define(["leaflet"], function (L) { return L.TileLayer.Canvas.extend({ setData: function (d) { this.data = d this.redraw() }, drawTile: function (canvas, tilePoint) { function getTileBBox(s, map, tileSize, margin) { var tl = map.unproject([s.x - margin, s.y - margin]) var br = map.unproject([s.x + margin + tileSize, s.y + margin + tileSize]) return [br.lat, tl.lng, tl.lat, br.lng] } if (!this.data) return var tileSize = this.options.tileSize var s = tilePoint.multiplyBy(tileSize) var map = this._map var margin = 50 var bbox = getTileBBox(s, map, tileSize, margin) var nodes = this.data.search(bbox) if (nodes.length === 0) return var ctx = canvas.getContext("2d") var distance = 12 var radius = 3 var a = 1.2 var startAngle = Math.PI ctx.beginPath() nodes.forEach(function (d) { var p = map.project([d.node.nodeinfo.location.latitude, d.node.nodeinfo.location.longitude]) var clients = d.node.statistics.clients if (clients === 0) return p.x -= s.x p.y -= s.y var angle = startAngle for (var i = 0; i < clients; i++) { if ((angle - startAngle) > 2 * Math.PI) { angle = startAngle distance += 2 * radius * a } var x = p.x + distance * Math.cos(angle) var y = p.y + distance * Math.sin(angle) ctx.moveTo(x, y) ctx.arc(x, y, radius, 0, 2 * Math.PI) var n = Math.floor((Math.PI * distance) / (a * radius)) var angleDelta = 2 * Math.PI / n angle += angleDelta } }) ctx.fillStyle = "rgba(153, 118, 16, 0.5)" ctx.fill() } }) })