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package org.apache.lucene.spatial.query;

import org.locationtech.spatial4j.shape.Rectangle;
import org.locationtech.spatial4j.shape.Shape;
import org.locationtech.spatial4j.shape.SpatialRelation;

import java.io.Serializable;
import java.util.ArrayList;
import java.util.HashMap;
import java.util.List;
import java.util.Locale;
import java.util.Map;

A predicate that compares a stored geometry to a supplied geometry. It's enum-like. For more explanation of each predicate, consider looking at the source implementation of evaluate(Shape, Shape). It's important to be aware that Lucene-spatial makes no distinction of shape boundaries, unlike many standardized definitions. Nor does it make dimensional distinctions (e.g. line vs polygon). You can lookup a predicate by "Covers" or "Contains", for example, and you will get the same underlying predicate implementation.
See Also:
@lucene.experimental
/** * A predicate that compares a stored geometry to a supplied geometry. It's enum-like. For more * explanation of each predicate, consider looking at the source implementation * of {@link #evaluate(org.locationtech.spatial4j.shape.Shape, org.locationtech.spatial4j.shape.Shape)}. It's important * to be aware that Lucene-spatial makes no distinction of shape boundaries, unlike many standardized * definitions. Nor does it make dimensional distinctions (e.g. line vs polygon). * You can lookup a predicate by "Covers" or "Contains", for example, and you will get the * same underlying predicate implementation. * * @see <a href="http://en.wikipedia.org/wiki/DE-9IM">DE-9IM at Wikipedia, based on OGC specs</a> * @see <a href="http://edndoc.esri.com/arcsde/9.1/general_topics/understand_spatial_relations.htm"> * ESRIs docs on spatial relations</a> * * @lucene.experimental */
public abstract class SpatialOperation implements Serializable { //TODO rename to SpatialPredicate. Use enum? LUCENE-5771 // Private registry private static final Map<String, SpatialOperation> registry = new HashMap<>();//has aliases private static final List<SpatialOperation> list = new ArrayList<>(); // Geometry Operations
Bounding box of the *indexed* shape, then Intersects.
/** Bounding box of the *indexed* shape, then {@link #Intersects}. */
public static final SpatialOperation BBoxIntersects = new SpatialOperation("BBoxIntersects") { @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { return indexedShape.getBoundingBox().relate(queryShape).intersects(); } };
Bounding box of the *indexed* shape, then IsWithin.
/** Bounding box of the *indexed* shape, then {@link #IsWithin}. */
public static final SpatialOperation BBoxWithin = new SpatialOperation("BBoxWithin") { { register("BBoxCoveredBy");//alias -- the better name } @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { Rectangle bbox = indexedShape.getBoundingBox(); return bbox.relate(queryShape) == SpatialRelation.WITHIN || bbox.equals(queryShape); } };
Meets the "Covers" OGC definition (boundary-neutral).
/** Meets the "Covers" OGC definition (boundary-neutral). */
public static final SpatialOperation Contains = new SpatialOperation("Contains") { { register("Covers");//alias -- the better name } @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { return indexedShape.relate(queryShape) == SpatialRelation.CONTAINS || indexedShape.equals(queryShape); } };
Meets the "Intersects" OGC definition.
/** Meets the "Intersects" OGC definition. */
public static final SpatialOperation Intersects = new SpatialOperation("Intersects") { @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { return indexedShape.relate(queryShape).intersects(); } };
Meets the "Equals" OGC definition.
/** Meets the "Equals" OGC definition. */
public static final SpatialOperation IsEqualTo = new SpatialOperation("Equals") { { register("IsEqualTo");//alias (deprecated) } @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { return indexedShape.equals(queryShape); } };
Meets the "Disjoint" OGC definition.
/** Meets the "Disjoint" OGC definition. */
public static final SpatialOperation IsDisjointTo = new SpatialOperation("Disjoint") { { register("IsDisjointTo");//alias (deprecated) } @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { return ! indexedShape.relate(queryShape).intersects(); } };
Meets the "CoveredBy" OGC definition (boundary-neutral).
/** Meets the "CoveredBy" OGC definition (boundary-neutral). */
public static final SpatialOperation IsWithin = new SpatialOperation("Within") { { register("IsWithin");//alias (deprecated) register("CoveredBy");//alias -- the more appropriate name. } @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { return indexedShape.relate(queryShape) == SpatialRelation.WITHIN || indexedShape.equals(queryShape); } };
Almost meets the "Overlaps" OGC definition, but boundary-neutral (boundary==interior).
/** Almost meets the "Overlaps" OGC definition, but boundary-neutral (boundary==interior). */
public static final SpatialOperation Overlaps = new SpatialOperation("Overlaps") { @Override public boolean evaluate(Shape indexedShape, Shape queryShape) { return indexedShape.relate(queryShape) == SpatialRelation.INTERSECTS;//not Contains or Within or Disjoint } }; private final String name; protected SpatialOperation(String name) { this.name = name; register(name); list.add( this ); } protected void register(String name) { registry.put(name, this); registry.put(name.toUpperCase(Locale.ROOT), this); } public static SpatialOperation get( String v ) { SpatialOperation op = registry.get( v ); if( op == null ) { op = registry.get(v.toUpperCase(Locale.ROOT)); } if( op == null ) { throw new IllegalArgumentException("Unknown Operation: " + v ); } return op; } public static List<SpatialOperation> values() { return list; } public static boolean is( SpatialOperation op, SpatialOperation ... tst ) { for( SpatialOperation t : tst ) { if( op == t ) { return true; } } return false; }
Returns whether the relationship between indexedShape and queryShape is satisfied by this operation.
/** * Returns whether the relationship between indexedShape and queryShape is * satisfied by this operation. */
public abstract boolean evaluate(Shape indexedShape, Shape queryShape); public String getName() { return name; } @Override public String toString() { return name; } }