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Elasticsearch GeoServer Data Store

Elasticsearch is a popular distributed search and analytics engine that enables complex search features in near real-time. Default field type mappings support string, numeric, boolean and date types and allow complex, hierarchical documents. Custom field type mappings can be defined for geospatial document fields. The geo_point type supports point geometries that can be specified through a coordinate string, geohash or coordinate array. The geo_shape type supports Point, LineString, Polygon, MultiPoint, MultiLineString, MultiPolygon and GeometryCollection GeoJSON types as well as envelope and circle types. Custom options allow configuration of the type and precision of the spatial index.

This data store allows features from an Elasticsearch index to be published through GeoServer. Both geo_point and geo_shape type mappings are supported. OGC filters are converted to Elasticsearch queries and can be combined with native Elasticsearch queries in WMS and WFS requests.

  • Java: 1.8
  • GeoServer: 2.15.x
  • Elasticsearch: 2.4.x, 5.x, 6.x, 7.x

Pre-compiled binaries can be found on the GitHub releases page.

Unpack zipfile and copy plugin file to the WEB_INF/lib directory of your GeoServer installation and then restart GeoServer.

Clone project:

$ git clone [email protected]:ngageoint/elasticgeo.git

Build and install plugin (requires GeoServer restart):

$ mvn clean install -DskipTests=true -Dskip.integration.tests=true
$ cp gs-web-elasticsearch/target/elasticgeo*.jar GEOSERVER_HOME/WEB_INF/lib

Run default tests:

$ mvn verify -Dskip.integration.tests=true

Run default and integration tests (requires Docker):

$ mvn verify

Note running integration tests in an IDE development environment requires that a local Elasticsearch instance is running and accepting HTTP connections over port 9200 (see Elasticsearch documentation).

Once the Elasticsearch GeoServer extension is installed, Elasticsearch index will be an available vector data source format when creating a new data store.

new_store

The Elasticsearch data store configuration panel includes connection parameters and search settings.

Available data store configuration parameters are summarized in the following table:

Parameter Description
elasticsearch_host

Host (IP) for connecting to Elasticsearch. HTTP scheme and port can optionally be included to override the defaults. Multiple hosts can be provided. Examples:

localhost
localhost:9200
http://localhost
http://localhost:9200
https://localhost:9200
https://somehost.somedomain:9200,https://anotherhost.somedomain:9200
elasticsearch_port Default HTTP port for connecting to Elasticsearch. Ignored if the hostname includes the port.
user Elasticsearch user. Must have superuser privilege on index.
passwd Elasticsearch user password
runas_geoserver_user Whether to submit requests on behalf of the authenticated GeoServer user
proxy_user Elasticsearch user for document queries. If not provided then admin user credentials are used for all requests.
proxy_passwd Elasticsearch proxy user password
index_name Index name or alias (wildcards supported)
reject_unauthorized Whether to validate the server certificate during the SSL handshake for https connections
default_max_features Default used when maxFeatures is unlimited
source_filtering_enabled Whether to enable filtering of the _source field
scroll_enabled Enable the Elasticsearch scan and scroll API
scroll_size Number of documents per shard when using the scroll API
scroll_time Search context timeout when using the scroll API
array_encoding Array encoding strategy. Allowed values are JSON (keep arrays) and CSV (keep first array element).
grid_size Hint for Geohash grid size (numRows*numCols)
grid_threshold Geohash grid aggregation precision will be the minimum necessary so that actual_grid_size/grid_size > grid_threshold

Basic authentication is supported through the user and passwd credential parameters. The provided user must have superuser privilege on the index to enable the mapping and alias requests performed during store initialization. Optional proxy_user and proxy_passwd parameters can be used to specify an alternate user for document search (OGC service) requests. The proxy user can have restricted privileges on the index through document level security. If not provided the default user is used for all requests.

The runas_geoserver_user flag can be used to enable Elasticsearch requests to be submitted on behalf of the authenticated GeoServer user. When the run-as mechanism is configured the plugin will add the es-security-runas-user header with the authenticated GeoServer username. See X-Pack run-as documentation for more information. Note the run-as mechanism is applied only to document search requests.

For added security it is recommended to define proxy_user and proxy_passwd when using the run-as mechanism. The proxy user will be used when submitting requests on behalf of the GeoServer user and can have restricted privileges enabling access only to documents that all users can have access to. The plugin can optionally be deployed to require user credentials and proxy credentials and to force the use of runas_geoserver_user by setting the environment variable org.geoserver.elasticsearch.xpack.force-runas:

$ export JAVA_OPTS="-Dorg.geoserver.elasticsearch.xpack.force-runas $JAVA_OPTS"

System properties are supported for SSL/TLS configuration:

javax.net.ssl.trustStore
javax.net.ssl.trustStorePassword
javax.net.ssl.keyStore
javax.net.ssl.keyStorePassword

See HttpClientBuilder documentation for available properties.

For example use javax.net.ssl.trustStore[Password] to validate server certificate:

$ export JAVA_OPTS="-Djavax.net.ssl.trustStore=/path/to/truststore.jks -Djavax.net.ssl.trustStorePassword=changeme $JAVA_OPTS "

The initial layer configuration panel for an Elasticsearch layer will include an additional pop-up showing a table of available fields.

field_list
Item Description
Use All Use all fields in the layer feature type
Short Names For hierarchical documents with inner fields (e.g. parent.child.field_name), only use the base name (field_name) in the schema. Note, full path will always be included when the base name is duplicated across fields.
Use Used to select the fields that will make up the layer feature type
Name Name of the field
Type Type of the field, as derived from the Elasticsearch schema. For geometry types, you have the option to provide a more specific data type.
Order Integer order values are used to sort fields, where fields with smaller order are returned first
Custom Name Provides the option to give the field a custom name
Default Geometry Indicates if the geometry field is the default one. Useful if the documents contain more than one geometry field, as SLDs and spatial filters will hit the default geometry field unless otherwise specified
Stored Indicates whether the field is stored in the index
Analyzed Indicates whether the field is analyzed
SRID Native spatial reference ID of the geometries. Currently only EPSG:4326 is supported.
Date Format Date format used for parsing field values and printing filter elements

To return to the field table after it has been closed, click the "Configure Elasticsearch fields" button below the "Feature Type Details" panel on the layer configuration page.

field_list_edit

Logging is configurable through Log4j. The data store includes logging such as the query object being sent to Elasticsearch, which is logged at a lower level than may be enabled by default. To enable these logs, add the following lines to the GeoServer logging configuration file (see GeoServer Global Settings):

log4j.category.mil.nga.giat.data.elasticsearch=DEBUG
log4j.category.mil.nga.giat.process.elasticsearch=DEBUG

The logging configuration file will be in the logs subdirectory in the GeoServer data directory. Check GeoServer global settings for which file is being used (e.g. DEFAULT_LOGGING.properties, etc.).

logging

Filtering capabilities include OpenGIS simple comparisons, temporal comparisons, as well as other common filter comparisons. Elasticsearch natively supports numerous spatial filter operators, depending on the type:

  • geo_shape types natively support BBOX/Intersects, Within and Disjoint binary spatial operators
  • geo_point types natively support BBOX and Within binary spatial operators, as well as the DWithin and Beyond distance buffer operators

Requests involving spatial filter operators not natively supported by Elasticsearch will include an additional filtering operation on the results returned from the query, which may impact performance.

Native Elasticsearch queries can be applied in WFS/WMS feature requests by including the q:{query_body} key:value pair in the viewparams parameter (see GeoServer SQL Views documentation for more information). If supplied, the query is combined with the query derived from the request bbox, CQL or OGC filter using the AND logical binary operator.

BBOX and CQL filter:

http://localhost:8080/geoserver/test/wms?service=WMS&version=1.1.0&request=GetMap
     &layers=test:active&styles=&bbox=-1,-1,10,10&width=279&height=512
     &srs=EPSG:4326&format=application/openlayers&maxFeatures=1000
     &cql_filter=standard_ss='IEEE 802.11b'

BBOX and native query:

http://localhost:8080/geoserver/test/wms?service=WMS&version=1.1.0&request=GetMap
     &layers=test:active&styles=&bbox=-1,-1,10,10&width=279&height=512
     &srs=EPSG:4326&format=application/openlayers&maxFeatures=1000
     &viewparams=q:{"term":{"standard_ss":"IEEE 802.11b"}}

Native query with BBOX filter:

http://localhost:8080/geoserver/test/wms?service=WMS&version=1.1.0&request=GetMap
     &layers=test:active&styles=&bbox=-1,-1,10,10&width=279&height=512
     &srs=EPSG:4326&format=application/openlayers&maxFeatures=1000
     &viewparams=q:{"term":{"standard_ss":"IEEE 802.11b"}}

Note that commas in native queries must be escaped with a backslash.

Elasticsearch aggregations are supported through WFS/WMS requests by including the a:{aggregation_body} key:value pair in the viewparams parameter (see GeoServer SQL Views documentation for more information):

http://localhost:8080/geoserver/test/ows?service=WFS&version=1.0.0&request=GetFeature
     &typeName=test:active&bbox=0.0,0.0,24.0,44.0
     &viewparams=a:{"agg": {"geohash_grid": {"field": "geo"\, "precision": 3}}}

Aggregation WFS features will include a single attribute, _aggregation, containing the raw aggregation content. Note that size is set to zero when an aggregation is supplied so only aggregation features are returned (e.g. maxFeatures is ignored and there will be no search hit results). See FAQ for common issues using aggregations.

Geohash grid aggregation support includes dynamic precision updating and a custom rendering transformation for visualization. Geohash grid aggregation precision is updated dynamically to approximate the specified grid_size based on current bbox extent and the additional grid_threshold parameter as described above.

Geohash grid aggregation visualization is supported in WMS requests through a custom rendering transformation, vec:GeoHashGrid, which translates aggregation response data into a raster for display. By default raster values correspond to the aggregation bucket doc_count. The following shows an example GeoServer style that uses the GeoHashGrid rendering transformation:

<StyledLayerDescriptor version="1.0.0"
    xsi:schemaLocation="http://www.opengis.net/sld StyledLayerDescriptor.xsd"
    xmlns="http://www.opengis.net/sld"
    xmlns:ogc="http://www.opengis.net/ogc"
    xmlns:xlink="http://www.w3.org/1999/xlink"
    xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
  <NamedLayer>
    <Name>GeoHashGrid</Name>
    <UserStyle>
      <Title>GeoHashGrid</Title>
      <Abstract>GeoHashGrid aggregation</Abstract>
      <FeatureTypeStyle>
        <Transformation>
          <ogc:Function name="vec:GeoHashGrid">
            <ogc:Function name="parameter">
              <ogc:Literal>data</ogc:Literal>
            </ogc:Function>
            <ogc:Function name="parameter">
              <ogc:Literal>gridStrategy</ogc:Literal>
              <ogc:Literal>Basic</ogc:Literal>
            </ogc:Function>
            <ogc:Function name="parameter">
              <ogc:Literal>pixelsPerCell</ogc:Literal>
              <ogc:Literal>1</ogc:Literal>
            </ogc:Function>
            <ogc:Function name="parameter">
              <ogc:Literal>outputBBOX</ogc:Literal>
              <ogc:Function name="env">
                <ogc:Literal>wms_bbox</ogc:Literal>
              </ogc:Function>
            </ogc:Function>
            <ogc:Function name="parameter">
              <ogc:Literal>outputWidth</ogc:Literal>
              <ogc:Function name="env">
                <ogc:Literal>wms_width</ogc:Literal>
              </ogc:Function>
            </ogc:Function>
            <ogc:Function name="parameter">
              <ogc:Literal>outputHeight</ogc:Literal>
              <ogc:Function name="env">
                <ogc:Literal>wms_height</ogc:Literal>
              </ogc:Function>
            </ogc:Function>
          </ogc:Function>
        </Transformation>
        <Rule>
         <RasterSymbolizer>
           <Geometry>
             <!-- Actual geometry property name in feature source -->
             <ogc:PropertyName>geo</ogc:PropertyName></Geometry>
           <Opacity>0.6</Opacity>
           <ColorMap type="ramp" >
             <ColorMapEntry color="#FFFFFF" quantity="0" label="nodata" opacity="0"/>
             <ColorMapEntry color="#2851CC" quantity="1" label="values"/>
             <ColorMapEntry color="#211F1F" quantity="2" label="label"/>
             <ColorMapEntry color="#EE0F0F" quantity="3" label="label"/>
             <ColorMapEntry color="#AAAAAA" quantity="4" label="label"/>
             <ColorMapEntry color="#6FEE4F" quantity="5" label="label"/>
             <ColorMapEntry color="#DDB02C" quantity="10" label="label"/>
           </ColorMap>
         </RasterSymbolizer>
        </Rule>
      </FeatureTypeStyle>
    </UserStyle>
  </NamedLayer>
 </StyledLayerDescriptor>

Example WMS request including Geohash grid aggregation with the above custom style:

http://localhost:8080/geoserver/test/wms?service=WMS&version=1.1.0&request=GetMap
     &layers=test:active&styles=geohashgrid&bbox=0.0,0.0,24.0,44.0&srs=EPSG:4326
     &width=418&height=768&format=application/openlayers
     &viewparams=a:{"agg": {"geohash_grid": {"field": "geo"\, "precision": 3}}}

gridStrategy: Parameter to identify the mil.nga.giat.process.elasticsearch.GeoHashGrid implementation that will be used to convert each geohashgrid bucket into a raster value (number).

Name gridStrategy gridStrategyArgs Description
Basic basic no Raster value is geohashgrid bucket doc_count.
Metric metric yes Raster value is geohashgrid bucket metric value.
Nested nested_agg yes Extract raster value from nested aggregation results.

gridStrategyArgs: (Optional) Parameter used to specify an optional argument list for the grid strategy.

emptyCellValue: (Optional) Parameter used to specify the value for empty grid cells. By default, empty grid cells are set to 0.

scaleMin, scaleMax: (Optional) Parameters used to specify a scale applied to all raster values. Each tile request is scaled according to the min and max values for that tile. It is best to use a non-tiled layer with this parameter to avoid confusing results.

useLog: (Optional) Flag indicating whether to apply logarithm to raster values (applied prior to scaling, if applicable)

Raster value is geohashgrid bucket doc_count.

Example Aggregation:

{
  "agg": {
    "geohash_grid": {
      "field": "geo"
    }
  }
}

Example bucket:

{
  "key" : "xv",
  "doc_count" : 1
}

Extracted raster value: 1

Raster value is geohashgrid bucket metric value.

Argument Index Default Value Description
0 metric Key used to pluck metric object from top level bucket. Empty string results in plucking doc_count.
1 value Key used to pluck the value from the metric object.

Example Aggregation:

{
  "agg": {
    "geohash_grid": {
      "field": "geo"
    },
    "aggs": {
      "metric": {
        "max": {
          "field": "magnitude"
        }
      }
    }
  }
}

Example bucket:

{
  "key" : "xv",
  "doc_count" : 1,
  "metric" : {
    "value" : 4.9
  }
}

Extracted raster value: 4.9

Extract raster value from nested aggregation results.

Argument Index Default Value Description
0 nested Key used to pluck nested aggregation results from the geogrid bucket.
1 empty string Key used to pluck metric object from each nested aggregation bucket. Empty string results in plucking doc_count.
2 value Key used to pluck the value from the metric object.
3 largest largest | smallest. Strategy used to select a bucket from the nested aggregation buckets. The grid cell raster value is extracted from the selected bucket.
4 value key | value. Strategy used to extract the raster value from the selected bucket. value: Raster value is the selected bucket's metric value. key: Raster value is the selected bucket's key.
5 null (Optional) Map used to convert String keys into numeric values. Use the format key1:1;key2:2. Only utilized when raster strategy is key.

Example Aggregation:

{
  "agg": {
    "geohash_grid": {
      "field": "geo"
    },
    "aggs": {
      "nested": {
        "histogram": {
          "field": "magnitude",
          "interval": 1,
          "min_doc_count": 1
        }
      }
    }
  }
}

Example Parameters:

<ogc:Function name="parameter">
  <ogc:Literal>gridStrategyArgs</ogc:Literal>
  <ogc:Literal>nested</ogc:Literal>
  <ogc:Literal></ogc:Literal>
  <ogc:Literal></ogc:Literal>
  <ogc:Literal>largest</ogc:Literal>
  <ogc:Literal>key</ogc:Literal>
</ogc:Function>

Example bucket:

{
  "key" : "xv",
  "doc_count" : 1729,
  "nested" : {
    "buckets" : [
      {
        "key" : 2.0,
        "doc_count" : 5
      },
      {
        "key" : 3.0,
        "doc_count" : 107
      },
      {
        "key" : 4.0,
        "doc_count" : 1506
      },
      {
        "key" : 5.0,
        "doc_count" : 100
      },
      {
        "key" : 6.0,
        "doc_count" : 11
      }
    ]
  }
}

Extracted raster value: 4.0

By default the raster values computed in the geohash grid aggregation rendering transformation correspond to the top level doc_count. Adding an additional strategy for computing the raster values from bucket data currently requires source code updates to the gt-elasticsearch-process module as described below.

First create a custom implementation of mil.nga.giat.process.elasticsearch.GeoHashGrid and provide an implementation of the computeCellValue method, which takes the raw bucket data and returns the raster value. For example the default basic implementation simply returns the doc_count:

public class BasicGeoHashGrid extends GeoHashGrid {
    @Override
    public Number computeCellValue(Map<String,Object> bucket) {
        return (Number) bucket.get("doc_count");
    }
}

Then update mil.nga.giat.process.elasticsearch.GeoHashGridProcess and add a new entry to the Strategy enum to point to the custom implementation.

After deploying the customized plugin the new geohash grid computer can be used by updating the gridStrategy parameter in the GeoServer style:

<StyledLayerDescriptor version="1.0.0"
    ...
        <Transformation>
          <ogc:Function name="vec:GeoHashGrid">
            ...
            <ogc:Function name="parameter">
              <ogc:Literal>gridStrategy</ogc:Literal>
              <ogc:Literal>NewName</ogc:Literal>
            </ogc:Function>
  • By default arrays are returned directly, which is suitable for many output formats including GeoJSON. When using CSV output format with layers containing arrays it's necessary to set the array_encoding store parameter to CSV. Note however when using the CSV array encoding that only the first value will be returned.
  • When updating from pre-2.11.0 versions of the plugin it may be necessary to reload older layers to enable full aggregation and time support. Missing aggregation data or errors of the form IllegalArgumentException: Illegal pattern component indicate a layer reload is necessary. In this case the layer must be removed and re-added to GeoServer (e.g. a feature type reload will not be sufficient).
  • Commas in the native query and aggregation body must be escaped with a backslash. Additionally body may need to be URL encoded.
  • Geometry property name in the aggregation SLD RasterSymbolizer must be a valid geometry property in the layer
  • PropertyIsEqualTo maps to an Elasticsearch term query, which will return documents that contain the supplied term. When searching on an analyzed string field, ensure that the search values are consistent with the analyzer used in the index. For example, values may need to be lowercase when querying fields analyzed with the default analyzer. See the Elasticsearch term query documentation for more information.
  • PropertyIsLike maps to either a query string query or a regexp query, depending on whether the field is analyzed or not. Reserved characters should be escaped as applicable. Note case sensitive and insensitive searches may not be supported for analyzed and not analyzed fields, respectively. See Elasticsearch query string and regexp query documentation for more information.
  • Date conversions are handled using the date format from the associated type mapping, or date_optional_time if not found. Note that UTC timezone is used for both parsing and printing of dates.
  • Filtering on Elasticsearch object types is supported. By default, field names will include the full path to the field (e.g. "parent.child.field_name"), but this can be changed in the GeoServer layer configuration.
    • When referencing fields with path elements using cql_filter, it may be necessary to quote the name (e.g. cql_filter="parent.child.field_name"='value')
  • Filtering on Elasticsearch nested types is supported only for non-geospatial fields.
  • Circle geometries are approximate and may not be fully consistent with the implementation in Elasticsearch, especially at extreme latitudes (see #86).
  • The joda-shaded module may need to be excluded when importing the project into Eclipse. Otherwise modules may have build errors of the form DateTimeFormatter cannot be resolved to a type.