Namespace for the Vector Geometry module of TerraLib. More...

Classes
class	AbstractPoint
	A base abstract class for 0-dimensional geometric objects that represents a single location in coordinate space. More...

class	AffineGT
	2D Affine Geometric transformation. More...

class	AffineGTFactory
	2D Affine Geometric transformation factory. More...

class	CircularString
	CircularString is a curve with circular interpolation between points. More...

class	CompoundCurve
	CompoundCurve is a curve that may have circular and linear segments. More...

struct	Coord2D
	An utility struct for representing 2D coordinates. More...

class	Curve
	Curve is an abstract class that represents 1-dimensional geometric objects stored as a sequence of coordinates. More...

class	CurvePolygon
	CurvePolygon is a planar surface defined by 1 exterior boundary and 0 or more interior boundaries. More...

class	Envelope
	An Envelope defines a 2D rectangular region. More...

class	GeometricTransformation
	2D Geometric transformation base class. More...

class	Geometry
	Geometry is the root class of the geometries hierarchy, it follows OGC and ISO standards. More...

class	GeometryCollection
	It is a collection of other geometric objects. More...

class	GeometryFactory
	This is the Geometry factory for TerraLib geometries. More...

class	GeometryProperty
	Geometric property. More...

class	GTFactory
	2D Geometric transformation factory. More...

class	GTFilter
	2D Geometric transformation tie-points filter (outliers remotion). More...

class	GTModelParameters
	2D Geometric transformation model parameters. More...

class	GTParameters
	2D Geometric transformation parameters. More...

class	Line
	A Line is LineString with 2 points. More...

class	LinearRing
	A LinearRing is a LineString that is both closed and simple. More...

class	LineString
	LineString is a curve with linear interpolation between points. More...

class	Module
	This singleton defines the TerraLib Vector Geometry module entry. More...

class	MultiCurve
	MultiCurve is a class that represents a 1-dimensional GeometryCollection whose elements are curves. More...

class	MultiLineString
	MultiLineString is a MultiCurve whose elements are LineStrings. More...

class	MultiPoint
	MultiPoint is a GeometryCollection whose elements are restricted to points. More...

class	MultiPolygon
	MultiPolygon is a MultiSurface whose elements are Polygons. More...

class	MultiSurface
	MultiSurface is a class that represents a 2-dimensional GeometryCollection whose elements are surfaces. More...

class	Point
	A point with x and y coordinate values. More...

class	PointKd
	A k-dimensional point. More...

class	PointM
	A point with an associated measure. More...

class	PointZ
	A point with z-coordinate value. More...

class	PointZM
	A point with a z-coordinate value and an associated measurement. More...

class	Polygon
	Polygon is a subclass of CurvePolygon whose rings are defined by linear rings. More...

class	PolyhedralSurface
	PolyhedralSurface is a contiguous collection of polygons, which share common boundary segments. More...

class	ProjectiveGT
	2D Projective Geometric transformation. More...

class	ProjectiveGTFactory
	2D Projective Geometric transformation factory. More...

class	RSTGT
	2D Rotation/scale/translation(rigid body) Geometric transformation. More...

class	RSTGTFactory
	2D RST Geometric transformation factory. More...

class	SecondDegreePolynomialGT
	Second Degree Polynomial Geometric transformation. More...

class	SecondDegreePolynomialGTFactory
	2D Second Degree Polynomial Geometric transformation factory. More...

class	Surface
	Surface is an abstract class that represents a 2-dimensional geometric objects. More...

class	ThirdDegreePolynomialGT
	Third Degree Polynomial Geometric transformation. More...

class	ThirdDegreePolynomialGTFactory
	2D Third Degree Polynomial Geometric transformation factory. More...

class	TIN
	TIN (triangulated irregular network) is a PolyhedralSurface consisting only of Triangle patches. More...

class	Triangle
	Triangle is a polygon with 3 distinct, non-collinear vertices and no interior boundary. More...

class	Visitor
	A visitor interface for the Geometry hierarchy. More...

class	WKBReader
	A class that deserializes a geometry from a valid WKB. More...

class	WKBSize
	A class that computes the number of bytes necessary to encode a geometry in WKB. More...

class	WKBWriter
	A class that serializes a geometry to the WKB format. More...

class	WKTActions
	A class that implements the Grammar Rules for well known text (WKT) format for Geometry. More...

class	WKTParser

class	WKTReader
	A class that deserializes a Geometry from a valid WKT. More...

class	WKTWriter
	A class that serializes a geometry to the WKT format. More...

Typedefs
typedef boost::shared_ptr < Geometry >	GeometryShrPtr

Enumerations
enum	BufferCapStyle { CapRoundType, CapButtType, CapSquareType }
	Buffer end cap style. More...

enum	Dimensionality { P = 0, L = 1, A = 2 }
	From Wikipedia: "in mathematics, the dimension of an object is an intrinsic property, independent of the space in which the object may happen to be embedded". More...

enum	GeomType { GeometryType = 0, GeometryZType = 1000, GeometryMType = 2000, GeometryZMType = 3000, PointType = 1, PointZType = 1001, PointMType = 2001, PointZMType = 3001, PointKdType = 0xFFFFFFFD, LineStringType = 2, LineStringZType = 1002, LineStringMType = 2002, LineStringZMType = 3002, CircularStringType = 8, CircularStringZType = 1008, CircularStringMType = 2008, CircularStringZMType = 3008, CompoundCurveType = 9, CompoundCurveZType = 1009, CompoundCurveMType = 2009, CompoundCurveZMType = 3009, PolygonType = 3, PolygonZType = 1003, PolygonMType = 2003, PolygonZMType = 3003, CurvePolygonType = 10, CurvePolygonZType = 1010, CurvePolygonMType = 2010, CurvePolygonZMType = 3010, GeometryCollectionType = 7, GeometryCollectionZType = 1007, GeometryCollectionMType = 2007, GeometryCollectionZMType = 3007, MultiPointType = 4, MultiPointZType = 1004, MultiPointMType = 2004, MultiPointZMType = 3004, MultiLineStringType = 5, MultiLineStringZType = 1005, MultiLineStringMType = 2005, MultiLineStringZMType = 3005, MultiPolygonType = 6, MultiPolygonZType = 1006, MultiPolygonMType = 2006, MultiPolygonZMType = 3006, MultiSurfaceType = 12, MultiSurfaceZType = 1012, MultiSurfaceMType = 2012, MultiSurfaceZMType = 3012, PolyhedralSurfaceType = 15, PolyhedralSurfaceZType = 1015, PolyhedralSurfaceMType = 2015, PolyhedralSurfaceZMType = 3015, TINType = 16, TINZType = 1016, TINMType = 2016, TINZMType = 3016, TriangleType = 17, TriangleZType = 1017, TriangleMType = 2017, TriangleZMType = 3017, UnknownGeometryType = 0xFFFFFFFF }
	Each enumerated type is compatible with a Well-known Binary (WKB) type code. More...

enum	SpatialRelation { UNKNOWN_SPATIAL_RELATION = 0, INTERSECTS = 1, DISJOINT = 2, TOUCHES = 4, OVERLAPS = 8, CROSSES = 16, WITHIN = 32, CONTAINS = 64, COVERS = 128, COVEREDBY = 256, EQUALS = 512 }
	Spatial relations between geometric objects. More...

Functions
TEGEOMEXPORT Envelope	AdjustToCut (const Envelope &env, double bWidth, double bHeight)
	Finds the correspondent smallest box that allows a box to be cut in blocks of a given size. More...

TEGEOMEXPORT Geometry *	FixGeometry (te::gm::Geometry *inputGeom)

int	GetCoordDimension (GeomType t)
	It returns the number of measurements or axes needed to describe a position in a coordinate system. More...

TEGEOMEXPORT Geometry *	GetGeomFromEnvelope (const Envelope *const e, int srid)
	It creates a Geometry (a polygon) from the given envelope. More...

template<class T1 , class T2 >
bool	Intersects (const T1 &o1, const T2 &o2)

template<>
TEGEOMEXPORT bool	Intersects (const te::gm::Point &point, const te::gm::Envelope &e)

TEGEOMEXPORT Coord2D *	locateAlong (const LineString *line, double initial, double final, double target)
	Make the line interpolation to find a target. More...

TEGEOMEXPORT void	Multi2Single (te::gm::Geometry g, std::vector< te::gm::Geometry > &geoms)
	It will get a GeometryCollection and distribute in a vector. More...

TEGEOMEXPORT bool	SatisfySpatialRelation (const Geometry g1, const Geometry g2, SpatialRelation relation)
	It returns if two geometries satisfy a given spatial relation. More...

Geometry Methods
Methods related to Geometry conversion.
te::dt::AbstractData *	GeometryToByteArrayConverter (te::dt::AbstractData *d) throw (Exception)
	It converts a Geometry data value to a ByteArray data value. More...

te::dt::AbstractData *	GeometryToStringConverter (te::dt::AbstractData *d) throw (Exception)
	It converts a Geometry data value to a String data value. More...

te::dt::AbstractData *	ByteArrayToGeometryConverter (te::dt::AbstractData *d)
	It converts a ByteArray data value to a Geometry data value. More...

te::dt::AbstractData *	StringToGeometryConverter (te::dt::AbstractData *d)
	It converts a String data value to a Geometry data value. More...

Detailed Description

Namespace for the Vector Geometry module of TerraLib.

Typedef Documentation

typedef boost::shared_ptr<Geometry> te::gm::GeometryShrPtr

Definition at line 872 of file Geometry.h.

Enumeration Type Documentation

enum te::gm::BufferCapStyle

Buffer end cap style.

The end cap style specifies the buffer geometry that will be created at the ends of LineStrings.

Enumerator
CapRoundType	A semi-circle (default).
CapButtType	A straight line perpendicular to the end segment
CapSquareType	A half-square

Definition at line 162 of file Enums.h.

enum te::gm::Dimensionality

From Wikipedia: "in mathematics, the dimension of an object is an intrinsic property, independent of the space in which the object may happen to be embedded".

Enumerator
P	Points are 0-dimensional.
L	Lines are 1-dimensional.
A	Polygons are 2-dimenional.

Definition at line 147 of file Enums.h.

enum te::gm::GeomType

Each enumerated type is compatible with a Well-known Binary (WKB) type code.

These are all WKB geometry types that TerraLib knows how to encode or decode. The values follows OGC Simple Feature Specification (SFS).

Enumerator
GeometryType	Geometry is not instantiable but this is the general type for geometries in R2 (x, y).
GeometryZType	Geometry is not instantiable but this is the general type for geometries in R3 (x, y, z).
GeometryMType	Geometry is not instantiable but this is the general type for geometries in R3 (x, y, m).
GeometryZMType	Geometry is not instantiable but this is the general type for geometries in R4 (x, y, z, m).
PointType	A point in R2 with coordinate values for x and y.
PointZType	A point in R3 with coordinate values for x, y and z.
PointMType	A point in R3 with coordinate values for x, y and m.
PointZMType	A point in R4 with coordinate values for x, y, z and m.
PointKdType	A point in Rn with k coordinate values.
LineStringType	A LineString in R2 with coordinate values for x and y.
LineStringZType	A LineString in R3 with coordinate values for x, y and z.
LineStringMType	A LineString in R3 with coordinate values for x, y and m.
LineStringZMType	A LineString in R4 with coordinate values for x, y, z and m.
CircularStringType	A CircularString in R2 with coordinate values for x and y.
CircularStringZType	A CircularString in R3 with coordinate values for x, y and z.
CircularStringMType	A CircularString in R3 with coordinate values for x, y and m.
CircularStringZMType	A CircularString in R4 with coordinate values for x, y, z and m.
CompoundCurveType	A CompoundCurve in R2 with coordinate values for x and y.
CompoundCurveZType	A CompoundCurve in R3 with coordinate values for x, y and z.
CompoundCurveMType	A CompoundCurve in R3 with coordinate values for x, y and m.
CompoundCurveZMType	A CompoundCurve in R4 with coordinate values for x, y, z and m.
PolygonType	A Polygon in R2 with coordinate values for x and y.
PolygonZType	A Polygon in R3 with coordinate values for x, y and z.
PolygonMType	A Polygon in R3 with coordinate values for x, y and m.
PolygonZMType	A Polygon in R4 with coordinate values for x, y, z and m.
CurvePolygonType	A CurvePolygon in R2 with coordinate values for x and y.
CurvePolygonZType	A CurvePolygon in R3 with coordinate values for x, y and z.
CurvePolygonMType	A CurvePolygon in R3 with coordinate values for x, y and m.
CurvePolygonZMType	A CurvePolygon in R4 with coordinate values for x, y, z and m.
GeometryCollectionType	A GeometryCollection in R2 with coordinate values for x and y.
GeometryCollectionZType	A GeometryCollection in R3 with coordinate values for x, y and z.
GeometryCollectionMType	A GeometryCollection in R3 with coordinate values for x, y and m.
GeometryCollectionZMType	A GeometryCollection in R4 with coordinate values for x, y, z and m.
MultiPointType	A MultiPoint in R2 with coordinate values for x and y.
MultiPointZType	A MultiPoint in R3 with coordinate values for x, y and z.
MultiPointMType	A MultiPoint in R3 with coordinate values for x, y and m.
MultiPointZMType	A MultiPoint in R4 with coordinate values for x, y, z and m.
MultiLineStringType	A MultiLineString in R2 with coordinate values for x and y.
MultiLineStringZType	A MultiLineString in R3 with coordinate values for x, y and z.
MultiLineStringMType	A MultiLineString in R3 with coordinate values for x, y and m.
MultiLineStringZMType	A MultiLineString in R4 with coordinate values for x, y, z and m.
MultiPolygonType	A MultiPolygon in R2 with coordinate values for x and y.
MultiPolygonZType	A MultiPolygon in R3 with coordinate values for x, y and z.
MultiPolygonMType	A MultiPolygon in R3 with coordinate values for x, y and m.
MultiPolygonZMType	A MultiPolygon in R4 with coordinate values for x, y, z and m.
MultiSurfaceType	A MultiSurface in R2 with coordinate values for x and y.
MultiSurfaceZType	A MultiSurface in R3 with coordinate values for x, y and z.
MultiSurfaceMType	A MultiSurface in R3 with coordinate values for x, y and m.
MultiSurfaceZMType	A MultiSurface in R4 with coordinate values for x, y, z and m.
PolyhedralSurfaceType	A PolyhedralSurface in R2 with coordinate values for x and y.
PolyhedralSurfaceZType	A PolyhedralSurface in R3 with coordinate values for x, y and z.
PolyhedralSurfaceMType	A PolyhedralSurface in R3 with coordinate values for x, y and m.
PolyhedralSurfaceZMType	A PolyhedralSurface in R4 with coordinate values for x, y, z and m.
TINType	A TIN in R2 with coordinate values for x and y.
TINZType	A TIN in R3 with coordinate values for x, y and z.
TINMType	A TIN in R3 with coordinate values for x, y and m.
TINZMType	A TIN in R4 with coordinate values for x, y, z and m.
TriangleType	A Triangle in R2 with coordinate values for x and y.
TriangleZType	A Triangle in R3 with coordinate values for x, y and z.
TriangleMType	A Triangle in R3 with coordinate values for x, y and m.
TriangleZMType	A Triangle in R4 with coordinate values for x, y, z and m.
UnknownGeometryType	Just a marker for an unknown geometry type.

Definition at line 41 of file Enums.h.

enum te::gm::SpatialRelation

Spatial relations between geometric objects.

Enumerator
UNKNOWN_SPATIAL_RELATION
INTERSECTS
DISJOINT
TOUCHES
OVERLAPS
CROSSES
WITHIN
CONTAINS
COVERS
COVEREDBY
EQUALS

Definition at line 127 of file Enums.h.

Function Documentation

TEGEOMEXPORT Envelope te::gm::AdjustToCut	(	const Envelope &	env,
		double	bWidth,
		double	bHeight
	)

Finds the correspondent smallest box that allows a box to be cut in blocks of a given size.

Parameters

env	Reference envelope
bWidth	Block width
bHeight	Block height

Returns: It returns a adjusted envelope

te::dt::AbstractData* te::gm::ByteArrayToGeometryConverter ( te::dt::AbstractData * d )

It converts a ByteArray data value to a Geometry data value.

Parameters

d	The input data value.

Returns: A new data value converted to Geometry type. The caller will take the ownership of the returned data.

Note: This method consider that the ByteArray data value contains a geometry encoded using WKB format.

Exceptions

It	throws an exception if the input abstract data is not a ByteArray type.
It	throws an exception if the conversion can be not done.

TEGEOMEXPORT Geometry* te::gm::FixGeometry ( te::gm::Geometry * inputGeom )

te::dt::AbstractData* te::gm::GeometryToByteArrayConverter	(	te::dt::AbstractData *	d	)
throw	(	Exception
	)

It converts a Geometry data value to a ByteArray data value.

Parameters

d	The input data value.

Returns: A new data value converted to ByteArray type. The caller will take the ownership of the returned data.

Note: The ByteArray data value will contains the Geometry encoded using WKB format.

Exceptions

It	throws an exception if the input abstract data is not a Geometry type.

te::dt::AbstractData* te::gm::GeometryToStringConverter	(	te::dt::AbstractData *	d	)
throw	(	Exception
	)

It converts a Geometry data value to a String data value.

Parameters

d	The input data value.

Returns: A new data value converted to String type. The caller will take the ownership of the returned data.

Note: The String data value will contains the Geometry encoded using WKT format.

Exceptions

It	throws an exception if the input abstract data is not a Geometry type.

int te::gm::GetCoordDimension ( GeomType t )

inline

It returns the number of measurements or axes needed to describe a position in a coordinate system.

It returns:

2 for a coordinate with x, y;
3 for a coordinate with x, y and z or x, y and m;
4 for a coordinate with x, y, z and m.

Parameters

t	The geomeytric type.

Returns: The number of measurements or axes needed to describe a position in a coordinate system.

Definition at line 61 of file Utils.h.

TEGEOMEXPORT Geometry* te::gm::GetGeomFromEnvelope	(	const Envelope *const	e,
		int	srid
	)

It creates a Geometry (a polygon) from the given envelope.

Parameters

e	The envelope to extract the coordinates. Don't call with a NULL envelope.
srid	The Spatial Reference System ID to be associated to the polygon.

Returns: A polygon (in counter-clock-wise) with rectangle coordinates: [(MINX, MINY), (MAXX, MINY), (MAXX, MAXY), (MINX, MAXY), (MINX, MINY)].

Note: The caller of this method will take the ownership of the returned geometry.

Referenced by te::rst::LineIterator< T >::LineIterator(), and te::rst::PointSetIterator< T >::PointSetIterator().

template<class T1 , class T2 >

bool te::gm::Intersects	(	const T1 &	o1,
		const T2 &	o2
	)

Referenced by te::sam::kdtree::AdaptativeIndex< KdTreeNode >::search().

template<>

TEGEOMEXPORT bool te::gm::Intersects	(	const te::gm::Point &	point,
		const te::gm::Envelope &	e
	)

TEGEOMEXPORT Coord2D* te::gm::locateAlong	(	const LineString *	line,
		double	initial,
		double	final,
		double	target
	)

Make the line interpolation to find a target.

Parameters

line	LineString to make the interpolation
initial	Initial value
final	Final value
target	Target value

Returns: It returns a target Coord2D in the line.

TEGEOMEXPORT void te::gm::Multi2Single	(	te::gm::Geometry *	g,
		std::vector< te::gm::Geometry * > &	geoms
	)

It will get a GeometryCollection and distribute in a vector.

Parameters

g	Input GeometryCollection.
geoms	Output Geometry Vector.

Note: If the geomSource is not a te::gm::GeometryCollectionType it will return an empty vector.

TEGEOMEXPORT bool te::gm::SatisfySpatialRelation	(	const Geometry *	g1,
		const Geometry *	g2,
		SpatialRelation	relation
	)

It returns if two geometries satisfy a given spatial relation.

Parameters

g1	The first geometry
g2	The second geometry
r	A given spatial relation to be tested

Returns: It returns true if the given two geometries satisfy the spatial relation. Otherwise, it returns false.

Exceptions

Exception It throws an exception if the spatial relation is not valid or if the test can not be evaluated.

Referenced by te::rst::LineIterator< T >::LineIterator(), and te::rst::PointSetIterator< T >::PointSetIterator().

te::dt::AbstractData* te::gm::StringToGeometryConverter ( te::dt::AbstractData * d )

It converts a String data value to a Geometry data value.

Parameters

d	The input data value.

Returns: A new data value converted to Geometry type. The caller will take the ownership of the returned data.

Note: This method consider that the String data value contains a geometry encoded using WKT format.

Exceptions

It	throws an exception if the input abstract data is not a String type.
It	throws an exception if the conversion can be not done.

Classes

Typedefs

Enumerations

Functions

Detailed Description

Typedef Documentation

Enumeration Type Documentation

Function Documentation