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Geospatial Data - Kotlin SDK

On this page

  • Geospatial Data Types
  • GeoPoint
  • GeoCircle
  • GeoBox
  • GeoPolygon
  • Persist Geospatial Data
  • Create a GeoJSON-Compatible Class
  • Use the Embedded Class
  • Query Geospatial Data
  • GeoCircle
  • GeoBox
  • GeoPolygon

New in version 1.11.0.

Geospatial data, or "geodata", specifies points and geometric objects on the Earth's surface.

Kotlin SDK version 1.11.0 and later adds experimental geospatial APIs that support querying with geospatial data. These queries can check whether a given point is contained within a shape. For example, you can find all coffee shops within 15 km of a specified point.

Changed in version 1.13.0: Geospatial data supported in Atlas Device Sync

Kotlin SDK version 1.13.0 and later adds support for geospatial data in Atlas Device Sync. This allows you to subscribe to geospatial queries in a synced realm. If you try to subscribe to a geospatial query with an older version of the SDK, you will receive a server error with a compensating write.

For more information about managing your Sync subscriptions, refer to Manage Sync Subscriptions - Kotlin SDK.

For more information on querying geospatial data with Device Sync, refer to Geospatial Data in the App Services documentation.

The Kotlin SDK supports geospatial queries using the following data types:

  • GeoPoint

  • GeoCircle

  • GeoBox

  • GeoPolygon

The SDK provides these geospatial data types to simplify querying geospatial data. You cannot persist these data types directly.

For information on how to persist geospatial data, refer to the Persist Geospatial Data section on this page.

A GeoPoint defines a specific location on the Earth's surface. All of the geospatial data types use GeoPoints to define their location.

A GeoCircle defines a circle on the Earth's surface. You define a GeoCircle by providing a GeoPoint for the center of the circle and a Distance object to specify the radius of the circle.

Note

You can define the radius in kilometers, miles, degrees, or radians.

The following example creates 2 circles:

val circle1 = GeoCircle.create(
center = GeoPoint.create(47.8, -122.6),
radius = Distance.fromKilometers(44.4)
)
val circle2 = GeoCircle.create(
center = GeoPoint.create(47.3, -121.9),
radius = Distance.fromDegrees(0.25)
)
Two GeoCircles
click to enlarge

A GeoBox defines a rectangle on the Earth's surface. You define the rectangle by specifying the bottom left (southwest) corner and the top right (northeast) corner.

The following example creates 2 boxes:

val box1 = GeoBox.create(
bottomLeft = GeoPoint.create(47.3, -122.7),
topRight = GeoPoint.create(48.1, -122.1)
)
val box2 = GeoBox.create(
bottomLeft = GeoPoint.create(47.5, -122.4),
topRight = GeoPoint.create(47.9, -121.8)
)
2 GeoBoxes
click to enlarge

A GeoPolygon defines a polygon on the Earth's surface.

Because a polygon is a closed shape, you must provide a minimum of 4 points: 3 points to define the polygon's shape and a fourth to close the shape.

Important

The fourth point in a polygon must be the same as the first point.

You can also exclude areas within a polygon by defining one or more "holes". A hole is another polygon whose bounds fit completely within the outer polygon. Holes can also be nested within each other. A location is considered inside the polygon if it is included in an odd number of rings.

The following example creates 3 polygons:

  • A basic polygon with 5 points

  • The same polygon with a single hole

  • The same polygon with two holes

// Create a basic polygon
val basicPolygon = GeoPolygon.create(
listOf(
GeoPoint.create(48.0, -122.8),
GeoPoint.create(48.2, -121.8),
GeoPoint.create(47.6, -121.6),
GeoPoint.create(47.0, -122.0),
GeoPoint.create(47.2, -122.6),
GeoPoint.create(48.0, -122.8)
)
)
// Create a polygon with a single hole
val outerRing = listOf(
GeoPoint.create(48.0, -122.8),
GeoPoint.create(48.2, -121.8),
GeoPoint.create(47.6, -121.6),
GeoPoint.create(47.0, -122.0),
GeoPoint.create(47.2, -122.6),
GeoPoint.create(48.0, -122.8)
)
val hole1 = listOf(
GeoPoint.create(47.8, -122.6),
GeoPoint.create(47.7, -122.2),
GeoPoint.create(47.4, -122.6),
GeoPoint.create(47.6, -122.5),
GeoPoint.create(47.8, -122.6)
)
val polygonWithOneHole = GeoPolygon.create(outerRing, hole1)
// Add a second hole to the polygon
val hole2 = listOf(
GeoPoint.create(47.55, -122.05),
GeoPoint.create(47.5, -121.9),
GeoPoint.create(47.3, -122.1),
GeoPoint.create(47.55, -122.05)
)
val polygonWithTwoHoles = GeoPolygon.create(outerRing, hole1, hole2)
3 GeoPolygons
click to enlarge

Important

Cannot Persist Geospatial Data Types

Currently, you can only persist geospatial data. Geospatial data types cannot be persisted directly. For example, you can't declare a property that is of type GeoBox.

These types can only be used as arguments for geospatial queries.

If you want to persist geospatial data, it must conform to the GeoJSON spec.

To do this with the Kotlin SDK, you can create a GeoJSON-compatible embedded class that you can then use in your data model.

To create a class that conforms to the GeoJSON spec, you:

  1. Create an embedded realm object (a class that inherits from EmbeddedRealmObject).

  2. At a minimum, add the two fields required by the GeoJSON spec:

    • A field of type String property that maps to a type property with the value of "Point": var type: String = "Point"

    • A field of type RealmList<Double> that maps to a coordinates property in the realm schema containing a latitude/longitude pair: var coordinates: RealmList<Double> = realmListOf()

The following example shows an embedded class named CustomGeoPoint that is used to persist geospatial data:

class CustomGeoPoint : EmbeddedRealmObject {
constructor(latitude: Double, longitude: Double) {
coordinates.apply {
add(longitude)
add(latitude)
}
}
// Empty constructor required by Realm
constructor() : this(0.0, 0.0)
// Name and type required by Realm
var coordinates: RealmList<Double> = realmListOf()
// Name, type, and value required by Realm
private var type: String = "Point"
@Ignore
var latitude: Double
get() = coordinates[1]
set(value) {
coordinates[1] = value
}
@Ignore
var longitude: Double
get() = coordinates[0]
set(value) {
coordinates[0] = value
}
}

Use the customGeoPoint class in your realm model, as shown in the following example:

class Company : RealmObject {
@PrimaryKey
var _id: ObjectId = ObjectId()
var location: CustomGeoPoint? = null
}

You can then add instances of your class to the realm:

realm.writeBlocking {
copyToRealm(
Company().apply {
location = CustomGeoPoint(47.68, -122.35)
}
)
copyToRealm(
Company().apply {
location = CustomGeoPoint(47.9, -121.85)
}
)
}

The following image shows the results of creating these two Company objects:

2 GeoPoints
click to enlarge

To query against geospatial data, you can use the GEOWITHIN operator with RQL. This method takes the coordinates property of an embedded object and checks if that point is contained within the geospatial shape for that object.

The format for querying geospatial data is the same, regardless of the shape of the geodata region.

Important

You cannot use parameterized queries with geospatial data.

The following examples show querying against various shapes to return a list of companies within the shape.

val companiesInLargeCircle =
realm.query<Company>("location GEOWITHIN $circle1").find()
println("Companies in large circle: ${companiesInLargeCircle.size}")
val companiesInSmallCircle =
realm.query<Company>("location GEOWITHIN $circle2").find()
println("Companies in small circle: ${companiesInSmallCircle.size}")
Companies in large circle: 1
Companies in small circle: 0
Querying a GeoCircle example
click to enlarge
val companiesInLargeBox =
realm.query<Company>("location GEOWITHIN $box1").find()
println("Companies in large box: ${companiesInLargeBox.size}")
val companiesInSmallBox =
realm.query<Company>("location GEOWITHIN $box2").find()
println("Companies in small box: ${companiesInSmallBox.size}")
Companies in large box: 1
Companies in small box: 2
Querying a GeoBox example
val companiesInBasicPolygon =
realm.query<Company>("location GEOWITHIN $basicPolygon").find()
println("Companies in basic polygon: ${companiesInBasicPolygon.size}")
val companiesInPolygonWithHoles =
realm.query<Company>("location GEOWITHIN $polygonWithTwoHoles").find()
println("Companies in polygon with holes: ${companiesInPolygonWithHoles.size}")
Companies in basic polygon: 2
Companies in polygon with holes: 1
Querying a GeoPolygon example
click to enlarge
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