Spatial RDD app
The page outlines the steps to create Spatial RDDs and run spatial queries using Sedona-core.
Set up dependencies¶
Please refer to Set up dependencies to set up dependencies.
Create Sedona config¶
Please refer to Create Sedona config to create a Sedona config.
Initiate SedonaContext¶
Please refer to Initiate SedonaContext to initiate a SedonaContext.
Create a SpatialRDD¶
Create a typed SpatialRDD¶
Sedona-core provides three special SpatialRDDs: PointRDD, PolygonRDD, and LineStringRDD.
Warning
Typed SpatialRDD has been deprecated for a long time. We do NOT recommend it anymore.
Create a generic SpatialRDD¶
A generic SpatialRDD is not typed to a certain geometry type and open to more scenarios. It allows an input data file contains mixed types of geometries. For instance, a WKT file contains three types gemetries LineString, Polygon and MultiPolygon.
From WKT/WKB¶
Geometries in a WKT and WKB file always occupy a single column no matter how many coordinates they have. Sedona provides WktReader
and WkbReader
to create generic SpatialRDD.
Suppose we have a checkin.tsv
WKT TSV file at Path /Download/checkin.tsv
as follows:
POINT (-88.331492 32.324142) hotel
POINT (-88.175933 32.360763) gas
POINT (-88.388954 32.357073) bar
POINT (-88.221102 32.35078) restaurant
Use the following code to create a SpatialRDD
val inputLocation = "/Download/checkin.tsv"
val wktColumn = 0 // The WKT string starts from Column 0
val allowTopologyInvalidGeometries = true // Optional
val skipSyntaxInvalidGeometries = false // Optional
val spatialRDD = WktReader.readToGeometryRDD(sedona.sparkContext, inputLocation, wktColumn, allowTopologyInvalidGeometries, skipSyntaxInvalidGeometries)
String inputLocation = "/Download/checkin.tsv"
int wktColumn = 0 // The WKT string starts from Column 0
boolean allowTopologyInvalidGeometries = true // Optional
boolean skipSyntaxInvalidGeometries = false // Optional
SpatialRDD spatialRDD = WktReader.readToGeometryRDD(sedona.sparkContext, inputLocation, wktColumn, allowTopologyInvalidGeometries, skipSyntaxInvalidGeometries)
from sedona.core.formatMapper import WktReader
from sedona.core.formatMapper import WkbReader
WktReader.readToGeometryRDD(sc, wkt_geometries_location, 0, True, False)
WkbReader.readToGeometryRDD(sc, wkb_geometries_location, 0, True, False)
From GeoJSON¶
Geometries in GeoJSON is similar to WKT/WKB. However, a GeoJSON file must be beaked into multiple lines.
Suppose we have a polygon.json
GeoJSON file at Path /Download/polygon.json
as follows:
{ "type": "Feature", "properties": { "STATEFP": "01", "COUNTYFP": "077", "TRACTCE": "011501", "BLKGRPCE": "5", "AFFGEOID": "1500000US010770115015", "GEOID": "010770115015", "NAME": "5", "LSAD": "BG", "ALAND": 6844991, "AWATER": 32636 }, "geometry": { "type": "Polygon", "coordinates": [ [ [ -87.621765, 34.873444 ], [ -87.617535, 34.873369 ], [ -87.6123, 34.873337 ], [ -87.604049, 34.873303 ], [ -87.604033, 34.872316 ], [ -87.60415, 34.867502 ], [ -87.604218, 34.865687 ], [ -87.604409, 34.858537 ], [ -87.604018, 34.851336 ], [ -87.603716, 34.844829 ], [ -87.603696, 34.844307 ], [ -87.603673, 34.841884 ], [ -87.60372, 34.841003 ], [ -87.603879, 34.838423 ], [ -87.603888, 34.837682 ], [ -87.603889, 34.83763 ], [ -87.613127, 34.833938 ], [ -87.616451, 34.832699 ], [ -87.621041, 34.831431 ], [ -87.621056, 34.831526 ], [ -87.62112, 34.831925 ], [ -87.621603, 34.8352 ], [ -87.62158, 34.836087 ], [ -87.621383, 34.84329 ], [ -87.621359, 34.844438 ], [ -87.62129, 34.846387 ], [ -87.62119, 34.85053 ], [ -87.62144, 34.865379 ], [ -87.621765, 34.873444 ] ] ] } },
{ "type": "Feature", "properties": { "STATEFP": "01", "COUNTYFP": "045", "TRACTCE": "021102", "BLKGRPCE": "4", "AFFGEOID": "1500000US010450211024", "GEOID": "010450211024", "NAME": "4", "LSAD": "BG", "ALAND": 11360854, "AWATER": 0 }, "geometry": { "type": "Polygon", "coordinates": [ [ [ -85.719017, 31.297901 ], [ -85.715626, 31.305203 ], [ -85.714271, 31.307096 ], [ -85.69999, 31.307552 ], [ -85.697419, 31.307951 ], [ -85.675603, 31.31218 ], [ -85.672733, 31.312876 ], [ -85.672275, 31.311977 ], [ -85.67145, 31.310988 ], [ -85.670622, 31.309524 ], [ -85.670729, 31.307622 ], [ -85.669876, 31.30666 ], [ -85.669796, 31.306224 ], [ -85.670356, 31.306178 ], [ -85.671664, 31.305583 ], [ -85.67177, 31.305299 ], [ -85.671878, 31.302764 ], [ -85.671344, 31.302123 ], [ -85.668276, 31.302076 ], [ -85.66566, 31.30093 ], [ -85.665687, 31.30022 ], [ -85.669183, 31.297677 ], [ -85.668703, 31.295638 ], [ -85.671985, 31.29314 ], [ -85.677177, 31.288211 ], [ -85.678452, 31.286376 ], [ -85.679236, 31.28285 ], [ -85.679195, 31.281426 ], [ -85.676865, 31.281049 ], [ -85.674661, 31.28008 ], [ -85.674377, 31.27935 ], [ -85.675714, 31.276882 ], [ -85.677938, 31.275168 ], [ -85.680348, 31.276814 ], [ -85.684032, 31.278848 ], [ -85.684387, 31.279082 ], [ -85.692398, 31.283499 ], [ -85.705032, 31.289718 ], [ -85.706755, 31.290476 ], [ -85.718102, 31.295204 ], [ -85.719132, 31.29689 ], [ -85.719017, 31.297901 ] ] ] } },
{ "type": "Feature", "properties": { "STATEFP": "01", "COUNTYFP": "055", "TRACTCE": "001300", "BLKGRPCE": "3", "AFFGEOID": "1500000US010550013003", "GEOID": "010550013003", "NAME": "3", "LSAD": "BG", "ALAND": 1378742, "AWATER": 247387 }, "geometry": { "type": "Polygon", "coordinates": [ [ [ -86.000685, 34.00537 ], [ -85.998837, 34.009768 ], [ -85.998012, 34.010398 ], [ -85.987865, 34.005426 ], [ -85.986656, 34.004552 ], [ -85.985, 34.002659 ], [ -85.98851, 34.001502 ], [ -85.987567, 33.999488 ], [ -85.988666, 33.99913 ], [ -85.992568, 33.999131 ], [ -85.993144, 33.999714 ], [ -85.994876, 33.995153 ], [ -85.998823, 33.989548 ], [ -85.999925, 33.994237 ], [ -86.000616, 34.000028 ], [ -86.000685, 34.00537 ] ] ] } },
{ "type": "Feature", "properties": { "STATEFP": "01", "COUNTYFP": "089", "TRACTCE": "001700", "BLKGRPCE": "2", "AFFGEOID": "1500000US010890017002", "GEOID": "010890017002", "NAME": "2", "LSAD": "BG", "ALAND": 1040641, "AWATER": 0 }, "geometry": { "type": "Polygon", "coordinates": [ [ [ -86.574172, 34.727375 ], [ -86.562684, 34.727131 ], [ -86.562797, 34.723865 ], [ -86.562957, 34.723168 ], [ -86.562336, 34.719766 ], [ -86.557381, 34.719143 ], [ -86.557352, 34.718322 ], [ -86.559921, 34.717363 ], [ -86.564827, 34.718513 ], [ -86.567582, 34.718565 ], [ -86.570572, 34.718577 ], [ -86.573618, 34.719377 ], [ -86.574172, 34.727375 ] ] ] } },
Use the following code to create a generic SpatialRDD:
val inputLocation = "/Download/polygon.json"
val allowTopologyInvalidGeometries = true // Optional
val skipSyntaxInvalidGeometries = false // Optional
val spatialRDD = GeoJsonReader.readToGeometryRDD(sedona.sparkContext, inputLocation, allowTopologyInvalidGeometries, skipSyntaxInvalidGeometries)
String inputLocation = "/Download/polygon.json"
boolean allowTopologyInvalidGeometries = true // Optional
boolean skipSyntaxInvalidGeometries = false // Optional
SpatialRDD spatialRDD = GeoJsonReader.readToGeometryRDD(sedona.sparkContext, inputLocation, allowTopologyInvalidGeometries, skipSyntaxInvalidGeometries)
from sedona.core.formatMapper import GeoJsonReader
GeoJsonReader.readToGeometryRDD(sc, geo_json_file_location)
Warning
The way that Sedona reads JSON file is different from SparkSQL
From Shapefile¶
val shapefileInputLocation="/Download/myshapefile"
val spatialRDD = ShapefileReader.readToGeometryRDD(sedona.sparkContext, shapefileInputLocation)
String shapefileInputLocation="/Download/myshapefile"
SpatialRDD spatialRDD = ShapefileReader.readToGeometryRDD(sedona.sparkContext, shapefileInputLocation)
from sedona.core.formatMapper.shapefileParser import ShapefileReader
ShapefileReader.readToGeometryRDD(sc, shape_file_location)
Note
The path to the shapefile is the path to the folder that contains the .shp file, not the path to the .shp file itself. The file extensions of .shp, .shx, .dbf must be in lowercase. Assume you have a shape file called myShapefile, the path should be XXX/myShapefile
. The file structure should be like this:
- shapefile1
- shapefile2
- myshapefile
- myshapefile.shp
- myshapefile.shx
- myshapefile.dbf
- myshapefile...
- ...
If the file you are reading contains non-ASCII characters you'll need to explicitly set the encoding
via sedona.global.charset
system property before creating your Spark context.
Example:
System.setProperty("sedona.global.charset", "utf8")
val sc = new SparkContext(...)
From SedonaSQL DataFrame¶
Note
More details about SedonaSQL, please read the SedonaSQL tutorial.
To create a generic SpatialRDD from CSV, TSV, WKT, WKB and GeoJSON input formats, you can use SedonaSQL.
We use checkin.csv CSV file as the example. You can create a generic SpatialRDD using the following steps:
- Load data in SedonaSQL.
var df = sedona.read.format("csv").option("header", "false").load(csvPointInputLocation) df.createOrReplaceTempView("inputtable")
- Create a Geometry type column in SedonaSQL
var spatialDf = sedona.sql( """ |SELECT ST_Point(CAST(inputtable._c0 AS Decimal(24,20)),CAST(inputtable._c1 AS Decimal(24,20))) AS checkin |FROM inputtable """.stripMargin)
- Use SedonaSQL DataFrame-RDD Adapter to convert a DataFrame to an SpatialRDD
var spatialRDD = Adapter.toSpatialRdd(spatialDf, "checkin")
"checkin" is the name of the geometry column
For WKT/WKB/GeoJSON data, please use ST_GeomFromWKT / ST_GeomFromWKB / ST_GeomFromGeoJSON instead.
Transform the Coordinate Reference System¶
Sedona doesn't control the coordinate unit (degree-based or meter-based) of all geometries in an SpatialRDD. The unit of all related distances in Sedona is same as the unit of all geometries in an SpatialRDD.
By default, this function uses lon/lat order since v1.5.0
. Before, it used lat/lon order. You can use spatialRDD.flipCoordinates to swap X and Y.
To convert Coordinate Reference System of an SpatialRDD, use the following code:
val sourceCrsCode = "epsg:4326" // WGS84, the most common degree-based CRS
val targetCrsCode = "epsg:3857" // The most common meter-based CRS
objectRDD.CRSTransform(sourceCrsCode, targetCrsCode, false)
String sourceCrsCode = "epsg:4326" // WGS84, the most common degree-based CRS
String targetCrsCode = "epsg:3857" // The most common meter-based CRS
objectRDD.CRSTransform(sourceCrsCode, targetCrsCode, false)
sourceCrsCode = "epsg:4326" // WGS84, the most common degree-based CRS
targetCrsCode = "epsg:3857" // The most common meter-based CRS
objectRDD.CRSTransform(sourceCrsCode, targetCrsCode, False)
false
in CRSTransform(sourceCrsCode, targetCrsCode, false) means that it will not tolerate Datum shift. If you want it to be lenient, use true
instead.
Warning
CRS transformation should be done right after creating each SpatialRDD, otherwise it will lead to wrong query results. For instance, use something like this:
val objectRDD = WktReader.readToGeometryRDD(sedona.sparkContext, inputLocation, wktColumn, allowTopologyInvalidGeometries, skipSyntaxInvalidGeometries)
objectRDD.CRSTransform("epsg:4326", "epsg:3857", false)
SpatialRDD objectRDD = WktReader.readToGeometryRDD(sedona.sparkContext, inputLocation, wktColumn, allowTopologyInvalidGeometries, skipSyntaxInvalidGeometries)
objectRDD.CRSTransform("epsg:4326", "epsg:3857", false)
objectRDD = WktReader.readToGeometryRDD(sedona.sparkContext, inputLocation, wktColumn, allowTopologyInvalidGeometries, skipSyntaxInvalidGeometries)
objectRDD.CRSTransform("epsg:4326", "epsg:3857", False)
The details CRS information can be found on EPSG.io
Read other attributes in an SpatialRDD¶
Each SpatialRDD can carry non-spatial attributes such as price, age and name.
The other attributes are combined together to a string and stored in UserData field of each geometry.
To retrieve the UserData field, use the following code:
val rddWithOtherAttributes = objectRDD.rawSpatialRDD.rdd.map[String](f=>f.getUserData.asInstanceOf[String])
SpatialRDD<Geometry> spatialRDD = Adapter.toSpatialRdd(spatialDf, "arealandmark");
spatialRDD.rawSpatialRDD.map(obj -> {return obj.getUserData();});
rdd_with_other_attributes = object_rdd.rawSpatialRDD.map(lambda x: x.getUserData())
Write a Spatial Range Query¶
A spatial range query takes as input a range query window and an SpatialRDD and returns all geometries that have specified relationship with the query window.
Assume you now have an SpatialRDD (typed or generic). You can use the following code to issue an Spatial Range Query on it.
spatialPredicate can be set to SpatialPredicate.INTERSECTS
to return all geometries intersect with query window. Supported spatial predicates are:
CONTAINS
: geometry is completely inside the query windowINTERSECTS
: geometry have at least one point in common with the query windowWITHIN
: geometry is completely within the query window (no touching edges)COVERS
: query window has no point outside of the geometryCOVERED_BY
: geometry has no point outside of the query windowOVERLAPS
: geometry and the query window spatially overlapCROSSES
: geometry and the query window spatially crossTOUCHES
: the only points shared between geometry and the query window are on the boundary of geometry and the query windowEQUALS
: geometry and the query window are spatially equal
Note
Spatial range query is equivalent with a SELECT query with spatial predicate as search condition in Spatial SQL. An example query is as follows:
SELECT *
FROM checkin
WHERE ST_Intersects(checkin.location, queryWindow)
val rangeQueryWindow = new Envelope(-90.01, -80.01, 30.01, 40.01)
val spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by the window
val usingIndex = false
var queryResult = RangeQuery.SpatialRangeQuery(spatialRDD, rangeQueryWindow, spatialPredicate, usingIndex)
Envelope rangeQueryWindow = new Envelope(-90.01, -80.01, 30.01, 40.01)
SpatialPredicate spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by the window
boolean usingIndex = false
JavaRDD queryResult = RangeQuery.SpatialRangeQuery(spatialRDD, rangeQueryWindow, spatialPredicate, usingIndex)
from sedona.core.geom.envelope import Envelope
from sedona.core.spatialOperator import RangeQuery
range_query_window = Envelope(-90.01, -80.01, 30.01, 40.01)
consider_boundary_intersection = False ## Only return gemeotries fully covered by the window
using_index = False
query_result = RangeQuery.SpatialRangeQuery(spatial_rdd, range_query_window, consider_boundary_intersection, using_index)
Note
Sedona Python users: Please use RangeQueryRaw from the same module if you want to avoid jvm python serde while converting to Spatial DataFrame. It takes the same parameters as RangeQuery but returns reference to jvm rdd which can be converted to dataframe without python - jvm serde using Adapter.
Example:
from sedona.core.geom.envelope import Envelope
from sedona.core.spatialOperator import RangeQueryRaw
from sedona.utils.adapter import Adapter
range_query_window = Envelope(-90.01, -80.01, 30.01, 40.01)
consider_boundary_intersection = False ## Only return gemeotries fully covered by the window
using_index = False
query_result = RangeQueryRaw.SpatialRangeQuery(spatial_rdd, range_query_window, consider_boundary_intersection, using_index)
gdf = Adapter.toDf(query_result, spark, ["col1", ..., "coln"])
Range query window¶
Besides the rectangle (Envelope) type range query window, Sedona range query window can be Point/Polygon/LineString.
The code to create a point, linestring (4 vertices) and polygon (4 vertices) is as follows:
val geometryFactory = new GeometryFactory()
val pointObject = geometryFactory.createPoint(new Coordinate(-84.01, 34.01))
val geometryFactory = new GeometryFactory()
val coordinates = new Array[Coordinate](5)
coordinates(0) = new Coordinate(0,0)
coordinates(1) = new Coordinate(0,4)
coordinates(2) = new Coordinate(4,4)
coordinates(3) = new Coordinate(4,0)
coordinates(4) = coordinates(0) // The last coordinate is the same as the first coordinate in order to compose a closed ring
val polygonObject = geometryFactory.createPolygon(coordinates)
val geometryFactory = new GeometryFactory()
val coordinates = new Array[Coordinate](4)
coordinates(0) = new Coordinate(0,0)
coordinates(1) = new Coordinate(0,4)
coordinates(2) = new Coordinate(4,4)
coordinates(3) = new Coordinate(4,0)
val linestringObject = geometryFactory.createLineString(coordinates)
GeometryFactory geometryFactory = new GeometryFactory()
Point pointObject = geometryFactory.createPoint(new Coordinate(-84.01, 34.01))
GeometryFactory geometryFactory = new GeometryFactory()
Coordinate[] coordinates = new Array[Coordinate](5)
coordinates(0) = new Coordinate(0,0)
coordinates(1) = new Coordinate(0,4)
coordinates(2) = new Coordinate(4,4)
coordinates(3) = new Coordinate(4,0)
coordinates(4) = coordinates(0) // The last coordinate is the same as the first coordinate in order to compose a closed ring
Polygon polygonObject = geometryFactory.createPolygon(coordinates)
GeometryFactory geometryFactory = new GeometryFactory()
val coordinates = new Array[Coordinate](4)
coordinates(0) = new Coordinate(0,0)
coordinates(1) = new Coordinate(0,4)
coordinates(2) = new Coordinate(4,4)
coordinates(3) = new Coordinate(4,0)
LineString linestringObject = geometryFactory.createLineString(coordinates)
A Shapely geometry can be used as a query window. To create shapely geometries, please follow Shapely official docs
Use spatial indexes¶
Sedona provides two types of spatial indexes, Quad-Tree and R-Tree. Once you specify an index type, Sedona will build a local tree index on each of the SpatialRDD partition.
To utilize a spatial index in a spatial range query, use the following code:
val rangeQueryWindow = new Envelope(-90.01, -80.01, 30.01, 40.01)
val spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by the window
val buildOnSpatialPartitionedRDD = false // Set to TRUE only if run join query
spatialRDD.buildIndex(IndexType.QUADTREE, buildOnSpatialPartitionedRDD)
val usingIndex = true
var queryResult = RangeQuery.SpatialRangeQuery(spatialRDD, rangeQueryWindow, spatialPredicate, usingIndex)
Envelope rangeQueryWindow = new Envelope(-90.01, -80.01, 30.01, 40.01)
SpatialPredicate spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by the window
boolean buildOnSpatialPartitionedRDD = false // Set to TRUE only if run join query
spatialRDD.buildIndex(IndexType.QUADTREE, buildOnSpatialPartitionedRDD)
boolean usingIndex = true
JavaRDD queryResult = RangeQuery.SpatialRangeQuery(spatialRDD, rangeQueryWindow, spatialPredicate, usingIndex)
from sedona.core.geom.envelope import Envelope
from sedona.core.enums import IndexType
from sedona.core.spatialOperator import RangeQuery
range_query_window = Envelope(-90.01, -80.01, 30.01, 40.01)
consider_boundary_intersection = False ## Only return gemeotries fully covered by the window
build_on_spatial_partitioned_rdd = False ## Set to TRUE only if run join query
spatial_rdd.buildIndex(IndexType.QUADTREE, build_on_spatial_partitioned_rdd)
using_index = True
query_result = RangeQuery.SpatialRangeQuery(
spatial_rdd,
range_query_window,
consider_boundary_intersection,
using_index
)
Tip
Using an index might not be the best choice all the time because building index also takes time. A spatial index is very useful when your data is complex polygons and line strings.
Output format¶
The output format of the spatial range query is another SpatialRDD.
The output format of the spatial range query is another RDD which consists of GeoData objects.
SpatialRangeQuery result can be used as RDD with map or other spark RDD functions. Also it can be used as Python objects when using collect method. Example:
query_result.map(lambda x: x.geom.length).collect()
[
1.5900840000000045,
1.5906639999999896,
1.1110299999999995,
1.1096700000000084,
1.1415619999999933,
1.1386399999999952,
1.1415619999999933,
1.1418860000000137,
1.1392780000000045,
...
]
Or transformed to GeoPandas GeoDataFrame
import geopandas as gpd
gpd.GeoDataFrame(
query_result.map(lambda x: [x.geom, x.userData]).collect(),
columns=["geom", "user_data"],
geometry="geom"
)
Write a Spatial KNN Query¶
A spatial K Nearnest Neighbor query takes as input a K, a query point and an SpatialRDD and finds the K geometries in the RDD which are the closest to he query point.
Assume you now have an SpatialRDD (typed or generic). You can use the following code to issue an Spatial KNN Query on it.
val geometryFactory = new GeometryFactory()
val pointObject = geometryFactory.createPoint(new Coordinate(-84.01, 34.01))
val K = 1000 // K Nearest Neighbors
val usingIndex = false
val result = KNNQuery.SpatialKnnQuery(objectRDD, pointObject, K, usingIndex)
GeometryFactory geometryFactory = new GeometryFactory()
Point pointObject = geometryFactory.createPoint(new Coordinate(-84.01, 34.01))
int K = 1000 // K Nearest Neighbors
boolean usingIndex = false
JavaRDD result = KNNQuery.SpatialKnnQuery(objectRDD, pointObject, K, usingIndex)
from sedona.core.spatialOperator import KNNQuery
from shapely.geometry import Point
point = Point(-84.01, 34.01)
k = 1000 ## K Nearest Neighbors
using_index = False
result = KNNQuery.SpatialKnnQuery(object_rdd, point, k, using_index)
Note
Spatial KNN query that returns 5 Nearest Neighbors is equal to the following statement in Spatial SQL
SELECT ck.name, ck.rating, ST_Distance(ck.location, myLocation) AS distance
FROM checkins ck
ORDER BY distance DESC
LIMIT 5
Query center geometry¶
Besides the Point type, Sedona KNN query center can be Polygon and LineString.
To learn how to create Polygon and LineString object, see Range query window.
To create Polygon or Linestring object please follow Shapely official docs
Use spatial indexes¶
To utilize a spatial index in a spatial KNN query, use the following code:
val geometryFactory = new GeometryFactory()
val pointObject = geometryFactory.createPoint(new Coordinate(-84.01, 34.01))
val K = 1000 // K Nearest Neighbors
val buildOnSpatialPartitionedRDD = false // Set to TRUE only if run join query
objectRDD.buildIndex(IndexType.RTREE, buildOnSpatialPartitionedRDD)
val usingIndex = true
val result = KNNQuery.SpatialKnnQuery(objectRDD, pointObject, K, usingIndex)
GeometryFactory geometryFactory = new GeometryFactory()
Point pointObject = geometryFactory.createPoint(new Coordinate(-84.01, 34.01))
val K = 1000 // K Nearest Neighbors
boolean buildOnSpatialPartitionedRDD = false // Set to TRUE only if run join query
objectRDD.buildIndex(IndexType.RTREE, buildOnSpatialPartitionedRDD)
boolean usingIndex = true
JavaRDD result = KNNQuery.SpatialKnnQuery(objectRDD, pointObject, K, usingIndex)
from sedona.core.spatialOperator import KNNQuery
from sedona.core.enums import IndexType
from shapely.geometry import Point
point = Point(-84.01, 34.01)
k = 5 ## K Nearest Neighbors
build_on_spatial_partitioned_rdd = False ## Set to TRUE only if run join query
spatial_rdd.buildIndex(IndexType.RTREE, build_on_spatial_partitioned_rdd)
using_index = True
result = KNNQuery.SpatialKnnQuery(spatial_rdd, point, k, using_index)
Warning
Only R-Tree index supports Spatial KNN query
Output format¶
The output format of the spatial KNN query is a list of geometries. The list has K geometry objects.
The output format of the spatial KNN query is a list of GeoData objects. The list has K GeoData objects.
Example:
>> result
[GeoData, GeoData, GeoData, GeoData, GeoData]
Write a Spatial Join Query¶
A spatial join query takes as input two Spatial RDD A and B. For each geometry in A, finds the geometries (from B) covered/intersected by it. A and B can be any geometry type and are not necessary to have the same geometry type.
Assume you now have two SpatialRDDs (typed or generic). You can use the following code to issue an Spatial Join Query on them.
val spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by each query window in queryWindowRDD
val usingIndex = false
objectRDD.analyze()
objectRDD.spatialPartitioning(GridType.KDBTREE)
queryWindowRDD.spatialPartitioning(objectRDD.getPartitioner)
val result = JoinQuery.SpatialJoinQuery(objectRDD, queryWindowRDD, usingIndex, spatialPredicate)
SpatialPredicate spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by each query window in queryWindowRDD
val usingIndex = false
objectRDD.analyze()
objectRDD.spatialPartitioning(GridType.KDBTREE)
queryWindowRDD.spatialPartitioning(objectRDD.getPartitioner)
JavaPairRDD result = JoinQuery.SpatialJoinQuery(objectRDD, queryWindowRDD, usingIndex, spatialPredicate)
from sedona.core.enums import GridType
from sedona.core.spatialOperator import JoinQuery
consider_boundary_intersection = False ## Only return geometries fully covered by each query window in queryWindowRDD
using_index = False
object_rdd.analyze()
object_rdd.spatialPartitioning(GridType.KDBTREE)
query_window_rdd.spatialPartitioning(object_rdd.getPartitioner())
result = JoinQuery.SpatialJoinQuery(object_rdd, query_window_rdd, using_index, consider_boundary_intersection)
Note
Spatial join query is equal to the following query in Spatial SQL:
SELECT superhero.name
FROM city, superhero
WHERE ST_Contains(city.geom, superhero.geom);
Use spatial partitioning¶
Sedona spatial partitioning method can significantly speed up the join query. Three spatial partitioning methods are available: KDB-Tree, Quad-Tree and R-Tree. Two SpatialRDD must be partitioned by the same way.
If you first partition SpatialRDD A, then you must use the partitioner of A to partition B.
objectRDD.spatialPartitioning(GridType.KDBTREE)
queryWindowRDD.spatialPartitioning(objectRDD.getPartitioner)
object_rdd.spatialPartitioning(GridType.KDBTREE)
query_window_rdd.spatialPartitioning(object_rdd.getPartitioner())
Or
queryWindowRDD.spatialPartitioning(GridType.KDBTREE)
objectRDD.spatialPartitioning(queryWindowRDD.getPartitioner)
query_window_rdd.spatialPartitioning(GridType.KDBTREE)
object_rdd.spatialPartitioning(query_window_rdd.getPartitioner())
Use spatial indexes¶
To utilize a spatial index in a spatial join query, use the following code:
objectRDD.spatialPartitioning(joinQueryPartitioningType)
queryWindowRDD.spatialPartitioning(objectRDD.getPartitioner)
val buildOnSpatialPartitionedRDD = true // Set to TRUE only if run join query
val usingIndex = true
queryWindowRDD.buildIndex(IndexType.QUADTREE, buildOnSpatialPartitionedRDD)
val result = JoinQuery.SpatialJoinQueryFlat(objectRDD, queryWindowRDD, usingIndex, spatialPredicate)
objectRDD.spatialPartitioning(joinQueryPartitioningType)
queryWindowRDD.spatialPartitioning(objectRDD.getPartitioner)
boolean buildOnSpatialPartitionedRDD = true // Set to TRUE only if run join query
boolean usingIndex = true
queryWindowRDD.buildIndex(IndexType.QUADTREE, buildOnSpatialPartitionedRDD)
JavaPairRDD result = JoinQuery.SpatialJoinQueryFlat(objectRDD, queryWindowRDD, usingIndex, spatialPredicate)
from sedona.core.enums import GridType
from sedona.core.enums import IndexType
from sedona.core.spatialOperator import JoinQuery
object_rdd.spatialPartitioning(GridType.KDBTREE)
query_window_rdd.spatialPartitioning(object_rdd.getPartitioner())
build_on_spatial_partitioned_rdd = True ## Set to TRUE only if run join query
using_index = True
query_window_rdd.buildIndex(IndexType.QUADTREE, build_on_spatial_partitioned_rdd)
result = JoinQuery.SpatialJoinQueryFlat(object_rdd, query_window_rdd, using_index, True)
The index should be built on either one of two SpatialRDDs. In general, you should build it on the larger SpatialRDD.
Output format¶
The output format of the spatial join query is a PairRDD. In this PairRDD, each object is a pair of two geometries. The left one is the geometry from objectRDD and the right one is the geometry from the queryWindowRDD.
Point,Polygon
Point,Polygon
Point,Polygon
Polygon,Polygon
LineString,LineString
Polygon,LineString
...
Each object on the left is covered/intersected by the object on the right.
Result for this query is RDD which holds two GeoData objects within list of lists. Example:
result.collect()
[[GeoData, GeoData], [GeoData, GeoData] ...]
It is possible to do some RDD operation on result data ex. Getting polygon centroid.
result.map(lambda x: x[0].geom.centroid).collect()
Note
Sedona Python users: Please use JoinQueryRaw from the same module for methods
-
spatialJoin
-
DistanceJoinQueryFlat
-
SpatialJoinQueryFlat
For better performance while converting to dataframe with adapter. That approach allows to avoid costly serialization between Python and jvm and in result operating on python object instead of native geometries.
Example:
from sedona.core.SpatialRDD import CircleRDD
from sedona.core.enums import GridType
from sedona.core.spatialOperator import JoinQueryRaw
object_rdd.analyze()
circle_rdd = CircleRDD(object_rdd, 0.1) ## Create a CircleRDD using the given distance
circle_rdd.analyze()
circle_rdd.spatialPartitioning(GridType.KDBTREE)
spatial_rdd.spatialPartitioning(circle_rdd.getPartitioner())
consider_boundary_intersection = False ## Only return gemeotries fully covered by each query window in queryWindowRDD
using_index = False
result = JoinQueryRaw.DistanceJoinQueryFlat(spatial_rdd, circle_rdd, using_index, consider_boundary_intersection)
gdf = Adapter.toDf(result, ["left_col1", ..., "lefcoln"], ["rightcol1", ..., "rightcol2"], spark)
Write a Distance Join Query¶
Warning
RDD distance joins are only reliable for points. For other geometry types, please use Spatial SQL.
A distance join query takes as input two Spatial RDD A and B and a distance. For each geometry in A, finds the geometries (from B) are within the given distance to it. A and B can be any geometry type and are not necessary to have the same geometry type. The unit of the distance is explained here.
If you don't want to transform your data and are ok with sacrificing the query accuracy, you can use an approximate degree value for distance. Please use this calculator.
Assume you now have two SpatialRDDs (typed or generic). You can use the following code to issue an Distance Join Query on them.
objectRddA.analyze()
val circleRDD = new CircleRDD(objectRddA, 0.1) // Create a CircleRDD using the given distance
circleRDD.spatialPartitioning(GridType.KDBTREE)
objectRddB.spatialPartitioning(circleRDD.getPartitioner)
val spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by each query window in queryWindowRDD
val usingIndex = false
val result = JoinQuery.DistanceJoinQueryFlat(objectRddB, circleRDD, usingIndex, spatialPredicate)
objectRddA.analyze()
CircleRDD circleRDD = new CircleRDD(objectRddA, 0.1) // Create a CircleRDD using the given distance
circleRDD.spatialPartitioning(GridType.KDBTREE)
objectRddB.spatialPartitioning(circleRDD.getPartitioner)
SpatialPredicate spatialPredicate = SpatialPredicate.COVERED_BY // Only return gemeotries fully covered by each query window in queryWindowRDD
boolean usingIndex = false
JavaPairRDD result = JoinQuery.DistanceJoinQueryFlat(objectRddB, circleRDD, usingIndex, spatialPredicate)
from sedona.core.SpatialRDD import CircleRDD
from sedona.core.enums import GridType
from sedona.core.spatialOperator import JoinQuery
object_rdd.analyze()
circle_rdd = CircleRDD(object_rdd, 0.1) ## Create a CircleRDD using the given distance
circle_rdd.analyze()
circle_rdd.spatialPartitioning(GridType.KDBTREE)
spatial_rdd.spatialPartitioning(circle_rdd.getPartitioner())
consider_boundary_intersection = False ## Only return gemeotries fully covered by each query window in queryWindowRDD
using_index = False
result = JoinQuery.DistanceJoinQueryFlat(spatial_rdd, circle_rdd, using_index, consider_boundary_intersection)
Distance join can only accept COVERED_BY
and INTERSECTS
as spatial predicates. The rest part of the join query is same as the spatial join query.
The details of spatial partitioning in join query is here.
The details of using spatial indexes in join query is here.
The output format of the distance join query is here.
Note
Distance join query is equal to the following query in Spatial SQL:
SELECT superhero.name
FROM city, superhero
WHERE ST_Distance(city.geom, superhero.geom) <= 10;
Save to permanent storage¶
You can always save an SpatialRDD back to some permanent storage such as HDFS and Amazon S3. You can save distributed SpatialRDD to WKT, GeoJSON and object files.
Note
Non-spatial attributes such as price, age and name will also be stored to permanent storage.
Save an SpatialRDD (not indexed)¶
Typed SpatialRDD and generic SpatialRDD can be saved to permanent storage.
Save to distributed WKT text file¶
Use the following code to save an SpatialRDD as a distributed WKT text file:
objectRDD.rawSpatialRDD.saveAsTextFile("hdfs://PATH")
objectRDD.saveAsWKT("hdfs://PATH")
Save to distributed WKB text file¶
Use the following code to save an SpatialRDD as a distributed WKB text file:
objectRDD.saveAsWKB("hdfs://PATH")
Save to distributed GeoJSON text file¶
Use the following code to save an SpatialRDD as a distributed GeoJSON text file:
objectRDD.saveAsGeoJSON("hdfs://PATH")
Save to distributed object file¶
Use the following code to save an SpatialRDD as a distributed object file:
objectRDD.rawSpatialRDD.saveAsObjectFile("hdfs://PATH")
object_rdd.rawJvmSpatialRDD.saveAsObjectFile("hdfs://PATH")
Note
Each object in a distributed object file is a byte array (not human-readable). This byte array is the serialized format of a Geometry or a SpatialIndex.
Save an SpatialRDD (indexed)¶
Indexed typed SpatialRDD and generic SpatialRDD can be saved to permanent storage. However, the indexed SpatialRDD has to be stored as a distributed object file.
Save to distributed object file¶
Use the following code to save an SpatialRDD as a distributed object file:
objectRDD.indexedRawRDD.saveAsObjectFile("hdfs://PATH")
Save an SpatialRDD (spatialPartitioned W/O indexed)¶
A spatial partitioned RDD can be saved to permanent storage but Spark is not able to maintain the same RDD partition Id of the original RDD. This will lead to wrong join query results. We are working on some solutions. Stay tuned!
Reload a saved SpatialRDD¶
You can easily reload an SpatialRDD that has been saved to a distributed object file.
Load to a typed SpatialRDD¶
Warning
Typed SpatialRDD has been deprecated for a long time. We do NOT recommend it anymore.
Load to a generic SpatialRDD¶
Use the following code to reload the SpatialRDD:
var savedRDD = new SpatialRDD[Geometry]
savedRDD.rawSpatialRDD = sc.objectFile[Geometry]("hdfs://PATH")
SpatialRDD savedRDD = new SpatialRDD<Geometry>
savedRDD.rawSpatialRDD = sc.objectFile<Geometry>("hdfs://PATH")
saved_rdd = load_spatial_rdd_from_disc(sc, "hdfs://PATH", GeoType.GEOMETRY)
Use the following code to reload the indexed SpatialRDD:
var savedRDD = new SpatialRDD[Geometry]
savedRDD.indexedRawRDD = sc.objectFile[SpatialIndex]("hdfs://PATH")
SpatialRDD savedRDD = new SpatialRDD<Geometry>
savedRDD.indexedRawRDD = sc.objectFile<SpatialIndex>("hdfs://PATH")
saved_rdd = SpatialRDD()
saved_rdd.indexedRawRDD = load_spatial_index_rdd_from_disc(sc, "hdfs://PATH")