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flet / flet-libgeos python
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Version:
3.13.0 ▾
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/**********************************************************************
*
* GEOS - Geometry Engine Open Source
* http://geos.osgeo.org
*
* Copyright (C) 2006 Refractions Research Inc.
*
* This is free software; you can redistribute and/or modify it under
* the terms of the GNU Lesser General Public Licence as published
* by the Free Software Foundation.
* See the COPYING file for more information.
*
**********************************************************************
*
* Last port: geom/prep/PreparedGeometry.java rev. 1.11 (JTS-1.10)
*
**********************************************************************/
#pragma once
#include <vector>
#include <memory>
#include <string>
#include <geos/export.h>
// Forward declarations
namespace geos {
namespace geom {
class Geometry;
class Coordinate;
class CoordinateSequence;
class IntersectionMatrix;
}
}
namespace geos {
namespace geom { // geos::geom
namespace prep { // geos::geom::prep
/**
* \class PreparedGeometry
*
* \brief
* An interface for classes which prepare {@link Geometry}s
* in order to optimize the performance
* of repeated calls to specific geometric operations.
*
* A given implementation may provide optimized implementations
* for only some of the specified methods,
* and delegate the remaining methods to the original {@link Geometry} operations.
* An implementation may also only optimize certain situations,
* and delegate others.
* See the implementing classes for documentation about which methods and situations
* they optimize.
*
*/
class GEOS_DLL PreparedGeometry {
public:
virtual
~PreparedGeometry() {}
/** \brief
* Gets the original {@link Geometry} which has been prepared.
*
* @return the base geometry
*/
virtual const geom::Geometry& getGeometry() const = 0;
/** \brief
* Tests whether the base {@link Geometry} contains a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry contains the given Geometry
*
* @see Geometry#contains(Geometry)
*/
virtual bool contains(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} properly contains
* a given geometry.
*
* The <code>containsProperly</code> predicate has the following
* equivalent definitions:
*
* - Every point of the other geometry is a point of this
* geometry's interior.
* - The DE-9IM Intersection Matrix for the two geometries matches
* <code>[T**FF*FF*]</code>
*
* In other words, if the test geometry has any interaction with
* the boundary of the target
* geometry the result of <tt>containsProperly</tt> is <tt>false</tt>.
* This is different semantics to the {@link Geometry::contains}
* predicate, in which test geometries can intersect the target's
* boundary and still be contained.
*
* The advantage of using this predicate is that it can be computed
* efficiently, since it avoids the need to compute the full
* topological relationship of the input boundaries in cases where
* they intersect.
*
* An example use case is computing the intersections
* of a set of geometries with a large polygonal geometry.
* Since <tt>intersection</tt> is a fairly slow operation, it can
* be more efficient
* to use <tt>containsProperly</tt> to filter out test geometries
* which lie
* wholly inside the area. In these cases the intersection is
* known <i>a priori</i> to be exactly the original test geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry properly contains the given Geometry
*
* @see Geometry::contains
*
*/
virtual bool containsProperly(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} is covered by a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry is covered by the given Geometry
*
* @see Geometry#coveredBy(Geometry)
*/
virtual bool coveredBy(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} covers a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry covers the given Geometry
*
* @see Geometry#covers(Geometry)
*/
virtual bool covers(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} crosses a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry crosses the given Geometry
*
* @see Geometry#crosses(Geometry)
*/
virtual bool crosses(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} is disjoint from a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry is disjoint from the given Geometry
*
* @see Geometry#disjoint(Geometry)
*/
virtual bool disjoint(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} intersects a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry intersects the given Geometry
*
* @see Geometry#intersects(Geometry)
*/
virtual bool intersects(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} overlaps a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry overlaps the given Geometry
*
* @see Geometry#overlaps(Geometry)
*/
virtual bool overlaps(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} touches a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry touches the given Geometry
*
* @see Geometry#touches(Geometry)
*/
virtual bool touches(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} is within a given geometry.
*
* @param geom the Geometry to test
* @return true if this Geometry is within the given Geometry
*
* @see Geometry#within(Geometry)
*/
virtual bool within(const geom::Geometry* geom) const = 0;
/** \brief
* Compute the nearest locations on the base {@link Geometry} and
* the given geometry.
*
* @param geom the Geometry to compute the nearest point to
* @return true the nearest points
*
*/
virtual std::unique_ptr<geom::CoordinateSequence> nearestPoints(const geom::Geometry* geom) const = 0;
/** \brief
* Compute the minimum distance between the base {@link Geometry} and
* the given geometry.
*
* @param geom the Geometry to compute the distance to
* @return the minimum distance between the two geometries
*
*/
virtual double distance(const geom::Geometry* geom) const = 0;
/** \brief
* Tests whether the base {@link Geometry} is within a given
* distance from the given geometry.
*
* @param geom the Geometry to test the distance to
* @param dist the distance value to compare
* @return true if this Geometry is within the given distance from
* the given Geometry.
*
*/
virtual bool isWithinDistance(const geom::Geometry* geom, double dist) const = 0;
/** \brief
* Compares the prepared geometry to the given geometry
* and returns the DE9IM intersection matrix as a string.
*
* @param geom the Geometry to test the
* @return the DE9IM matrix
*/
virtual std::unique_ptr<IntersectionMatrix> relate(const geom::Geometry* geom) const = 0;
/** \brief
* Compares the prepared geometry to the given geometry
* and the provided DE9IM pattern, and returns true if the
* pattern is consistent with the relationship between the
* prepared and provided geometries.
*
* @param geom the Geometry to test the distance to
* @param pat the DE9IM pattern
* @return true if the patterns are consistent
*/
virtual bool relate(const geom::Geometry* geom, const std::string& pat) const = 0;
};
} // namespace geos::geom::prep
} // namespace geos::geom
} // namespace geos