52 Q_PROPERTY(
double x READ x WRITE setX )
53 Q_PROPERTY(
double y READ y WRITE setY )
54 Q_PROPERTY(
double z READ z WRITE setZ )
55 Q_PROPERTY(
double m READ m WRITE setM )
86 QgsPoint(
double x = std::numeric_limits<double>::quiet_NaN(),
double y = std::numeric_limits<double>::quiet_NaN(),
double z = std::numeric_limits<double>::quiet_NaN(),
double m = std::numeric_limits<double>::quiet_NaN(),
QgsWkbTypes::Type wkbType =
QgsWkbTypes::Unknown );
88 QgsPoint( SIP_PYOBJECT x
SIP_TYPEHINT( Optional[Union[
QgsPoint, QPointF,
float]] ) = Py_None, SIP_PYOBJECT y
SIP_TYPEHINT( Optional[
float] ) = Py_None, SIP_PYOBJECT z
SIP_TYPEHINT( Optional[
float] ) = Py_None, SIP_PYOBJECT m
SIP_TYPEHINT( Optional[
float] ) = Py_None, SIP_PYOBJECT wkbType
SIP_TYPEHINT( Optional[
int] ) = Py_None ) [(
double x = 0.0,
double y = 0.0,
double z = 0.0,
double m = 0.0,
QgsWkbTypes::Type wkbType =
QgsWkbTypes::Unknown )];
90 if ( sipCanConvertToType( a0, sipType_QgsPointXY, SIP_NOT_NONE ) && a1 == Py_None && a2 == Py_None && a3 == Py_None && a4 == Py_None )
95 QgsPointXY *p =
reinterpret_cast<QgsPointXY *
>( sipConvertToType( a0, sipType_QgsPointXY, 0, SIP_NOT_NONE, &state, &sipIsErr ) );
98 sipReleaseType( p, sipType_QgsPointXY, state );
102 sipCpp =
new sipQgsPoint(
QgsPoint( *p ) );
105 else if ( sipCanConvertToType( a0, sipType_QPointF, SIP_NOT_NONE ) && a1 == Py_None && a2 == Py_None && a3 == Py_None && a4 == Py_None )
110 QPointF *p =
reinterpret_cast<QPointF *
>( sipConvertToType( a0, sipType_QPointF, 0, SIP_NOT_NONE, &state, &sipIsErr ) );
113 sipReleaseType( p, sipType_QPointF, state );
117 sipCpp =
new sipQgsPoint(
QgsPoint( *p ) );
121 ( a0 == Py_None || PyFloat_AsDouble( a0 ) != -1.0 || !PyErr_Occurred() ) &&
122 ( a1 == Py_None || PyFloat_AsDouble( a1 ) != -1.0 || !PyErr_Occurred() ) &&
123 ( a2 == Py_None || PyFloat_AsDouble( a2 ) != -1.0 || !PyErr_Occurred() ) &&
124 ( a3 == Py_None || PyFloat_AsDouble( a3 ) != -1.0 || !PyErr_Occurred() ) )
126 double x = a0 == Py_None ? std::numeric_limits<double>::quiet_NaN() : PyFloat_AsDouble( a0 );
127 double y = a1 == Py_None ? std::numeric_limits<double>::quiet_NaN() : PyFloat_AsDouble( a1 );
128 double z = a2 == Py_None ? std::numeric_limits<double>::quiet_NaN() : PyFloat_AsDouble( a2 );
129 double m = a3 == Py_None ? std::numeric_limits<double>::quiet_NaN() : PyFloat_AsDouble( a3 );
131 sipCpp =
new sipQgsPoint(
QgsPoint( x, y, z, m, wkbType ) );
135 PyErr_SetString( PyExc_TypeError, QStringLiteral(
"Invalid type in constructor arguments." ).toUtf8().constData() );
156 explicit QgsPoint(
QgsWkbTypes::Type wkbType,
double x = std::numeric_limits<double>::quiet_NaN(),
double y = std::numeric_limits<double>::quiet_NaN(),
double z = std::numeric_limits<double>::quiet_NaN(),
double m = std::numeric_limits<double>::quiet_NaN() )
SIP_SKIP;
160 const QgsPoint *pt = qgsgeometry_cast< const QgsPoint * >( &other );
169 const bool nan1X = std::isnan( mX );
170 const bool nan2X = std::isnan( pt->
x() );
171 if ( nan1X != nan2X )
176 const bool nan1Y = std::isnan( mY );
177 const bool nan2Y = std::isnan( pt->
y() );
178 if ( nan1Y != nan2Y )
185 const bool nan1Z = std::isnan( mZ );
186 const bool nan2Z = std::isnan( pt->
z() );
187 if ( nan1Z != nan2Z )
195 const bool nan1M = std::isnan( mM );
196 const bool nan2M = std::isnan( pt->
m() );
197 if ( nan1M != nan2M )
333 return QPointF( mX, mY );
345 return std::sqrt( ( mX - x ) * ( mX - x ) + ( mY - y ) * ( mY - y ) );
357 return std::sqrt( ( mX - other.x() ) * ( mX - other.x() ) + ( mY - other.y() ) * ( mY - other.y() ) );
369 return ( mX - x ) * ( mX - x ) + ( mY - y ) * ( mY - y );
381 return ( mX - other.x() ) * ( mX - other.x() ) + ( mY - other.y() ) * ( mY - other.y() );
391 double distance3D(
double x,
double y,
double z )
const SIP_HOLDGIL;
409 double distanceSquared3D(
double x,
double y,
double z )
const SIP_HOLDGIL;
463 QgsPoint project(
double distance,
double azimuth,
double inclination = 90.0 ) const
SIP_HOLDGIL;
502 QgsPoint *snappedToGrid(
double hSpacing,
double vSpacing,
double dSpacing = 0,
double mSpacing = 0 ) const override
SIP_FACTORY;
503 bool removeDuplicateNodes(
double epsilon = 4 * std::numeric_limits<
double>::epsilon(),
bool useZValues = false ) override;
504 void clear() override;
506 bool fromWkt( const QString &wkt ) override;
509 QString asWkt(
int precision = 17 ) const override;
513 QString asKml(
int precision = 17 ) const override;
514 void draw( QPainter &p ) const override;
515 QPainterPath asQPainterPath() const override;
517 void transform( const QTransform &t,
double zTranslate = 0.0,
double zScale = 1.0,
double mTranslate = 0.0,
double mScale = 1.0 ) override;
520 int vertexNumberFromVertexId(
QgsVertexId id ) const override;
522 bool isValid( QString &error
SIP_OUT,
Qgis::GeometryValidityFlags flags =
Qgis::GeometryValidityFlags() ) const override
SIP_HOLDGIL;
527 bool deleteVertex(
QgsVertexId position ) override;
538 double vertexAngle(
QgsVertexId vertex ) const override;
540 int vertexCount(
int = 0,
int = 0 ) const override;
541 int ringCount(
int = 0 ) const override;
542 int partCount() const override;
545 double segmentLength(
QgsVertexId startVertex ) const override;
548 bool addZValue(
double zValue = 0 ) override;
549 bool addMValue(
double mValue = 0 ) override;
550 bool dropZValue() override;
551 bool dropMValue() override;
552 void swapXy() override;
572 return static_cast<const QgsPoint *
>( geom );
580 SIP_PYOBJECT __repr__();
582 QString
str = QStringLiteral(
"<QgsPoint: %1>" ).arg( sipCpp->asWkt() );
583 sipRes = PyUnicode_FromString(
str.toUtf8().constData() );
The Qgis class provides global constants for use throughout the application.
Abstract base class for all geometries.
virtual QgsPoint childPoint(int index) const
Returns point at index (for geometries without child geometries - i.e.
bool is3D() const SIP_HOLDGIL
Returns true if the geometry is 3D and contains a z-value.
virtual int childCount() const
Returns number of child geometries (for geometries with child geometries) or child points (for geomet...
virtual void transformVertices(const std::function< QgsPoint(const QgsPoint &) > &transform)
Transforms the vertices from the geometry in place, applying the transform function to every vertex.
virtual QgsAbstractGeometry * createEmptyWithSameType() const =0
Creates a new geometry with the same class and same WKB type as the original and transfers ownership.
virtual void clearCache() const
Clears any cached parameters associated with the geometry, e.g., bounding boxes.
virtual void normalize()=0
Reorganizes the geometry into a normalized form (or "canonical" form).
virtual void filterVertices(const std::function< bool(const QgsPoint &) > &filter)
Filters the vertices from the geometry in place, removing any which do not return true for the filter...
QgsWkbTypes::Type wkbType() const SIP_HOLDGIL
Returns the WKB type of the geometry.
virtual bool operator==(const QgsAbstractGeometry &other) const =0
virtual int compareToSameClass(const QgsAbstractGeometry *other) const =0
Compares to an other geometry of the same class, and returns a integer for sorting of the two geometr...
bool isMeasure() const SIP_HOLDGIL
Returns true if the geometry contains m values.
Custom exception class for Coordinate Reference System related exceptions.
Base class for feedback objects to be used for cancellation of something running in a worker thread.
A class to represent a 2D point.
Point geometry type, with support for z-dimension and m-values.
double distance(double x, double y) const SIP_HOLDGIL
Returns the Cartesian 2D distance between this point and a specified x, y coordinate.
double m() const SIP_HOLDGIL
Returns the point's m value.
double & rx()
Returns a reference to the x-coordinate of this point.
QPointF toQPointF() const SIP_HOLDGIL
Returns the point as a QPointF.
QgsPoint & operator+=(QgsVector v) SIP_HOLDGIL
Adds a vector to this point in place.
void setX(double x) SIP_HOLDGIL
Sets the point's x-coordinate.
double distance(const QgsPoint &other) const SIP_HOLDGIL
Returns the Cartesian 2D distance between this point and another point.
void setY(double y) SIP_HOLDGIL
Sets the point's y-coordinate.
void setZ(double z) SIP_HOLDGIL
Sets the point's z-coordinate.
static const QgsPoint * cast(const QgsAbstractGeometry *geom)
Cast the geom to a QgsPoint.
QgsPoint operator-(QgsVector v) const SIP_HOLDGIL
Subtracts a vector from this point.
double y() const SIP_HOLDGIL
Returns the point's y-coordinate.
double distanceSquared(const QgsPoint &other) const SIP_HOLDGIL
Returns the Cartesian 2D squared distance between this point another point.
double distanceSquared(double x, double y) const SIP_HOLDGIL
Returns the Cartesian 2D squared distance between this point a specified x, y coordinate.
QgsPoint operator+(QgsVector v) const SIP_HOLDGIL
Adds a vector to this point.
double x() const SIP_HOLDGIL
Returns the point's x-coordinate.
double z() const SIP_HOLDGIL
Returns the point's z-coordinate.
QgsPoint & operator-=(QgsVector v) SIP_HOLDGIL
Subtracts a vector from this point in place.
double & ry()
Returns a reference to the y-coordinate of this point.
bool operator!=(const QgsAbstractGeometry &other) const override SIP_HOLDGIL
void setM(double m) SIP_HOLDGIL
Sets the point's m-value.
double & rz()
Returns a reference to the z-coordinate of this point.
double & rm()
Returns a reference to the m value of this point.
A rectangle specified with double values.
A class to represent a vector.
Handles storage of information regarding WKB types and their properties.
static bool hasM(Type type) SIP_HOLDGIL
Tests whether a WKB type contains m values.
Type
The WKB type describes the number of dimensions a geometry has.
static Type flatType(Type type) SIP_HOLDGIL
Returns the flat type for a WKB type.
static bool hasZ(Type type) SIP_HOLDGIL
Tests whether a WKB type contains the z-dimension.
double ANALYSIS_EXPORT leftOf(const QgsPoint &thepoint, const QgsPoint *p1, const QgsPoint *p2)
Returns whether 'thepoint' is left or right of the line from 'p1' to 'p2'. Negative values mean left ...
bool qgsDoubleNear(double a, double b, double epsilon=4 *std::numeric_limits< double >::epsilon())
Compare two doubles (but allow some difference)
#define SIP_TYPEHINT(type)
#define SIP_THROW(name,...)
QVector< QgsRingSequence > QgsCoordinateSequence
double closestSegment(const QgsPolylineXY &pl, const QgsPointXY &pt, int &vertexAfter, double epsilon)
Utility class for identifying a unique vertex within a geometry.