Tutorial¶
This tutorial demonstrates how to configure two complex feature types using the app-schema plugin and data from two property files.
GeoSciML¶
This example uses Geoscience Markup Language (GeoSciML) 2.0, a GML 3.1 application schema:
“GeoSciML is an application schema that specifies a set of feature-types and supporting structures for information used in the solid-earth geosciences.”
The tutorial defines two feature types:
gsml:GeologicUnit
, which describes “a body of material in the Earth”.gsml:MappedFeature
, which describes the representation on a map of a feature, in this casegsml:GeologicUnit
.
Because a single gsml:GeologicUnit
can be observed at several distinct locations on the Earth’s surface, it can have a multivalued gsml:occurrence
property, each being a gsml:MappedFeature
.
Installation¶
Install GeoServer as usual.
Install the app-schema plugin
geoserver-*-app-schema-plugin.zip
:Place the jar files in
WEB-INF/lib
.The
tutorial
folder contains the GeoServer configuraration (data directory) used for this tutorial.- Either replace your existing
data
directory with the tutorial data directory, - Or edit
WEB-INF/web.xml
to setGEOSERVER_DATA_DIR
to point to the tutorial data directory. (Be sure to uncomment the section that setsGEOSERVER_DATA_DIR
.)
- Either replace your existing
Perform any configuration required by your servlet container, and then start the servlet. For example, if you are using Tomcat, configure a new context in
server.xml
and then restart Tomcat.The first time GeoServer starts with the tutorial configuration, it will download all the schema (XSD) files it needs and store them in the
app-schema-cache
folder in the data directory. You must be connected to the internet for this to work.
datastore.xml¶
Each data store configuration file datastore.xml
specifies the location of a mapping file and triggers its loading as an app-schema data source. This file should not be confused with the source data store, which is specified inside the mapping file.
For gsml_GeologicUnit
the file is workspaces/gsml/gsml_GeologicUnit/datastore.xml
:
<dataStore>
<id>gsml_GeologicUnit_datastore</id>
<name>gsml_GeologicUnit</name>
<enabled>true</enabled>
<workspace>
<id>gsml_workspace</id>
</workspace>
<connectionParameters>
<entry key="namespace">urn:cgi:xmlns:CGI:GeoSciML:2.0</entry>
<entry key="url">file:workspaces/gsml/gsml_GeologicUnit/gsml_GeologicUnit.xml</entry>
<entry key="dbtype">app-schema</entry>
</connectionParameters>
</dataStore>
For gsml:MappedFeature
the file is workspaces/gsml/gsml_MappedFeature/datastore.xml
:
<dataStore>
<id>gsml_MappedFeature_datastore</id>
<name>gsml_MappedFeature</name>
<enabled>true</enabled>
<workspace>
<id>gsml_workspace</id>
</workspace>
<connectionParameters>
<entry key="namespace">urn:cgi:xmlns:CGI:GeoSciML:2.0</entry>
<entry key="url">file:workspaces/gsml/gsml_MappedFeature/gsml_MappedFeature.xml</entry>
<entry key="dbtype">app-schema</entry>
</connectionParameters>
</dataStore>
Note
Ensure that there is no whitespace inside an entry
element.
Mapping files¶
Configuration of app-schema feature types is performed in mapping files:
workspaces/gsml/gsml_GeologicUnit/gsml_GeologicUnit.xml
workspaces/gsml/gsml_MappedFeature/gsml_MappedFeature.xml
Namespaces¶
Each mapping file contains namespace prefix definitions:
<Namespace>
<prefix>gml</prefix>
<uri>http://www.opengis.net/gml</uri>
</Namespace>
<Namespace>
<prefix>gsml</prefix>
<uri>urn:cgi:xmlns:CGI:GeoSciML:2.0</uri>
</Namespace>
<Namespace>
<prefix>xlink</prefix>
<uri>http://www.w3.org/1999/xlink</uri>
</Namespace>
Only those namespace prefixes used in the mapping file need to be declared, so the mapping file for gsml:GeologicUnit
has less.
Source data store¶
The data for this tutorial is contained in two property files:
workspaces/gsml/gsml_GeologicUnit/gsml_GeologicUnit.properties
workspaces/gsml/gsml_MappedFeature/gsml_MappedFeature.properties
Java Properties describes the format of property files.
For this example, each feature type uses an identical source data store configuration. This directory
parameter indicates that the source data is contained in property files named by their feature type, in the same directory as the corresponding mapping file:
<sourceDataStores>
<DataStore>
<id>datastore</id>
<parameters>
<Parameter>
<name>directory</name>
<value>file:./</value>
</Parameter>
</parameters>
</DataStore>
</sourceDataStores>
See Data Stores for a description of how to use other types of data stores such as databases.
Target types¶
Both feature types are defined by the same XML Schema, the top-level schema for GeoSciML 2.0. This is specified in the targetTypes
section. The type of the output feature is defined in targetElement
in the typeMapping
section below:
<targetTypes>
<FeatureType>
<schemaUri>http://www.geosciml.org/geosciml/2.0/xsd/geosciml.xsd</schemaUri>
</FeatureType>
</targetTypes>
In this case the schema is published, but because the OASIS XML Catalog is used for schema resolution, a private or modified schema in the catalog can be used if desired.
Mappings¶
The typeMappings
element begins with configuration elements. From the mapping file for gsml:GeologicUnit
:
<typeMappings>
<FeatureTypeMapping>
<sourceDataStore>datastore</sourceDataStore>
<sourceType>gsml_GeologicUnit</sourceType>
<targetElement>gsml:GeologicUnit</targetElement>
- The mapping starts with
sourceDataStore
, which gives the arbitrary identifier used above to name the source of the input data in thesourceDataStores
section. sourceType
gives the name of the source simple feature type. In this case it is the simple feature typegsml_GeologicUnit
, sourced from the rows of the filegsml_GeologicUnit.properties
in the same directory as the mapping file.- When working with databases
sourceType
is the name of a table or view. Database identifiers must be lowercase for PostGIS or uppercase for Oracle Spatial. targetElement
is the name of the output complex feature type.
gml:id mapping¶
The first mapping sets the gml:id
to be the feature id specified in the source property file:
<AttributeMapping>
<targetAttribute>
gsml:GeologicUnit
</targetAttribute>
<idExpression>
<OCQL>ID</OCQL>
</idExpression>
</AttributeMapping>
targetAttribute
is the XPath to the element for which the mapping applies, in this case, the top-level feature type.idExpression
is a special form that can only be used to set thegml:id
on a feature. Any field or CQL expression can be used, if it evaluates to an NCName.
Ordinary mapping¶
Most mappings consist of a target and source. Here is one from gsml:GeologicUnit
:
<AttributeMapping>
<targetAttribute>
gml:description
</targetAttribute>
<sourceExpression>
<OCQL>DESCRIPTION</OCQL>
</sourceExpression>
</AttributeMapping>
- In this case, the value of
gml:description
is just the value of theDESCRIPTION
field in the property file. - For a database, the field name is the name of the column (the table/view is set in
sourceType
above). Database identifiers must be lowercase for PostGIS or uppercase for Oracle Spatial. - CQL expressions can be used to calculate content. Use caution because queries on CQL-calculated values prevent the construction of efficient SQL queries.
- Source expressions can be CQL literals, which are single-quoted.
Client properties¶
In addition to the element content, a mapping can set one or more “client properties” (XML attributes). Here is one from gsml:MappedFeature
:
<AttributeMapping>
<targetAttribute>
gsml:specification
</targetAttribute>
<ClientProperty>
<name>xlink:href</name>
<value>GU_URN</value>
</ClientProperty>
</AttributeMapping>
- This mapping leaves the content of the
gsml:specification
element empty but sets anxlink:href
attribute to the value of theGU_URN
field. - Multiple
ClientProperty
mappings can be set.
In this example from the mapping for gsml:GeologicUnit
both element content and an XML attribute are provided:
<AttributeMapping>
<targetAttribute>
gml:name[1]
</targetAttribute>
<sourceExpression>
<OCQL>NAME</OCQL>
</sourceExpression>
<ClientProperty>
<name>codeSpace</name>
<value>'urn:x-test:classifierScheme:TestAuthority:GeologicUnitName'</value>
</ClientProperty>
</AttributeMapping>
- The
codespace
XML attribute is set to a fixed value by providing a CQL literal. - There are multiple mappings for
gml:name
, and the index[1]
means that this mapping targets the first.
targetAttributeNode¶
If the type of a property is abstract, a targetAttributeNode
mapping must be used to specify a concrete type. This mapping must occur before the mapping for the content of the property.
Here is an example from the mapping file for gsml:MappedFeature
:
<AttributeMapping>
<targetAttribute>gsml:positionalAccuracy</targetAttribute>
<targetAttributeNode>gsml:CGI_TermValuePropertyType</targetAttributeNode>
</AttributeMapping>
<AttributeMapping>
<targetAttribute>gsml:positionalAccuracy/gsml:CGI_TermValue/gsml:value</targetAttribute>
<sourceExpression>
<OCQL>'urn:ogc:def:nil:OGC:missing'</OCQL>
</sourceExpression>
<ClientProperty>
<name>codeSpace</name>
<value>'urn:ietf:rfc:2141'</value>
</ClientProperty>
</AttributeMapping>
gsml:positionalAccuracy
is of typegsml:CGI_TermValuePropertyType
, which is abstract, so must be mapped to its concrete subtypegsml:CGI_TermValuePropertyType
with atargetAttributeNode
mapping before its contents can be mapped.- This example also demonstrates that mapping can be applied to nested properties to arbitrary depth. This becomes unmanageable for deep nesting, where feature chaining is preferred.
Feature chaining¶
In feature chaining, one feature type is used as a property of an enclosing feature type, by value or by reference:
<AttributeMapping>
<targetAttribute>
gsml:occurrence
</targetAttribute>
<sourceExpression>
<OCQL>URN</OCQL>
<linkElement>gsml:MappedFeature</linkElement>
<linkField>gml:name[2]</linkField>
</sourceExpression>
<isMultiple>true</isMultiple>
</AttributeMapping>
- In this case from the mapping for
gsml:GeologicUnit
, we specify a mapping for itsgsml:occurrence
. - The
URN
field of the sourcegsml_GeologicUnit
simple feature is use as the “foreign key”, which maps to the secondgml:name
in eachgsml:MappedFeature
. - Every
gsml:MappedFeature
withgml:name[2]
equal to theURN
of thegsml:GeologicUnit
under construction is included as agsml:occurrence
property of thegsml:GeologicUnit
(by value).
WFS response¶
When GeoServer is running, test app-schema WFS in a web browser. If GeoServer is listening on localhost:8080
you can query the two feature types using these links:
- http://localhost:8080/geoserver/wfs?request=GetFeature&version=1.1.0&typeName=gsml:GeologicUnit
- http://localhost:8080/geoserver/wfs?request=GetFeature&version=1.1.0&typeName=gsml:MappedFeature
gsml:GeologicUnit¶
Feature chaining has been used to construct the multivalued property gsml:occurrence
of gsml:GeologicUnit
. This property is a gsml:MappedFeature
. The WFS response for gsml:GeologicUnit
combines the output of both feature types into a single response. The first gsml:GeologicUnit
has two gsml:occurrence
properties, while the second has one. The relationships between the feature instances are data driven.
Because the mapping files in the tutorial configuration do not contain attribute mappings for all mandatory properties of these feature types, the WFS response is not schema-valid against the GeoSciML 2.0 schemas. Schema-validity can be achieved by adding more attribute mappings to the mapping files.
Note
These feature types are defined in terms of GML 3.1 (the default for WFS 1.1.0); other GML versions will not work.
Warning
The web interface does not yet support app-schema store or layer administration.
Acknowledgements¶
gsml_GeologicUnit.properties
and gsml_MappedFeature.properties
are derived from data provided by the Department of Primary Industries, Victoria, Australia. For the purposes of this tutorial, this data has been modified to the extent that it has no real-world meaning.