项目需求需要空间计算能力,开始选型Sedona(GeoSpark)来完成,
需求需要每一条数据在满足某条件的情况下,去查找某张表进行空间匹配,找到离这个点(point)最近的一条道路(lineString)
第一个方案: 使用sedona来使用临近道路的判断
由于sedona本质还是使用spark的能力,所以遵循spark的开发规则,不能在rdd.map 里面干活,sedona也不支持批量查,只能一条一条匹配。 伪代码如下
val spatial_sql =
"""
| select
| ST_GeomFromWKT(geom) geom, name, adcode
| from ods.ods_third_party_road_data
|""".stripMargin
val third_party_road_df = spark.sql(spatial_sql).toDF()
aoi_day_s_df.rdd.collect().par.map(row => {
val tmp_location = row.getAs[String]("poi_location")
val near_street = spatialQueryStreet(third_party_road_df, city_code, tmp_location)
println(near_street)
...
)
def spatialQueryStreet(third_party_road_df:DataFrame, city_code:String, location: String): String = {
val frame = third_party_road_df.where("adcode = '%s'".format(city_code)).toDF()
val tp_road_spatial_rdd = Adapter.toSpatialRdd(frame, "geom")
tp_road_spatial_rdd.buildIndex(IndexType.RTREE, false)
val geometryFactory = new GeometryFactory()
val x = location.substring(location.indexOf("(") + 1, location.indexOf(" "))
val y = location.substring(location.indexOf(" ") + 1, location.indexOf(")"))
val pointObject = geometryFactory.createPoint(new Coordinate(x.toDouble, y.toDouble))
val usingIndex = true
val result = KNNQuery.SpatialKnnQuery(tp_road_spatial_rdd, pointObject, 1, usingIndex)
if (result.isEmpty) {
return ""
} else {
val dst = result.get(0)
//System.out.println("==== dst.getUserData: " + dst.getUserData.toString)
val strings = dst.getUserData.toString.split("\t")
val near_street = strings(0)
//System.out.println("==== near_street: " + near_street)
near_street
}
结果效率不高,因为每条数据都要匹配,sedona又不能在rdd.map中使用,所以必须先collect().map,这就不能利用到spark多节点并行的特性; 2. 每条数据都基于third_party_road_df创建了空间索引来查,效率更低了(如果只有一条数据还勉强可以接受)
方案2: 改sedona为JTS来处理,jts直接创建rtree,可以在rdd.map中处理,而且创建速度也更快一些,效率更高了
伪代码如下
poi_build_aoi_aoi_day_s_df.rdd.map(row => {
val tmp_location = row.getAs[String]("poi_location")
val rtree = createRtree(model_list)
near_street = spatialQueryStreet(rtree, tmp_location)
println(near_street)
...
)
def createRtree(third_party_road_list: Array[ThirdPartyModel]): STRtree = {
val rtree = new STRtree()
for (model <- third_party_road_list) {
val geom = model.geometry
geom.setUserData(model.name)
rtree.insert(geom.getEnvelopeInternal, model.geometry)
}
rtree.build()
rtree
}
def spatialQueryStreet(rtree: STRtree, location: String): String = {
if (rtree == null) {
""
}
val geometryFactory = new GeometryFactory()
val x = location.substring(location.indexOf("(") + 1, location.indexOf(" "))
val y = location.substring(location.indexOf(" ") + 1, location.indexOf(")"))
val pointObject = geometryFactory.createPoint(new Coordinate(x.toDouble, y.toDouble))
val result = rtree.nearestNeighbour(pointObject.getEnvelopeInternal, pointObject, new GeometryItemDistance())
val name = result.asInstanceOf[Geometry].getUserData.asInstanceOf[String]
println(s"nearestNeighbour name: $name")
name
}
通过这次修改,由原来跑3个小时(甚至更多)的任务在15分钟内就跑完了
PS: 经尝试rtree 不能通过广播变量发送出去,会报序列化异常
其实还可以再优化一下,上面每条数据还是创建了一次rtree, 可以改为mapPartition,然后只建一次rtree, 数据量大时效果更佳
aoi_day_s_df.rdd.mapPartitions(iterator => {
// rtree 放到iterator.map 外面创建,搞一次就ok了,更快(不过我没有试验,应该是百分百可行的)
val rtree = createRtree(model_list)
val seq = iterator.map(row => {
val tmp_location = row.getAs[String]("poi_location")
near_street = spatialQueryStreet(rtree, tmp_location)
println(near_street)
...
)
seq
)
