Ejemplo n.º 1
0
def get_s2_coverage(swLat, swLng, neLat, neLng):
    geoms = []

    r = s2sphere.RegionCoverer()
    r.min_level = 10
    r.max_level = 10
    r.max_cells = 40
    p1 = s2sphere.LatLng.from_degrees(float(swLat), float(swLng))
    p2 = s2sphere.LatLng.from_degrees(float(neLat), float(neLng))
    covering = r.get_covering(s2sphere.LatLngRect.from_point_pair(p1, p2))
    for cell_id in covering:
        cell_to_render = {}
        rect_bound = s2sphere.Cell(cell_id)
        center = s2sphere.LatLng.from_point(rect_bound.get_center())
        cell_to_render['s2_cell_id'] = str(cell_id.id())
        cell_to_render['center'] = {
            'lat': center.lat().degrees,
            'lng': center.lng().degrees
        }
        cell_to_render['vertices'] = get_vertices_from_s2cell(rect_bound)

        # log.info(rect_bound.approx_area())

        del rect_bound
        geoms.append(cell_to_render)

    return geoms
Ejemplo n.º 2
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def search_map(request):
    print(request)
    params = {}
    params["north"] = 1
    params["south"] = 1
    params["east"] = 1
    params["west"] = 1
    json_result = []

    # 1. Check redis results
    # redis_cached = check_redis(params)
    # if len(redis_cached) != 0:
    #     json_result.append(redis_cached)

    tic = time.gmtime(0) # 
    
    # 2. Check database results
    region = s2sphere.RegionCoverer()
    p1 = s2sphere.LatLng.from_degrees(params["north"], params["west"])
    p2 = s2sphere.LatLng.from_degrees(params["south"], params["east"])
    cell_ids = region.get_covering(s2sphere.LatLngRect.from_point_pair(p1, p2))
    
    db_result = search_database(cell_ids)

    toc = time.gmtime(0)

    # if toc - tic > COMMON_TIME_LAG:
    #     return json_result

    if len(db_result) == 0:
        data_fetcher.fetch(cell_ids)
        db_result =search_database(cell_ids)
    else:
        return HttpResponse(json.dupms(json_result))
Ejemplo n.º 3
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def get_cell_ids(lat, lng, angle):
    region = s2sphere.Cap.from_axis_angle(s2sphere.LatLng.from_degrees(lat, lng).to_point(), s2sphere.Angle.from_radians(angle))
    coverer = s2sphere.RegionCoverer()
    coverer.min_level = 9
    coverer.max_level = 9
    cells = coverer.get_covering(region)
    return cells
Ejemplo n.º 4
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def main():
    r = s2sphere.RegionCoverer()
    p1 = s2sphere.LatLng.from_degrees(48.831776, 2.222639)
    p2 = s2sphere.LatLng.from_degrees(48.902839, 2.406)
    cell_ids = r.get_covering(s2sphere.LatLngRect.from_point_pair(p1, p2))
    # print(cell_ids)

    # create a map
    map_osm = folium.Map(location=[48.86, 2.3], zoom_start=12, tiles='Stamen Toner')

    # # get vertices from rect to draw them on map
    # rect_vertices = []
    # for i in [0, 1, 2, 3, 0]:
    #     rect_vertices.append([vertex.lat().degrees(), vertex.lng().degrees()])

    # draw the cells
    style_function = lambda x: {'weight': 1, 'fillColor': '#eea500'}
    for cellid in cell_ids:
        cell = s2sphere.Cell(cellid)
        vertices = []
        for i in range(0, 4):
            vertex = cell.get_vertex(i)
            latlng = s2sphere.LatLng.from_point(vertex)
            # currently the angle is in radians
            vertices.append((math.degrees(latlng.lat().radians), math.degrees(latlng.lng().radians)))
            gj = folium.GeoJson({"type": "Polygon", "coordinates": [vertices]}, style_function=style_function)
            gj.add_child(folium.Popup(cellid.to_token()))
            gj.add_to(map_osm)
Ejemplo n.º 5
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 def get_s2cells_from_circle(lat, lng, radius, level=15):
     earth = 6371000
     region = s2sphere.Cap.from_axis_angle(s2sphere.LatLng.from_degrees(lat, lng).to_point(),
                                           s2sphere.Angle.from_degrees(360 * radius / (2 * math.pi * earth)))
     coverer = s2sphere.RegionCoverer()
     coverer.min_level = level
     coverer.max_level = level
     cells = coverer.get_covering(region)
     return cells
Ejemplo n.º 6
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 def lat_lng_to_cell_id(lat, lng, level=10):
     region_cover = s2sphere.RegionCoverer()
     region_cover.min_level = level
     region_cover.max_level = level
     region_cover.max_cells = 1
     p1 = s2sphere.LatLng.from_degrees(lat, lng)
     p2 = s2sphere.LatLng.from_degrees(lat, lng)
     covering = region_cover.get_covering(s2sphere.LatLngRect.from_point_pair(p1, p2))
     # we will only get our desired cell ;)
     return covering[0].id()
Ejemplo n.º 7
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def break_down_area_to_cell(north, south, west, east):
    """Return a list of s2 cell id"""
    result = []
    region = s2sphere.RegionCoverer()
    region.min_level = 15
    region.max_level = 15
    p1 = s2sphere.LatLng.from_degrees(north, west)
    p2 = s2sphere.LatLng.from_degrees(south, east)
    cell_ids = region.get_covering(s2sphere.LatLngRect.from_point_pair(p1, p2))
    result += [cell_id.id() for cell_id in cell_ids]
    return result
Ejemplo n.º 8
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 def test_covering(self):
     r = s2sphere.RegionCoverer()
     p1 = s2sphere.LatLng.from_degrees(33, -122)
     p2 = s2sphere.LatLng.from_degrees(33.1, -122.1)
     cell_ids = r.get_covering(s2sphere.LatLngRect.from_point_pair(p1, p2))
     ids = sorted([c.id() for c in cell_ids])
     target = [
         9291041754864156672, 9291043953887412224, 9291044503643226112,
         9291045878032760832, 9291047252422295552, 9291047802178109440,
         9291051650468806656, 9291052200224620544
     ]
     self.assertEqual(ids, target)
Ejemplo n.º 9
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def getNeighbors(loc, level=15, spread=700):
    distance = VincentyDistance(meters=spread)
    center = (loc[0], loc[1], 0)
    p1 = distance.destination(point=center, bearing=45)
    p2 = distance.destination(point=center, bearing=225)
    p1 = s2sphere.LatLng.from_degrees(p1[0], p1[1])
    p2 = s2sphere.LatLng.from_degrees(p2[0], p2[1])
    rect = s2sphere.LatLngRect.from_point_pair(p1, p2)
    region = s2sphere.RegionCoverer()
    region.min_level = level
    region.max_level = level
    cells = region.get_covering(rect)
    return sorted([c.id() for c in cells])
Ejemplo n.º 10
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def get_s2_cells(n=north, w=west, s=south, e=east, level=12):
    region_covered = s2sphere.LatLngRect.from_point_pair(
        s2sphere.LatLng.from_degrees(n, w), s2sphere.LatLng.from_degrees(s, e))
    coverer = s2sphere.RegionCoverer()
    coverer.min_level = level
    coverer.max_level = level
    coverer.max_cells = 50
    covering = coverer.get_covering(region_covered)
    markers = []
    for cellid in covering:
        cell = s2sphere.Cell(cellid)
        markers.append({
            'id': 'cell-' + str(cellid.id()),
            'coords': [(get_vertex(cell, v)) for v in range(0, 4)]
        })
    return markers
Ejemplo n.º 11
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    def calc_s2_cells(north, south, west, east, cell_size=16):
        centers_in_area = []
        region = s2sphere.RegionCoverer()
        region.min_level = cell_size
        region.max_level = cell_size
        p1 = s2sphere.LatLng.from_degrees(north, west)
        p2 = s2sphere.LatLng.from_degrees(south, east)
        cell_ids = region.get_covering(
            s2sphere.LatLngRect.from_point_pair(p1, p2))
        log.debug('Detecting ' + str(len(cell_ids)) +
              ' L{} Cells in Area'.format(str(cell_size)))
        for cell_id in cell_ids:
            split_cell_id = str(cell_id).split(' ')
            position = S2Helper.get_position_from_cell(int(split_cell_id[1], 16))
            centers_in_area.append([position[0], position[1]])
            # calc_route_data.append(str(position[0]) + ', ' + str(position[1]))

        return centers_in_area
Ejemplo n.º 12
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def generate_cells(nLat, nLng, sLat, sLng, cell_size=13):
    points = []
    area = s2sphere.LatLngRect.from_point_pair(
        s2sphere.LatLng.from_degrees(nLat, nLng),
        s2sphere.LatLng.from_degrees(sLat, sLng))

    r = s2sphere.RegionCoverer()
    r.min_level = cell_size
    r.max_level = cell_size

    cells = r.get_covering(area)

    for cell in cells:
        c = s2sphere.Cell(cell.parent(13))
        ll = s2sphere.LatLng.from_point(c.get_center())
        points.append([ll.lat().degrees, ll.lng().degrees])

    return points
Ejemplo n.º 13
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    def get_s2_cells_from_fence(geofence, cell_size=16):
        _geofence = geofence
        south, east, north, west = _geofence.get_polygon_from_fence()
        calc_route_data = []
        region = s2sphere.RegionCoverer()
        region.min_level = cell_size
        region.max_level = cell_size
        p1 = s2sphere.LatLng.from_degrees(north, west)
        p2 = s2sphere.LatLng.from_degrees(south, east)
        cell_ids = region.get_covering(
            s2sphere.LatLngRect.from_point_pair(p1, p2))

        for cell_id in cell_ids:
            split_cell_id = str(cell_id).split(' ')
            position = S2Helper.middle_of_cell(int(split_cell_id[1], 16))
            calc_route_data.append([position[0], position[1]])
        log.debug('Detecting ' + str(len(calc_route_data)) +
                  ' L{} Cells in Area'.format(str(cell_size)))

        return calc_route_data
Ejemplo n.º 14
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def break_down_area_to_cell(north, south, west, east):
    result = []

    region = s2sphere.RegionCoverer()
    region.min_level = 15
    region.max_level = 15
    p1 = s2sphere.LatLng.from_degrees(north, west)
    p2 = s2sphere.LatLng.from_degrees(south, east)

    rect = s2sphere.LatLngRect.from_point_pair(p1, p2)
    area = rect.area()

    if (area * 1000 * 1000 * 100 > 7):
        print DBG + "The area is too big, return ..."
        #logger.info(DBG + "The area is too big, return ...")
        return

    cell_ids = region.get_covering(rect)
    result += [cell_id.id() for cell_id in cell_ids]

    return result
Ejemplo n.º 15
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def get_cellids_in_range(latitude,
                         longitude,
                         range_in_meters,
                         min_level,
                         max_level,
                         max_cells,
                         level_mod=1):
    ll = s2sphere.LatLng.from_degrees(latitude, longitude)

    cap = s2sphere.Cap(ll.to_point(),
                       (meters_to_radians(range_in_meters)**2) / 2)

    cap_rect_bound = cap.get_rect_bound()

    coverer = s2sphere.RegionCoverer()
    coverer.min_level = min_level
    coverer.max_level = max_level
    coverer.max_cells = max_cells
    coverer.level_mod = level_mod
    cell_ids = coverer.get_covering(cap)
    return cell_ids
Ejemplo n.º 16
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def getCircleCoveringRect(lat, lng, radius, parent_level):
    radius_radians = earthMetersToRadians(radius)
    latlng = s2sphere.LatLng.from_degrees(float(lat),
                                          float(lng)).normalized().to_point()
    region = s2sphere.Cap.from_axis_height(
        latlng, (radius_radians * radius_radians) / 2)
    coverer = s2sphere.RegionCoverer()
    coverer.min_level = int(parent_level)
    coverer.max_level = int(parent_level)
    coverer.max_cells = MAX_S2_CELLS
    covering = coverer.get_covering(region)
    s2_rect = []
    for cell_id in covering:
        new_cell = s2sphere.Cell(cell_id)
        vertices = []
        for i in range(4):
            vertex = new_cell.get_vertex(i)
            latlng = s2sphere.LatLng.from_point(vertex)
            vertices.append((math.degrees(latlng.lat().radians),
                             math.degrees(latlng.lng().radians)))
        s2_rect.append(vertices)
    return s2_rect
Ejemplo n.º 17
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import socket
from s2sphere import CellId, math, Cap, LatLng, Angle
from s2sphere import RegionCoverer

HOST = ''
PORT = 50007

MAX_NUMBER_OF_SIMULATION = 100
POKEMON_NUMBER = 493
EXPIRATION_DURATION = 60 * 20 * 1000

client = MongoClient('localhost', 27017)
db = client.pokemon_golazzy_data
posts = db.posts

region = s2sphere.RegionCoverer()


class Pokemon:
    def __init__(self, pokemon_id, lng, lat, expire, cell_id):
        self.pokemon_id = pokemon_id
        self.lng = lng
        self.lat = lat
        self.expire = expire
        self.cell_id = cell_id

    def __str__(self):
        return "id: {0}, lng: {1}, lat: {2}, expire: {3}".format(
            self.pokemon_id, self.lng, self.lat, self.expire)

Ejemplo n.º 18
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def getRectCoveringRect(max_lon, min_lon, max_lat, min_lat):
    r = s2sphere.RegionCoverer()
    p1 = s2sphere.LatLng.from_degrees(min_lat, min_lon)
    p2 = s2sphere.LatLng.from_degrees(max_lat, max_lon)
    cell_ids = r.get_covering(s2sphere.LatLngRect.from_point_pair(p1, p2))
    return cell_ids