { if (a < 0) a = ~a; var o = indexesByArc[a]; if (o) o.push(i); else indexesByArc[a] = [i]; }); } function polygon(arcs, i) { arcs.forEach(function(arc) { line(arc, i); }); } function geometry(o, i) { if (o.type === "GeometryCollection") o.geometries.forEach(function(o) { geometry(o, i); }); else if (o.type in geometryType) geometryType[o.type](o.arcs, i); } var geometryType = { LineString: line, MultiLineString: polygon, Polygon: polygon, MultiPolygon: function(arcs, i) { arcs.forEach(function(arc) { polygon(arc, i); }); } }; objects.forEach(geometry); for (var i in indexesByArc) { for (var indexes = indexesByArc[i], m = indexes.length, j = 0; j < m; ++j) { for (var k = j + 1; k < m; ++k) { var ij = indexes[j], ik = indexes[k], n; if ((n = neighbors[ij])[i = bisect(n, ik)] !== ik) n.splice(i, 0, ik); if ((n = neighbors[ik])[i = bisect(n, ij)] !== ij) n.splice(i, 0, ij); } } } return neighbors; }; var untransform = function(transform) { if (transform == null) return identity; var x0, y0, kx = transform.scale[0], ky = transform.scale[1], dx = transform.translate[0], dy = transform.translate[1]; return function(input, i) { if (!i) x0 = y0 = 0; var j = 2, n = input.length, output = new Array(n), x1 = Math.round((input[0] - dx) / kx), y1 = Math.round((input[1] - dy) / ky); output[0] = x1 - x0, x0 = x1; output[1] = y1 - y0, y0 = y1; while (j < n) output[j] = input[j], ++j; return output; }; }; var quantize = function(topology, transform) { if (topology.transform) throw new Error("already quantized"); if (!transform || !transform.scale) { if (!((n = Math.floor(transform)) >= 2)) throw new Error("n must be \u22652"); box = topology.bbox || bbox(topology); var x0 = box[0], y0 = box[1], x1 = box[2], y1 = box[3], n; transform = {scale: [x1 - x0 ? (x1 - x0) / (n - 1) : 1, y1 - y0 ? (y1 - y0) / (n - 1) : 1], translate: [x0, y0]}; } else { box = topology.bbox; } var t = untransform(transform), box, key, inputs = topology.objects, outputs = {}; function quantizePoint(point) { return t(point); } function quantizeGeometry(input) { var output; switch (input.type) { case "GeometryCollection": output = {type: "GeometryCollection", geometries: input.geometries.map(quantizeGeometry)}; break; case "Point": output = {type: "Point", coordinates: quantizePoint(input.coordinates)}; break; case "MultiPoint": output = {type: "MultiPoint", coordinates: input.coordinates.map(quantizePoint)}; break; default: return input; } if (input.id != null) output.id = input.id; if (input.bbox != null) output.bbox = input.bbox; if (input.properties != null) output.properties = input.properties; return output; } function quantizeArc(input) { var i = 0, j = 1, n = input.length, p, output = new Array(n); // pessimistic output[0] = t(input[0], 0); while (++i < n) if ((p = t(input[i], i))[0] || p[1]) output[j++] = p; // non-coincident points if (j === 1) output[j++] = [0, 0]; // an arc must have at least two points output.length = j; return output; } for (key in inputs) outputs[key] = quantizeGeometry(inputs[key]); return { type: "Topology", bbox: box, transform: transform, objects: outputs, arcs: topology.arcs.map(quantizeArc) }; }; // Computes the bounding box of the specified hash of GeoJSON objects. var bounds = function(objects) { var x0 = Infinity, y0 = Infinity, x1 = -Infinity, y1 = -Infinity; function boundGeometry(geometry) { if (geometry != null && boundGeometryType.hasOwnProperty(geometry.type)) boundGeometryType[geometry.type](geometry); } var boundGeometryType = { GeometryCollection: function(o) { o.geometries.forEach(boundGeometry); }, Point: function(o) { boundPoint(o.coordinates); }, MultiPoint: function(o) { o.coordinates.forEach(boundPoint); }, LineString: function(o) { boundLine(o.arcs); }, MultiLineString: function(o) { o.arcs.forEach(boundLine); }, Polygon: function(o) { o.arcs.forEach(boundLine); }, MultiPolygon: function(o) { o.arcs.forEach(boundMultiLine); } }; function boundPoint(coordinates) { var x = coordinates[0], y = coordinates[1]; if (x < x0) x0 = x; if (x > x1) x1 = x; if (y < y0) y0 = y; if (y > y1) y1 = y; } function boundLine(coordinates) { coordinates.forEach(boundPoint); } function boundMultiLine(coordinates) { coordinates.forEach(boundLine); } for (var key in objects) { boundGeometry(objects[key]); } return x1 >= x0 && y1 >= y0 ? [x0, y0, x1, y1] : undefined; }; var hashset = function(size, hash, equal, type, empty) { if (arguments.length === 3) { type = Array; empty = null; } var store = new type(size = 1 << Math.max(4, Math.ceil(Math.log(size) / Math.LN2))), mask = size - 1; for (var i = 0; i < size; ++i) { store[i] = empty; } function add(value) { var index = hash(value) & mask, match = store[index], collisions = 0; while (match != empty) { if (equal(match, value)) return true; if (++collisions >= size) throw new Error("full hashset"); match = store[index = (index + 1) & mask]; } store[index] = value; return true; } function has(value) { var index = hash(value) & mask, match = store[index], collisions = 0; while (match != empty) { if (equal(match, value)) return true; if (++collisions >= size) break; match = store[index = (index + 1) & mask]; } return false; } function values() { var values = []; for (var i = 0, n = store.length; i < n; ++i) { var match = store[i]; if (match != empty) values.push(match); } return values; } return { add: add, has: has, values: values }; }; var hashmap = function(size, hash, equal, keyType, keyEmpty, valueType) { if (arguments.length === 3) { keyType = valueType = Array; keyEmpty = null; } var keystore = new keyType(size = 1 << Math.max(4, Math.ceil(Math.log(size) / Math.LN2))), valstore = new valueType(size), mask = size - 1; for (var i = 0; i < size; ++i) { keystore[i] = keyEmpty; } function set(key, value) { var index = hash(key) & mask, matchKey = keystore[index], collisions = 0; while (matchKey != keyEmpty) { if (equal(matchKey, key)) return valstore[index] = value; if (++collisions >= size) throw new Error("full hashmap"); matchKey = keystore[index = (index + 1) & mask]; } keystore[index] = key; valstore[index] = value; return value; } function maybeSet(key, value) { var index = hash(key) & mask, matchKey = keystore[index], collisions = 0; while (matchKey != keyEmpty) { if (equal(matchKey, key)) return valstore[index]; if (++collisions >= size) throw new Error("full hashmap"); matchKey = keystore[index = (index + 1) & mask]; } keystore[index] = key; valstore[index] = value; return value; } function get(key, missingValue) { var index = hash(key) & mask, matchKey = keystore[index], collisions = 0; while (matchKey != keyEmpty) { if (equal(matchKey, key)) return valstore[index]; if (++collisions >= size) break; matchKey = keystore[index = (index + 1) & mask]; } return missingValue; } function keys() { var keys = []; for (var i = 0, n = keystore.length; i < n; ++i) { var matchKey = keystore[i]; if (matchKey != keyEmpty) keys.push(matchKey); } return keys; } return { set: set, maybeSet: maybeSet, // set if unset get: get, keys: keys }; }; var equalPoint = function(pointA, pointB) { return pointA[0] === pointB[0] && pointA[1] === pointB[1]; }; // TODO if quantized, use simpler Int32 hashing? var buffer = new ArrayBuffer(16); var uints = new Uint32Array(buffer); var hashPoint = function(point) { var hash = uints[0] ^ uints[1]; hash = hash << 5 ^ hash >> 7 ^ uints[2] ^ uints[3]; return hash & 0x7fffffff; }; // Given an extracted (pre-)topology, identifies all of the junctions. These are // the points at which arcs (lines or rings) will need to be cut so that each // arc is represented uniquely. // // A junction is a point where at least one arc deviates from another arc going // through the same point. For example, consider the point B. If there is a arc // through ABC and another arc through CBA, then B is not a junction because in // both cases the adjacent point pairs are {A,C}. However, if there is an // additional arc ABD, then {A,D} != {A,C}, and thus B becomes a junction. // // For a closed ring ABCA, the first point A’s adjacent points are the second // and last point {B,C}. For a line, the first and last point are always // considered junctions, even if the line is closed; this ensures that a closed // line is never rotated. var join = function(topology) { var coordinates = topology.coordinates, lines = topology.lines, rings = topology.rings, indexes = index(), visitedByIndex = new Int32Array(coordinates.length), leftByIndex = new Int32Array(coordinates.length), rightByIndex = new Int32Array(coordinates.length), junctionByIndex = new Int8Array(coordinates.length), junctionCount = 0, // upper bound on number of junctions i, n, previousIndex, currentIndex, nextIndex; for (i = 0, n = coordinates.length; i < n; ++i) { visitedByIndex[i] = leftByIndex[i] = rightByIndex[i] = -1; } for (i = 0, n = lines.length; i < n; ++i) { var line = lines[i], lineStart = line[0], lineEnd = line[1]; currentIndex = indexes[lineStart]; nextIndex = indexes[++lineStart]; ++junctionCount, junctionByIndex[currentIndex] = 1; // start while (++lineStart <= lineEnd) { sequence(i, previousIndex = currentIndex, currentIndex = nextIndex, nextIndex = indexes[lineStart]); } ++junctionCount, junctionByIndex[nextIndex] = 1; // end } for (i = 0, n = coordinates.length; i < n; ++i) { visitedByIndex[i] = -1; } for (i = 0, n = rings.length; i < n; ++i) { var ring = rings[i], ringStart = ring[0] + 1, ringEnd = ring[1]; previousIndex = indexes[ringEnd - 1]; currentIndex = indexes[ringStart - 1]; nextIndex = indexes[ringStart]; sequence(i, previousIndex, currentIndex, nextIndex); while (++ringStart <= ringEnd) { sequence(i, previousIndex = currentIndex, currentIndex = nextIndex, nextIndex = indexes[ringStart]); } } function sequence(i, previousIndex, currentIndex, nextIndex) { if (visitedByIndex[currentIndex] === i) return; // ignore self-intersection visitedByIndex[currentIndex] = i; var leftIndex = leftByIndex[currentIndex]; if (leftIndex >= 0) { var rightIndex = rightByIndex[currentIndex]; if ((leftIndex !== previousIndex || rightIndex !== nextIndex) && (leftIndex !== nextIndex || rightIndex !== previousIndex)) { ++junctionCount, junctionByIndex[currentIndex] = 1; } } else { leftByIndex[currentIndex] = previousIndex; rightByIndex[currentIndex] = nextIndex; } } function index() { var indexByPoint = hashmap(coordinates.length * 1.4, hashIndex, equalIndex, Int32Array, -1, Int32Array), indexes = new Int32Array(coordinates.length); for (var i = 0, n = coordinates.length; i < n; ++i) { indexes[i] = indexByPoint.maybeSet(i, i); } return indexes; } function hashIndex(i) { return hashPoint(coordinates[i]); } function equalIndex(i, j) { return equalPoint(coordinates[i], coordinates[j]); } visitedByIndex = leftByIndex = rightByIndex = null; var junctionByPoint = hashset(junctionCount * 1.4, hashPoint, equalPoint), j; // Convert back to a standard hashset by point for caller convenience. for (i = 0, n = coordinates.length; i < n; ++i) { if (junctionByIndex[j = indexes[i]]) { junctionByPoint.add(coordinates[j]); } } return junctionByPoint; }; // Given an extracted (pre-)topology, cuts (or rotates) arcs so that all shared // point sequences are identified. The topology can then be subsequently deduped // to remove exact duplicate arcs. var cut = function(topology) { var junctions = join(topology), coordinates = topology.coordinates, lines = topology.lines, rings = topology.rings, next, i, n; for (i = 0, n = lines.length; i < n; ++i) { var line = lines[i], lineMid = line[0], lineEnd = line[1]; while (++lineMid < lineEnd) { if (junctions.has(coordinates[lineMid])) { next = {0: lineMid, 1: line[1]}; line[1] = lineMid; line = line.next = next; } } } for (i = 0, n = rings.length; i < n; ++i) { var ring = rings[i], ringStart = ring[0], ringMid = ringStart, ringEnd = ring[1], ringFixed = junctions.has(coordinates[ringStart]); while (++ringMid < ringEnd) { if (junctions.has(coordinates[ringMid])) { if (ringFixed) { next = {0: ringMid, 1: ring[1]}; ring[1] = ringMid; ring = ring.next = next; } else { // For the first junction, we can rotate rather than cut. rotateArray(coordinates, ringStart, ringEnd, ringEnd - ringMid); coordinates[ringEnd] = coordinates[ringStart]; ringFixed = true; ringMid = ringStart; // restart; we may have skipped junctions } } } } return topology; }; function rotateArray(array, start, end, offset) { reverse$1(array, start, end); reverse$1(array, start, start + offset); reverse$1(array, start + offset, end); } function reverse$1(array, start, end) { for (var mid = start + ((end-- - start) >> 1), t; start < mid; ++start, --end) { t = array[start], array[start] = array[end], array[end] = t; } } // Given a cut topology, combines duplicate arcs. var dedup = function(topology) { var coordinates = topology.coordinates, lines = topology.lines, line, rings = topology.rings, ring, arcCount = lines.length + rings.length, i, n; delete topology.lines; delete topology.rings; // Count the number of (non-unique) arcs to initialize the hashmap safely. for (i = 0, n = lines.length; i < n; ++i) { line = lines[i]; while (line = line.next) ++arcCount; } for (i = 0, n = rings.length; i < n; ++i) { ring = rings[i]; while (ring = ring.next) ++arcCount; } var arcsByEnd = hashmap(arcCount * 2 * 1.4, hashPoint, equalPoint), arcs = topology.arcs = []; for (i = 0, n = lines.length; i < n; ++i) { line = lines[i]; do { dedupLine(line); } while (line = line.next); } for (i = 0, n = rings.length; i < n; ++i) { ring = rings[i]; if (ring.next) { // arc is no longer closed do { dedupLine(ring); } while (ring = ring.next); } else { dedupRing(ring); } } function dedupLine(arc) { var startPoint, endPoint, startArcs, startArc, endArcs, endArc, i, n; // Does this arc match an existing arc in order? if (startArcs = arcsByEnd.get(startPoint = coordinates[arc[0]])) { for (i = 0, n = startArcs.length; i < n; ++i) { startArc = startArcs[i]; if (equalLine(startArc, arc)) { arc[0] = startArc[0]; arc[1] = startArc[1]; return; } } } // Does this arc match an existing arc in reverse order? if (endArcs = arcsByEnd.get(endPoint = coordinates[arc[1]])) { for (i = 0, n = endArcs.length; i < n; ++i) { endArc = endArcs[i]; if (reverseEqualLine(endArc, arc)) { arc[1] = endArc[0]; arc[0] = endArc[1]; return; } } } if (startArcs) startArcs.push(arc); else arcsByEnd.set(startPoint, [arc]); if (endArcs) endArcs.push(arc); else arcsByEnd.set(endPoint, [arc]); arcs.push(arc); } function dedupRing(arc) { var endPoint, endArcs, endArc, i, n; // Does this arc match an existing line in order, or reverse order? // Rings are closed, so their start point and end point is the same. if (endArcs = arcsByEnd.get(endPoint = coordinates[arc[0]])) { for (i = 0, n = endArcs.length; i < n; ++i) { endArc = endArcs[i]; if (equalRing(endArc, arc)) { arc[0] = endArc[0]; arc[1] = endArc[1]; return; } if (reverseEqualRing(endArc, arc)) { arc[0] = endArc[1]; arc[1] = endArc[0]; return; } } } // Otherwise, does this arc match an existing ring in order, or reverse order? if (endArcs = arcsByEnd.get(endPoint = coordinates[arc[0] + findMinimumOffset(arc)])) { for (i = 0, n = endArcs.length; i < n; ++i) { endArc = endArcs[i]; if (equalRing(endArc, arc)) { arc[0] = endArc[0]; arc[1] = endArc[1]; return; } if (reverseEqualRing(endArc, arc)) { arc[0] = endArc[1]; arc[1] = endArc[0]; return; } } } if (endArcs) endArcs.push(arc); else arcsByEnd.set(endPoint, [arc]); arcs.push(arc); } function equalLine(arcA, arcB) { var ia = arcA[0], ib = arcB[0], ja = arcA[1], jb = arcB[1]; if (ia - ja !== ib - jb) return false; for (; ia <= ja; ++ia, ++ib) if (!equalPoint(coordinates[ia], coordinates[ib])) return false; return true; } function reverseEqualLine(arcA, arcB) { var ia = arcA[0], ib = arcB[0], ja = arcA[1], jb = arcB[1]; if (ia - ja !== ib - jb) return false; for (; ia <= ja; ++ia, --jb) if (!equalPoint(coordinates[ia], coordinates[jb])) return false; return true; } function equalRing(arcA, arcB) { var ia = arcA[0], ib = arcB[0], ja = arcA[1], jb = arcB[1], n = ja - ia; if (n !== jb - ib) return false; var ka = findMinimumOffset(arcA), kb = findMinimumOffset(arcB); for (var i = 0; i < n; ++i) { if (!equalPoint(coordinates[ia + (i + ka) % n], coordinates[ib + (i + kb) % n])) return false; } return true; } function reverseEqualRing(arcA, arcB) { var ia = arcA[0], ib = arcB[0], ja = arcA[1], jb = arcB[1], n = ja - ia; if (n !== jb - ib) return false; var ka = findMinimumOffset(arcA), kb = n - findMinimumOffset(arcB); for (var i = 0; i < n; ++i) { if (!equalPoint(coordinates[ia + (i + ka) % n], coordinates[jb - (i + kb) % n])) return false; } return true; } // Rings are rotated to a consistent, but arbitrary, start point. // This is necessary to detect when a ring and a rotated copy are dupes. function findMinimumOffset(arc) { var start = arc[0], end = arc[1], mid = start, minimum = mid, minimumPoint = coordinates[mid]; while (++mid < end) { var point = coordinates[mid]; if (point[0] < minimumPoint[0] || point[0] === minimumPoint[0] && point[1] < minimumPoint[1]) { minimum = mid; minimumPoint = point; } } return minimum - start; } return topology; }; // Given an array of arcs in absolute (but already quantized!) coordinates, // converts to fixed-point delta encoding. // This is a destructive operation that modifies the given arcs! var delta = function(arcs) { var i = -1, n = arcs.length; while (++i < n) { var arc = arcs[i], j = 0, k = 1, m = arc.length, point = arc[0], x0 = point[0], y0 = point[1], x1, y1; while (++j < m) { point = arc[j], x1 = point[0], y1 = point[1]; if (x1 !== x0 || y1 !== y0) arc[k++] = [x1 - x0, y1 - y0], x0 = x1, y0 = y1; } if (k === 1) arc[k++] = [0, 0]; // Each arc must be an array of two or more positions. arc.length = k; } return arcs; }; // Extracts the lines and rings from the specified hash of geometry objects. // // Returns an object with three properties: // // * coordinates - shared buffer of [x, y] coordinates // * lines - lines extracted from the hash, of the form [start, end] // * rings - rings extracted from the hash, of the form [start, end] // // For each ring or line, start and end represent inclusive indexes into the // coordinates buffer. For rings (and closed lines), coordinates[start] equals // coordinates[end]. // // For each line or polygon geometry in the input hash, including nested // geometries as in geometry collections, the `coordinates` array is replaced // with an equivalent `arcs` array that, for each line (for line string // geometries) or ring (for polygon geometries), points to one of the above // lines or rings. var extract = function(objects) { var index = -1, lines = [], rings = [], coordinates = []; function extractGeometry(geometry) { if (geometry && extractGeometryType.hasOwnProperty(geometry.type)) extractGeometryType[geometry.type](geometry); } var extractGeometryType = { GeometryCollection: function(o) { o.geometries.forEach(extractGeometry); }, LineString: function(o) { o.arcs = extractLine(o.arcs); }, MultiLineString: function(o) { o.arcs = o.arcs.map(extractLine); }, Polygon: function(o) { o.arcs = o.arcs.map(extractRing); }, MultiPolygon: function(o) { o.arcs = o.arcs.map(extractMultiRing); } }; function extractLine(line) { for (var i = 0, n = line.length; i < n; ++i) coordinates[++index] = line[i]; var arc = {0: index - n + 1, 1: index}; lines.push(arc); return arc; } function extractRing(ring) { for (var i = 0, n = ring.length; i < n; ++i) coordinates[++index] = ring[i]; var arc = {0: index - n + 1, 1: index}; rings.push(arc); return arc; } function extractMultiRing(rings) { return rings.map(extractRing); } for (var key in objects) { extractGeometry(objects[key]); } return { type: "Topology", coordinates: coordinates, lines: lines, rings: rings, objects: objects }; }; // Given a hash of GeoJSON objects, returns a hash of GeoJSON geometry objects. // Any null input geometry objects are represented as {type: null} in the output. // Any feature.{id,properties,bbox} are transferred to the output geometry object. // Each output geometry object is a shallow copy of the input (e.g., properties, coordinates)! var geometry = function(inputs) { var outputs = {}, key; for (key in inputs) outputs[key] = geomifyObject(inputs[key]); return outputs; }; function geomifyObject(input) { return input == null ? {type: null} : (input.type === "FeatureCollection" ? geomifyFeatureCollection : input.type === "Feature" ? geomifyFeature : geomifyGeometry)(input); } function geomifyFeatureCollection(input) { var output = {type: "GeometryCollection", geometries: input.features.map(geomifyFeature)}; if (input.bbox != null) output.bbox = input.bbox; return output; } function geomifyFeature(input) { var output = geomifyGeometry(input.geometry), key; // eslint-disable-line no-unused-vars if (input.id != null) output.id = input.id; if (input.bbox != null) output.bbox = input.bbox; for (key in input.properties) { output.properties = input.properties; break; } return output; } function geomifyGeometry(input) { if (input == null) return {type: null}; var output = input.type === "GeometryCollection" ? {type: "GeometryCollection", geometries: input.geometries.map(geomifyGeometry)} : input.type === "Point" || input.type === "MultiPoint" ? {type: input.type, coordinates: input.coordinates} : {type: input.type, arcs: input.coordinates}; // TODO Check for unknown types? if (input.bbox != null) output.bbox = input.bbox; return output; } var prequantize = function(objects, bbox, n) { var x0 = bbox[0], y0 = bbox[1], x1 = bbox[2], y1 = bbox[3], kx = x1 - x0 ? (n - 1) / (x1 - x0) : 1, ky = y1 - y0 ? (n - 1) / (y1 - y0) : 1; function quantizePoint(input) { return [Math.round((input[0] - x0) * kx), Math.round((input[1] - y0) * ky)]; } function quantizePoints(input, m) { var i = -1, j = 0, n = input.length, output = new Array(n), // pessimistic pi, px, py, x, y; while (++i < n) { pi = input[i]; x = Math.round((pi[0] - x0) * kx); y = Math.round((pi[1] - y0) * ky); if (x !== px || y !== py) output[j++] = [px = x, py = y]; // non-coincident points } output.length = j; while (j < m) j = output.push([output[0][0], output[0][1]]); return output; } function quantizeLine(input) { return quantizePoints(input, 2); } function quantizeRing(input) { return quantizePoints(input, 4); } function quantizePolygon(input) { return input.map(quantizeRing); } function quantizeGeometry(o) { if (o != null && quantizeGeometryType.hasOwnProperty(o.type)) quantizeGeometryType[o.type](o); } var quantizeGeometryType = { GeometryCollection: function(o) { o.geometries.forEach(quantizeGeometry); }, Point: function(o) { o.coordinates = quantizePoint(o.coordinates); }, MultiPoint: function(o) { o.coordinates = o.coordinates.map(quantizePoint); }, LineString: function(o) { o.arcs = quantizeLine(o.arcs); }, MultiLineString: function(o) { o.arcs = o.arcs.map(quantizeLine); }, Polygon: function(o) { o.arcs = quantizePolygon(o.arcs); }, MultiPolygon: function(o) { o.arcs = o.arcs.map(quantizePolygon); } }; for (var key in objects) { quantizeGeometry(objects[key]); } return { scale: [1 / kx, 1 / ky], translate: [x0, y0] }; }; // Constructs the TopoJSON Topology for the specified hash of features. // Each object in the specified hash must be a GeoJSON object, // meaning FeatureCollection, a Feature or a geometry object. var topology = function(objects, quantization) { var bbox = bounds(objects = geometry(objects)), transform = quantization > 0 && bbox && prequantize(objects, bbox, quantization), topology = dedup(cut(extract(objects))), coordinates = topology.coordinates, indexByArc = hashmap(topology.arcs.length * 1.4, hashArc, equalArc); objects = topology.objects; // for garbage collection topology.bbox = bbox; topology.arcs = topology.arcs.map(function(arc, i) { indexByArc.set(arc, i); return coordinates.slice(arc[0], arc[1] + 1); }); delete topology.coordinates; coordinates = null; function indexGeometry(geometry$$1) { if (geometry$$1 && indexGeometryType.hasOwnProperty(geometry$$1.type)) indexGeometryType[geometry$$1.type](geometry$$1); } var indexGeometryType = { GeometryCollection: function(o) { o.geometries.forEach(indexGeometry); }, LineString: function(o) { o.arcs = indexArcs(o.arcs); }, MultiLineString: function(o) { o.arcs = o.arcs.map(indexArcs); }, Polygon: function(o) { o.arcs = o.arcs.map(indexArcs); }, MultiPolygon: function(o) { o.arcs = o.arcs.map(indexMultiArcs); } }; function indexArcs(arc) { var indexes = []; do { var index = indexByArc.get(arc); indexes.push(arc[0] < arc[1] ? index : ~index); } while (arc = arc.next); return indexes; } function indexMultiArcs(arcs) { return arcs.map(indexArcs); } for (var key in objects) { indexGeometry(objects[key]); } if (transform) { topology.transform = transform; topology.arcs = delta(topology.arcs); } return topology; }; function hashArc(arc) { var i = arc[0], j = arc[1], t; if (j < i) t = i, i = j, j = t; return i + 31 * j; } function equalArc(arcA, arcB) { var ia = arcA[0], ja = arcA[1], ib = arcB[0], jb = arcB[1], t; if (ja < ia) t = ia, ia = ja, ja = t; if (jb < ib) t = ib, ib = jb, jb = t; return ia === ib && ja === jb; } var prune = function(topology) { var oldObjects = topology.objects, newObjects = {}, oldArcs = topology.arcs, oldArcsLength = oldArcs.length, oldIndex = -1, newIndexByOldIndex = new Array(oldArcsLength), newArcsLength = 0, newArcs, newIndex = -1, key; function scanGeometry(input) { switch (input.type) { case "GeometryCollection": input.geometries.forEach(scanGeometry); break; case "LineString": scanArcs(input.arcs); break; case "MultiLineString": input.arcs.forEach(scanArcs); break; case "Polygon": input.arcs.forEach(scanArcs); break; case "MultiPolygon": input.arcs.forEach(scanMultiArcs); break; } } function scanArc(index) { if (index < 0) index = ~index; if (!newIndexByOldIndex[index]) newIndexByOldIndex[index] = 1, ++newArcsLength; } function scanArcs(arcs) { arcs.forEach(scanArc); } function scanMultiArcs(arcs) { arcs.forEach(scanArcs); } function reindexGeometry(input) { var output; switch (input.type) { case "GeometryCollection": output = {type: "GeometryCollection", geometries: input.geometries.map(reindexGeometry)}; break; case "LineString": output = {type: "LineString", arcs: reindexArcs(input.arcs)}; break; case "MultiLineString": output = {type: "MultiLineString", arcs: input.arcs.map(reindexArcs)}; break; case "Polygon": output = {type: "Polygon", arcs: input.arcs.map(reindexArcs)}; break; case "MultiPolygon": output = {type: "MultiPolygon", arcs: input.arcs.map(reindexMultiArcs)}; break; default: return input; } if (input.id != null) output.id = input.id; if (input.bbox != null) output.bbox = input.bbox; if (input.properties != null) output.properties = input.properties; return output; } function reindexArc(oldIndex) { return oldIndex < 0 ? ~newIndexByOldIndex[~oldIndex] : newIndexByOldIndex[oldIndex]; } function reindexArcs(arcs) { return arcs.map(reindexArc); } function reindexMultiArcs(arcs) { return arcs.map(reindexArcs); } for (key in oldObjects) { scanGeometry(oldObjects[key]); } newArcs = new Array(newArcsLength); while (++oldIndex < oldArcsLength) { if (newIndexByOldIndex[oldIndex]) { newIndexByOldIndex[oldIndex] = ++newIndex; newArcs[newIndex] = oldArcs[oldIndex]; } } for (key in oldObjects) { newObjects[key] = reindexGeometry(oldObjects[key]); } return { type: "Topology", bbox: topology.bbox, transform: topology.transform, objects: newObjects, arcs: newArcs }; }; var filter = function(topology, filter) { var oldObjects = topology.objects, newObjects = {}, key; if (filter == null) filter = filterTrue; function filterGeometry(input) { var output, arcs; switch (input.type) { case "Polygon": { arcs = filterRings(input.arcs); output = arcs ? {type: "Polygon", arcs: arcs} : {type: null}; break; } case "MultiPolygon": { arcs = input.arcs.map(filterRings).filter(filterIdentity); output = arcs.length ? {type: "MultiPolygon", arcs: arcs} : {type: null}; break; } case "GeometryCollection": { arcs = input.geometries.map(filterGeometry).filter(filterNotNull); output = arcs.length ? {type: "GeometryCollection", geometries: arcs} : {type: null}; break; } default: return input; } if (input.id != null) output.id = input.id; if (input.bbox != null) output.bbox = input.bbox; if (input.properties != null) output.properties = input.properties; return output; } function filterRings(arcs) { return arcs.length && filterExteriorRing(arcs[0]) // if the exterior is small, ignore any holes ? [arcs[0]].concat(arcs.slice(1).filter(filterInteriorRing)) : null; } function filterExteriorRing(ring) { return filter(ring, false); } function filterInteriorRing(ring) { return filter(ring, true); } for (key in oldObjects) { newObjects[key] = filterGeometry(oldObjects[key]); } return prune({ type: "Topology", bbox: topology.bbox, transform: topology.transform, objects: newObjects, arcs: topology.arcs }); }; function filterTrue() { return true; } function filterIdentity(x) { return x; } function filterNotNull(geometry) { return geometry.type != null; } var filterAttached = function(topology) { var ownerByArc = new Array(topology.arcs.length), // arc index -> index of unique associated ring, or -1 if used by multiple rings ownerIndex = 0, key; function testGeometry(o) { switch (o.type) { case "GeometryCollection": o.geometries.forEach(testGeometry); break; case "Polygon": testArcs(o.arcs); break; case "MultiPolygon": o.arcs.forEach(testArcs); break; } } function testArcs(arcs) { for (var i = 0, n = arcs.length; i < n; ++i, ++ownerIndex) { for (var ring = arcs[i], j = 0, m = ring.length; j < m; ++j) { var arc = ring[j]; if (arc < 0) arc = ~arc; var owner = ownerByArc[arc]; if (owner == null) ownerByArc[arc] = ownerIndex; else if (owner !== ownerIndex) ownerByArc[arc] = -1; } } } for (key in topology.objects) { testGeometry(topology.objects[key]); } return function(ring) { for (var j = 0, m = ring.length, arc; j < m; ++j) { if (ownerByArc[(arc = ring[j]) < 0 ? ~arc : arc] === -1) { return true; } } return false; }; }; function planarTriangleArea(triangle) { var a = triangle[0], b = triangle[1], c = triangle[2]; return Math.abs((a[0] - c[0]) * (b[1] - a[1]) - (a[0] - b[0]) * (c[1] - a[1])) / 2; } function planarRingArea$1(ring) { var i = -1, n = ring.length, a, b = ring[n - 1], area = 0; while (++i < n) a = b, b = ring[i], area += a[0] * b[1] - a[1] * b[0]; return Math.abs(area) / 2; } var filterWeight = function(topology, minWeight, weight) { minWeight = minWeight == null ? Number.MIN_VALUE : +minWeight; if (weight == null) weight = planarRingArea$1; return function(ring, interior) { return weight(feature(topology, {type: "Polygon", arcs: [ring]}).geometry.coordinates[0], interior) >= minWeight; }; }; var filterAttachedWeight = function(topology, minWeight, weight) { var a = filterAttached(topology), w = filterWeight(topology, minWeight, weight); return function(ring, interior) { return a(ring, interior) || w(ring, interior); }; }; function compare(a, b) { return a[1][2] - b[1][2]; } var newHeap = function() { var heap = {}, array = [], size = 0; heap.push = function(object) { up(array[object._ = size] = object, size++); return size; }; heap.pop = function() { if (size <= 0) return; var removed = array[0], object; if (--size > 0) object = array[size], down(array[object._ = 0] = object, 0); return removed; }; heap.remove = function(removed) { var i = removed._, object; if (array[i] !== removed) return; // invalid request if (i !== --size) object = array[size], (compare(object, removed) < 0 ? up : down)(array[object._ = i] = object, i); return i; }; function up(object, i) { while (i > 0) { var j = ((i + 1) >> 1) - 1, parent = array[j]; if (compare(object, parent) >= 0) break; array[parent._ = i] = parent; array[object._ = i = j] = object; } } function down(object, i) { while (true) { var r = (i + 1) << 1, l = r - 1, j = i, child = array[j]; if (l < size && compare(array[l], child) < 0) child = array[j = l]; if (r < size && compare(array[r], child) < 0) child = array[j = r]; if (j === i) break; array[child._ = i] = child; array[object._ = i = j] = object; } } return heap; }; function copy(point) { return [point[0], point[1], 0]; } var presimplify = function(topology, weight) { var point = topology.transform ? transform(topology.transform) : copy, heap = newHeap(); if (weight == null) weight = planarTriangleArea; var arcs = topology.arcs.map(function(arc) { var triangles = [], maxWeight = 0, triangle, i, n; arc = arc.map(point); for (i = 1, n = arc.length - 1; i < n; ++i) { triangle = [arc[i - 1], arc[i], arc[i + 1]]; triangle[1][2] = weight(triangle); triangles.push(triangle); heap.push(triangle); } // Always keep the arc endpoints! arc[0][2] = arc[n][2] = Infinity; for (i = 0, n = triangles.length; i < n; ++i) { triangle = triangles[i]; triangle.previous = triangles[i - 1]; triangle.next = triangles[i + 1]; } while (triangle = heap.pop()) { var previous = triangle.previous, next = triangle.next; // If the weight of the current point is less than that of the previous // point to be eliminated, use the latter’s weight instead. This ensures // that the current point cannot be eliminated without eliminating // previously- eliminated points. if (triangle[1][2] < maxWeight) triangle[1][2] = maxWeight; else maxWeight = triangle[1][2]; if (previous) { previous.next = next; previous[2] = triangle[2]; update(previous); } if (next) { next.previous = previous; next[0] = triangle[0]; update(next); } } return arc; }); function update(triangle) { heap.remove(triangle); triangle[1][2] = weight(triangle); heap.push(triangle); } return { type: "Topology", bbox: topology.bbox, objects: topology.objects, arcs: arcs }; }; var quantile = function(topology, p) { var array = []; topology.arcs.forEach(function(arc) { arc.forEach(function(point) { if (isFinite(point[2])) { // Ignore endpoints, whose weight is Infinity. array.push(point[2]); } }); }); return array.length && quantile$1(array.sort(descending), p); }; function quantile$1(array, p) { if (!(n = array.length)) return; if ((p = +p) <= 0 || n < 2) return array[0]; if (p >= 1) return array[n - 1]; var n, h = (n - 1) * p, i = Math.floor(h), a = array[i], b = array[i + 1]; return a + (b - a) * (h - i); } function descending(a, b) { return b - a; } var simplify = function(topology, minWeight) { minWeight = minWeight == null ? Number.MIN_VALUE : +minWeight; // Remove points whose weight is less than the minimum weight. var arcs = topology.arcs.map(function(input) { var i = -1, j = 0, n = input.length, output = new Array(n), // pessimistic point; while (++i < n) { if ((point = input[i])[2] >= minWeight) { output[j++] = [point[0], point[1]]; } } output.length = j; return output; }); return { type: "Topology", transform: topology.transform, bbox: topology.bbox, objects: topology.objects, arcs: arcs }; }; var pi = Math.PI; var tau = 2 * pi; var quarterPi = pi / 4; var radians = pi / 180; var abs = Math.abs; var atan2 = Math.atan2; var cos = Math.cos; var sin = Math.sin; function halfArea(ring, closed) { var i = 0, n = ring.length, sum = 0, point = ring[closed ? i++ : n - 1], lambda0, lambda1 = point[0] * radians, phi1 = (point[1] * radians) / 2 + quarterPi, cosPhi0, cosPhi1 = cos(phi1), sinPhi0, sinPhi1 = sin(phi1); for (; i < n; ++i) { point = ring[i]; lambda0 = lambda1, lambda1 = point[0] * radians; phi1 = (point[1] * radians) / 2 + quarterPi; cosPhi0 = cosPhi1, cosPhi1 = cos(phi1); sinPhi0 = sinPhi1, sinPhi1 = sin(phi1); // Spherical excess E for a spherical triangle with vertices: south pole, // previous point, current point. Uses a formula derived from Cagnoli’s // theorem. See Todhunter, Spherical Trig. (1871), Sec. 103, Eq. (2). // See https://github.com/d3/d3-geo/blob/master/README.md#geoArea var dLambda = lambda1 - lambda0, sdLambda = dLambda >= 0 ? 1 : -1, adLambda = sdLambda * dLambda, k = sinPhi0 * sinPhi1, u = cosPhi0 * cosPhi1 + k * cos(adLambda), v = k * sdLambda * sin(adLambda); sum += atan2(v, u); } return sum; } function sphericalRingArea(ring, interior) { var sum = halfArea(ring, true); if (interior) sum *= -1; return (sum < 0 ? tau + sum : sum) * 2; } function sphericalTriangleArea(t) { return abs(halfArea(t, false)) * 2; } exports.bbox = bbox; exports.feature = feature; exports.mesh = mesh; exports.meshArcs = meshArcs; exports.merge = merge; exports.mergeArcs = mergeArcs; exports.neighbors = neighbors; exports.quantize = quantize; exports.transform = transform; exports.untransform = untransform; exports.topology = topology; exports.filter = filter; exports.filterAttached = filterAttached; exports.filterAttachedWeight = filterAttachedWeight; exports.filterWeight = filterWeight; exports.planarRingArea = planarRingArea$1; exports.planarTriangleArea = planarTriangleArea; exports.presimplify = presimplify; exports.quantile = quantile; exports.simplify = simplify; exports.sphericalRingArea = sphericalRingArea; exports.sphericalTriangleArea = sphericalTriangleArea; Object.defineProperty(exports, '__esModule', { value: true }); })));