api/qgsdistancearea_8cpp_source.html

/***************************************************************************

  qgsdistancearea.cpp - Distance and area calculations on the ellipsoid

 ---------------------------------------------------------------------------

  Date                 : September 2005

  Copyright            : (C) 2005 by Martin Dobias

  email                : won.der at centrum.sk

 ***************************************************************************

 *                                                                         *

 *   This program is free software; you can redistribute it and/or modify  *

 *   it under the terms of the GNU General Public License as published by  *

 *   the Free Software Foundation; either version 2 of the License, or     *

 *   (at your option) any later version.                                   *

 *                                                                         *

 ***************************************************************************/


#include "qgsdistancearea.h"


#include <cmath>

#include <geodesic.h>

#include <memory>


#include "qgis.h"

#include "qgscoordinatereferencesystem.h"

#include "qgscoordinatetransform.h"

#include "qgscurvepolygon.h"

#include "qgsexception.h"

#include "qgsgeometry.h"

#include "qgsgeometrycollection.h"

#include "qgslinestring.h"

#include "qgslogger.h"

#include "qgsmessagelog.h"

#include "qgsmultilinestring.h"

#include "qgsmultisurface.h"

#include "qgspointxy.h"

#include "qgspolygon.h"

#include "qgssurface.h"

#include "qgsunittypes.h"


#include <QObject>

#include <QString>


using namespace Qt::StringLiterals;


#define DEG2RAD( x ) ( ( x ) * M_PI / 180 )

#define RAD2DEG( r ) ( 180.0 * ( r ) / M_PI )

#define POW2( x ) ( ( x ) * ( x ) )


QgsDistanceArea::QgsDistanceArea()

{

  // init with default settings

  mSemiMajor = -1.0;

  mSemiMinor = -1.0;

  mInvFlattening = -1.0;

  const QgsCoordinateTransformContext context;                             // this is ok - by default we have a source/dest of WGS84, so no reprojection takes place

  setSourceCrs( QgsCoordinateReferenceSystem( u"EPSG:4326"_s ), context ); // WGS 84

  setEllipsoid( Qgis::geoNone() );

}


QgsDistanceArea::~QgsDistanceArea() = default;


QgsDistanceArea::QgsDistanceArea( const QgsDistanceArea &other )

  //****** IMPORTANT! editing this? make sure you update the move constructor too! *****

  : mCachedSourceToEllipsoid( other.mCachedSourceToEllipsoid )

  , mEllipsoid( other.mEllipsoid )

  , mSemiMajor( other.mSemiMajor )

  , mSemiMinor( other.mSemiMinor )

  , mInvFlattening( other.mInvFlattening )

  , mDestinationCrs( other.mDestinationCrs )

  , mSourceCrs( other.mSourceCrs )

  , mCoordTransformContext( other.mCoordTransformContext )

  , mCoordTransformDirty( other.mCoordTransformDirty )

//****** IMPORTANT! editing this? make sure you update the move constructor too! *****

{

  computeAreaInit();

}


QgsDistanceArea::QgsDistanceArea( QgsDistanceArea &&other )

  : mCachedSourceToEllipsoid( std::move( other.mCachedSourceToEllipsoid ) )

  , mEllipsoid( std::move( other.mEllipsoid ) )

  , mSemiMajor( other.mSemiMajor )

  , mSemiMinor( other.mSemiMinor )

  , mInvFlattening( other.mInvFlattening )

  , mGeod( std::move( other.mGeod ) )

  , mDestinationCrs( std::move( other.mDestinationCrs ) )

  , mSourceCrs( std::move( other.mSourceCrs ) )

  , mCoordTransformContext( std::move( other.mCoordTransformContext ) )

  , mCoordTransformDirty( other.mCoordTransformDirty )

{}


QgsDistanceArea &QgsDistanceArea::operator=( const QgsDistanceArea &other )

{

  if ( &other == this )

    return *this;


  //****** IMPORTANT! editing this? make sure you update the move assignment operator too! *****

  mCachedSourceToEllipsoid = other.mCachedSourceToEllipsoid;

  mEllipsoid = other.mEllipsoid;

  mSemiMajor = other.mSemiMajor;

  mSemiMinor = other.mSemiMinor;

  mInvFlattening = other.mInvFlattening;

  mDestinationCrs = other.mDestinationCrs;

  mSourceCrs = other.mSourceCrs;

  mCoordTransformContext = other.mCoordTransformContext;

  mCoordTransformDirty = other.mCoordTransformDirty;

  computeAreaInit();

  //****** IMPORTANT! editing this? make sure you update the move assignment operator too! *****

  return *this;

}


QgsDistanceArea &QgsDistanceArea::operator=( QgsDistanceArea &&other )

{

  if ( &other == this )

    return *this;


  mCachedSourceToEllipsoid = other.mCachedSourceToEllipsoid;

  mEllipsoid = other.mEllipsoid;

  mSemiMajor = other.mSemiMajor;

  mSemiMinor = other.mSemiMinor;

  mInvFlattening = other.mInvFlattening;

  mSourceCrs = other.mSourceCrs;

  mDestinationCrs = other.mDestinationCrs;

  mCoordTransformContext = other.mCoordTransformContext;

  mCoordTransformDirty = other.mCoordTransformDirty;

  mGeod = std::move( other.mGeod );

  return *this;

}


bool QgsDistanceArea::willUseEllipsoid() const

{

  return mEllipsoid != Qgis::geoNone();

}


void QgsDistanceArea::setSourceCrs( const QgsCoordinateReferenceSystem &srcCRS, const QgsCoordinateTransformContext &context )

{

  mSourceCrs = srcCRS;

  mCoordTransformContext = context;

  mCoordTransformDirty = true;

}


bool QgsDistanceArea::setEllipsoid( const QString &ellipsoid )

{

  // Shortcut if ellipsoid is none.

  if ( ellipsoid == Qgis::geoNone() )

  {

    mEllipsoid = Qgis::geoNone();

    mDestinationCrs = QgsCoordinateReferenceSystem();

    mCoordTransformDirty = true;

    mGeod.reset();

    return true;

  }


  const QgsEllipsoidUtils::EllipsoidParameters params = QgsEllipsoidUtils::ellipsoidParameters( ellipsoid );

  if ( !params.valid )

  {

    mGeod.reset();

    return false;

  }

  else

  {

    mEllipsoid = ellipsoid;

    setFromParams( params );

    return true;

  }

}


// Inverse flattening is calculated with invf = a/(a-b)

// Also, b = a-(a/invf)


bool QgsDistanceArea::setEllipsoid( double semiMajor, double semiMinor )

{

  mEllipsoid = u"PARAMETER:%1:%2"_s.arg( qgsDoubleToString( semiMajor ), qgsDoubleToString( semiMinor ) );


  QgsEllipsoidUtils::EllipsoidParameters params = QgsEllipsoidUtils::ellipsoidParameters( mEllipsoid );


  setFromParams( params );


  return true;

}


double QgsDistanceArea::measure( const QgsAbstractGeometry *geomV2, MeasureType type ) const

{

  if ( !geomV2 )

  {

    return 0.0;

  }


  const int geomDimension = geomV2->dimension();

  if ( geomDimension <= 0 )

  {

    return 0.0;

  }


  MeasureType measureType = type;

  if ( measureType == Default )

  {

    measureType = ( geomDimension == 1 ? Length : Area );

  }


  if ( !willUseEllipsoid() )

  {

    //no transform required

    if ( measureType == Length )

    {

      return geomV2->length();

    }

    else

    {

      return geomV2->area();

    }

  }

  else

  {

    //multigeom is sum of measured parts

    const QgsGeometryCollection *collection = qgsgeometry_cast<const QgsGeometryCollection *>( geomV2 );

    if ( collection )

    {

      double sum = 0;

      for ( int i = 0; i < collection->numGeometries(); ++i )

      {

        sum += measure( collection->geometryN( i ), measureType );

      }

      return sum;

    }


    if ( measureType == Length )

    {

      const QgsCurve *curve = qgsgeometry_cast<const QgsCurve *>( geomV2 );

      if ( !curve )

      {

        return 0.0;

      }


      QgsLineString *lineString = curve->curveToLine();

      const double length = measureLine( lineString );

      delete lineString;

      return length;

    }

    else

    {

      const QgsSurface *surface = qgsgeometry_cast<const QgsSurface *>( geomV2 );

      if ( !surface )

        return 0.0;


      double area = 0;

      const QgsCurvePolygon *curvePolygon = qgsgeometry_cast<const QgsCurvePolygon *>( surface );

      if ( curvePolygon )

      {

        QgsPolygon *polygon = curvePolygon->surfaceToPolygon();


        const QgsCurve *outerRing = polygon->exteriorRing();

        area += measurePolygon( outerRing );


        for ( int i = 0; i < polygon->numInteriorRings(); ++i )

        {

          const QgsCurve *innerRing = polygon->interiorRing( i );

          area -= measurePolygon( innerRing );

        }

        delete polygon;

      }

      return area;

    }

  }

}


double QgsDistanceArea::measureArea( const QgsGeometry &geometry ) const

{

  if ( geometry.isNull() )

    return 0.0;


  const QgsAbstractGeometry *geomV2 = geometry.constGet();

  return measure( geomV2, Area );

}


double QgsDistanceArea::measureLength( const QgsGeometry &geometry ) const

{

  if ( geometry.isNull() )

    return 0.0;


  const QgsAbstractGeometry *geomV2 = geometry.constGet();

  return measure( geomV2, Length );

}


double QgsDistanceArea::measurePerimeter( const QgsGeometry &geometry ) const

{

  if ( geometry.isNull() )

    return 0.0;


  const QgsAbstractGeometry *geomV2 = geometry.constGet();

  if ( !geomV2 || geomV2->dimension() < 2 )

  {

    return 0.0;

  }


  if ( !willUseEllipsoid() )

  {

    return geomV2->perimeter();

  }


  //create list with (single) surfaces

  QVector< const QgsSurface * > surfaces;

  const QgsSurface *surf = qgsgeometry_cast<const QgsSurface *>( geomV2 );

  if ( surf )

  {

    surfaces.append( surf );

  }

  const QgsMultiSurface *multiSurf = qgsgeometry_cast<const QgsMultiSurface *>( geomV2 );

  if ( multiSurf )

  {

    surfaces.reserve( ( surf ? 1 : 0 ) + multiSurf->numGeometries() );

    for ( int i = 0; i < multiSurf->numGeometries(); ++i )

    {

      surfaces.append( static_cast<const QgsSurface *>( multiSurf->geometryN( i ) ) );

    }

  }


  double length = 0;

  QVector<const QgsSurface *>::const_iterator surfaceIt = surfaces.constBegin();

  for ( ; surfaceIt != surfaces.constEnd(); ++surfaceIt )

  {

    if ( !*surfaceIt )

    {

      continue;

    }


    const QgsCurvePolygon *curvePolygon = qgsgeometry_cast<const QgsCurvePolygon *>( *surfaceIt );

    if ( curvePolygon )

    {

      QgsPolygon *poly = curvePolygon->surfaceToPolygon();

      const QgsCurve *outerRing = poly->exteriorRing();

      if ( outerRing )

      {

        length += measure( outerRing );

      }

      const int nInnerRings = poly->numInteriorRings();

      for ( int i = 0; i < nInnerRings; ++i )

      {

        length += measure( poly->interiorRing( i ) );

      }

      delete poly;

    }

  }

  return length;

}


double QgsDistanceArea::measureLine( const QgsCurve *curve ) const

{

  if ( !curve )

  {

    return 0.0;

  }


  QgsPointSequence linePointsV2;

  QVector<QgsPointXY> linePoints;

  curve->points( linePointsV2 );

  QgsGeometry::convertPointList( linePointsV2, linePoints );

  return measureLine( linePoints );

}


double QgsDistanceArea::measureLine( const QVector<QgsPointXY> &points ) const

{

  if ( points.size() < 2 )

    return 0;


  double total = 0;

  QgsPointXY p1, p2;


  if ( willUseEllipsoid() )

  {

    if ( !mGeod )

      computeAreaInit();

    Q_ASSERT_X( static_cast<bool>( mGeod ), "QgsDistanceArea::measureLine()", "Error creating geod_geodesic object" );

    if ( !mGeod )

      return 0;

  }


  QgsCoordinateTransform sourceToEllipsoidTransform = sourceToEllipsoid();


  if ( willUseEllipsoid() )

    p1 = sourceToEllipsoidTransform.transform( points[0] );

  else

    p1 = points[0];


  for ( QVector<QgsPointXY>::const_iterator i = points.constBegin(); i != points.constEnd(); ++i )

  {

    if ( willUseEllipsoid() )

    {

      p2 = sourceToEllipsoidTransform.transform( *i );


      double distance = 0;

      double azimuth1 = 0;

      double azimuth2 = 0;

      geod_inverse( mGeod.get(), p1.y(), p1.x(), p2.y(), p2.x(), &distance, &azimuth1, &azimuth2 );

      total += distance;

    }

    else

    {

      p2 = *i;

      total += measureLine( p1, p2 );

    }


    p1 = p2;

  }


  return total;

}


double QgsDistanceArea::measureLine( const QgsPointXY &p1, const QgsPointXY &p2 ) const

{

  double result;


  if ( willUseEllipsoid() )

  {

    if ( !mGeod )

      computeAreaInit();

    Q_ASSERT_X( static_cast<bool>( mGeod ), "QgsDistanceArea::measureLine()", "Error creating geod_geodesic object" );

    if ( !mGeod )

      return 0;

  }


  QgsPointXY pp1 = p1, pp2 = p2;


  QgsDebugMsgLevel( u"Measuring from %1 to %2"_s.arg( p1.toString( 4 ), p2.toString( 4 ) ), 3 );

  if ( willUseEllipsoid() )

  {

    QgsCoordinateTransform sourceToEllipsoidTransform = sourceToEllipsoid();

    QgsDebugMsgLevel( u"Ellipsoidal calculations is enabled, using ellipsoid %1"_s.arg( mEllipsoid ), 4 );

    QgsDebugMsgLevel( u"From proj4 : %1"_s.arg( sourceToEllipsoidTransform.sourceCrs().toProj() ), 4 );

    QgsDebugMsgLevel( u"To   proj4 : %1"_s.arg( sourceToEllipsoidTransform.destinationCrs().toProj() ), 4 );

    pp1 = sourceToEllipsoidTransform.transform( p1 );

    pp2 = sourceToEllipsoidTransform.transform( p2 );

    QgsDebugMsgLevel( u"New points are %1 and %2, calculating..."_s.arg( pp1.toString( 4 ), pp2.toString( 4 ) ), 4 );


    double azimuth1 = 0;

    double azimuth2 = 0;

    geod_inverse( mGeod.get(), pp1.y(), pp1.x(), pp2.y(), pp2.x(), &result, &azimuth1, &azimuth2 );

  }

  else

  {

    QgsDebugMsgLevel( u"Cartesian calculation on canvas coordinates"_s, 4 );

    result = p2.distance( p1 );

  }


  QgsDebugMsgLevel( u"The result was %1"_s.arg( result ), 3 );

  return result;

}


double QgsDistanceArea::measureLineProjected( const QgsPointXY &p1, double distance, double azimuth, QgsPointXY *projectedPoint ) const

{

  QgsCoordinateTransform sourceToEllipsoidTransform = sourceToEllipsoid();


  double result = 0.0;

  QgsPointXY p2;

  if ( sourceToEllipsoidTransform.sourceCrs().isGeographic() && willUseEllipsoid() )

  {

    p2 = computeSpheroidProject( p1, distance, azimuth );

    result = p1.distance( p2 );

  }

  else // Cartesian coordinates

  {

    result = distance; // Avoid rounding errors when using meters [return as sent]

    if ( sourceCrs().mapUnits() != Qgis::DistanceUnit::Meters )

    {

      distance = ( distance * QgsUnitTypes::fromUnitToUnitFactor( Qgis::DistanceUnit::Meters, sourceCrs().mapUnits() ) );

      p2 = p1.project( distance, azimuth );

      result = p1.distance( p2 );

    }

    else

    {

      p2 = p1.project( distance, azimuth );

    }

  }

  QgsDebugMsgLevel(

    u"Converted distance of %1 %2 to %3 distance %4 %5, using azimuth[%6] from point[%7] to point[%8] sourceCrs[%9] mEllipsoid[%10] isGeographic[%11] [%12]"_s

      .arg(

        QString::number( distance, 'f', 7 ),

        QgsUnitTypes::toString( Qgis::DistanceUnit::Meters ),

        QString::number( result, 'f', 7 ),

        sourceToEllipsoid().sourceCrs().isGeographic() ? u"Geographic"_s : u"Cartesian"_s,

        QgsUnitTypes::toString( sourceCrs().mapUnits() )

      )

      .arg( azimuth )

      .arg( p1.asWkt(), p2.asWkt(), sourceCrs().description(), mEllipsoid )

      .arg( sourceCrs().isGeographic() )

      .arg( u"SemiMajor[%1] SemiMinor[%2] InvFlattening[%3] "_s.arg( QString::number( mSemiMajor, 'f', 7 ), QString::number( mSemiMinor, 'f', 7 ), QString::number( mInvFlattening, 'f', 7 ) ) ),

    4

  );

  if ( projectedPoint )

  {

    *projectedPoint = QgsPointXY( p2 );

  }

  return result;

}


QgsPointXY QgsDistanceArea::computeSpheroidProject( const QgsPointXY &p1, double distance, double azimuth ) const

{

  if ( !mGeod )

    computeAreaInit();

  if ( !mGeod )

    return QgsPointXY();


  double lat2 = 0;

  double lon2 = 0;

  double azimuth2 = 0;

  geod_direct( mGeod.get(), p1.y(), p1.x(), RAD2DEG( azimuth ), distance, &lat2, &lon2, &azimuth2 );


  return QgsPointXY( lon2, lat2 );

}


double QgsDistanceArea::latitudeGeodesicCrossesAntimeridian( const QgsPointXY &pp1, const QgsPointXY &pp2, double &fractionAlongLine ) const

{

  QgsPointXY p1 = pp1;

  QgsPointXY p2 = pp2;

  if ( p1.x() < -120 )

    p1.setX( p1.x() + 360 );

  if ( p2.x() < -120 )

    p2.setX( p2.x() + 360 );


  // we need p2.x() > 180 and p1.x() < 180

  double p1x = p1.x() < 180 ? p1.x() : p2.x();

  double p1y = p1.x() < 180 ? p1.y() : p2.y();

  double p2x = p1.x() < 180 ? p2.x() : p1.x();

  double p2y = p1.x() < 180 ? p2.y() : p1.y();

  // lat/lon are our candidate intersection position - we want this to get as close to 180 as possible

  // the first candidate is p2

  double lat = p2y;

  double lon = p2x;


  if ( mEllipsoid == Qgis::geoNone() )

  {

    fractionAlongLine = ( 180 - p1x ) / ( p2x - p1x );

    if ( p1.x() >= 180 )

      fractionAlongLine = 1 - fractionAlongLine;

    return p1y + ( 180 - p1x ) / ( p2x - p1x ) * ( p2y - p1y );

  }


  if ( !mGeod )

    computeAreaInit();

  Q_ASSERT_X( static_cast<bool>( mGeod ), "QgsDistanceArea::latitudeGeodesicCrossesAntimeridian()", "Error creating geod_geodesic object" );

  if ( !mGeod )

    return 0;


  geod_geodesicline line;

  geod_inverseline( &line, mGeod.get(), p1y, p1x, p2y, p2x, GEOD_ALL );


  const double totalDist = line.s13;

  double intersectionDist = line.s13;


  int iterations = 0;

  double t = 0;

  // iterate until our intersection candidate is within ~1 mm of the antimeridian (or too many iterations happened)

  while ( std::fabs( lon - 180.0 ) > 0.00000001 && iterations < 100 )

  {

    if ( iterations > 0 && std::fabs( p2x - p1x ) > 5 )

    {

      // if we have too large a range of longitudes, we use a binary search to narrow the window -- this ensures we will converge

      if ( lon < 180 )

      {

        p1x = lon;

        p1y = lat;

      }

      else

      {

        p2x = lon;

        p2y = lat;

      }

      QgsDebugMsgLevel( u"Narrowed window to %1, %2 - %3, %4"_s.arg( p1x ).arg( p1y ).arg( p2x ).arg( p2y ), 4 );


      geod_inverseline( &line, mGeod.get(), p1y, p1x, p2y, p2x, GEOD_ALL );

      intersectionDist = line.s13 * 0.5;

    }

    else

    {

      // we have a sufficiently narrow window -- use Newton's method

      // adjust intersection distance by fraction of how close the previous candidate was to 180 degrees longitude -

      // this helps us close in to the correct longitude quickly

      intersectionDist *= ( 180.0 - p1x ) / ( lon - p1x );

    }


    // now work out the point on the geodesic this far from p1 - this becomes our new candidate for crossing the antimeridian


    geod_position( &line, intersectionDist, &lat, &lon, &t );

    // we don't want to wrap longitudes > 180 around)

    if ( lon < 0 )

      lon += 360;


    iterations++;

    QgsDebugMsgLevel( u"After %1 iterations lon is %2, lat is %3, dist from p1: %4"_s.arg( iterations ).arg( lon ).arg( lat ).arg( intersectionDist ), 4 );

  }


  fractionAlongLine = intersectionDist / totalDist;

  if ( p1.x() >= 180 )

    fractionAlongLine = 1 - fractionAlongLine;


  // either converged on 180 longitude or hit too many iterations

  return lat;

}


QgsGeometry QgsDistanceArea::splitGeometryAtAntimeridian( const QgsGeometry &geometry ) const

{

  QgsCoordinateTransform sourceToEllipsoidTransform = sourceToEllipsoid();


  if ( QgsWkbTypes::geometryType( geometry.wkbType() ) != Qgis::GeometryType::Line )

    return geometry;


  QgsGeometry g = geometry;

  // TODO - avoid segmentization of curved geometries (if this is even possible!)

  if ( QgsWkbTypes::isCurvedType( g.wkbType() ) )

    g.convertToStraightSegment();


  auto res = std::make_unique< QgsMultiLineString >();

  for ( auto part = g.const_parts_begin(); part != g.const_parts_end(); ++part )

  {

    const QgsLineString *line = qgsgeometry_cast< const QgsLineString * >( *part );

    if ( !line )

      continue;

    if ( line->isEmpty() )

    {

      continue;

    }


    const std::unique_ptr< QgsLineString > l = std::make_unique< QgsLineString >();

    try

    {

      double x = 0;

      double y = 0;

      double z = 0;

      double m = 0;

      QVector< QgsPoint > newPoints;

      newPoints.reserve( line->numPoints() );

      double prevLon = 0;

      double prevLat = 0;

      double lon = 0;

      double lat = 0;

      double prevZ = 0;

      double prevM = 0;

      for ( int i = 0; i < line->numPoints(); i++ )

      {

        QgsPoint p = line->pointN( i );

        x = p.x();

        if ( sourceToEllipsoidTransform.sourceCrs().isGeographic() )

        {

          x = std::fmod( x, 360.0 );

          if ( x > 180 )

            x -= 360;

          p.setX( x );

        }

        y = p.y();

        lon = x;

        lat = y;

        sourceToEllipsoidTransform.transformInPlace( lon, lat, z );


        //test if we crossed the antimeridian in this segment

        if ( i > 0 && ( ( prevLon < -120 && lon > 120 ) || ( prevLon > 120 && lon < -120 ) ) )

        {

          // we did!

          // when crossing the antimeridian, we need to calculate the latitude

          // at which the geodesic intersects the antimeridian

          double fract = 0;

          const double lat180 = latitudeGeodesicCrossesAntimeridian( QgsPointXY( prevLon, prevLat ), QgsPointXY( lon, lat ), fract );

          if ( line->is3D() )

          {

            z = prevZ + ( p.z() - prevZ ) * fract;

          }

          if ( line->isMeasure() )

          {

            m = prevM + ( p.m() - prevM ) * fract;

          }


          QgsPointXY antiMeridianPoint;

          if ( prevLon < -120 )

            antiMeridianPoint = sourceToEllipsoidTransform.transform( QgsPointXY( -180, lat180 ), Qgis::TransformDirection::Reverse );

          else

            antiMeridianPoint = sourceToEllipsoidTransform.transform( QgsPointXY( 180, lat180 ), Qgis::TransformDirection::Reverse );


          QgsPoint newPoint( antiMeridianPoint );

          if ( line->is3D() )

            newPoint.addZValue( z );

          if ( line->isMeasure() )

            newPoint.addMValue( m );


          if ( std::isfinite( newPoint.x() ) && std::isfinite( newPoint.y() ) )

          {

            newPoints << newPoint;

          }

          res->addGeometry( new QgsLineString( newPoints ) );


          newPoints.clear();

          newPoints.reserve( line->numPoints() - i + 1 );


          if ( lon < -120 )

            antiMeridianPoint = sourceToEllipsoidTransform.transform( QgsPointXY( -180, lat180 ), Qgis::TransformDirection::Reverse );

          else

            antiMeridianPoint = sourceToEllipsoidTransform.transform( QgsPointXY( 180, lat180 ), Qgis::TransformDirection::Reverse );


          if ( std::isfinite( antiMeridianPoint.x() ) && std::isfinite( antiMeridianPoint.y() ) )

          {

            // we want to keep the previously calculated z/m value for newPoint, if present. They're the same each

            // of the antimeridian split

            newPoint.setX( antiMeridianPoint.x() );

            newPoint.setY( antiMeridianPoint.y() );

            newPoints << newPoint;

          }

        }

        newPoints << p;


        prevLon = lon;

        prevLat = lat;

        if ( line->is3D() )

          prevZ = p.z();

        if ( line->isMeasure() )

          prevM = p.m();

      }

      res->addGeometry( new QgsLineString( newPoints ) );

    }

    catch ( QgsCsException & )

    {

      QgsMessageLog::logMessage( QObject::tr( "Caught a coordinate system exception while trying to transform linestring. Unable to calculate break point." ) );

      res->addGeometry( line->clone() );

      break;

    }

  }


  return QgsGeometry( std::move( res ) );

}


QVector< QVector<QgsPointXY> > QgsDistanceArea::geodesicLine( const QgsPointXY &p1, const QgsPointXY &p2, const double interval, const bool breakLine ) const

{

  QgsCoordinateTransform sourceToEllipsoidTransform = sourceToEllipsoid();


  if ( !willUseEllipsoid() )

  {

    return QVector< QVector< QgsPointXY > >() << ( QVector< QgsPointXY >() << p1 << p2 );

  }


  if ( !mGeod )

    computeAreaInit();

  if ( !mGeod )

    return QVector< QVector< QgsPointXY > >();


  QgsPointXY pp1, pp2;

  try

  {

    pp1 = sourceToEllipsoidTransform.transform( p1 );

    pp2 = sourceToEllipsoidTransform.transform( p2 );

  }

  catch ( QgsCsException & )

  {

    QgsMessageLog::logMessage( QObject::tr( "Caught a coordinate system exception while trying to transform a point. Unable to calculate geodesic line." ) );

    return QVector< QVector< QgsPointXY > >();

  }


  geod_geodesicline line;

  geod_inverseline( &line, mGeod.get(), pp1.y(), pp1.x(), pp2.y(), pp2.x(), GEOD_ALL );

  const double totalDist = line.s13;


  QVector< QVector< QgsPointXY > > res;

  QVector< QgsPointXY > currentPart;

  currentPart << p1;

  double d = interval;

  double prevLon = pp1.x();

  double prevLat = pp1.y();

  bool lastRun = false;

  double t = 0;

  while ( true )

  {

    double lat, lon;

    if ( lastRun )

    {

      lat = pp2.y();

      lon = pp2.x();

      if ( lon > 180 )

        lon -= 360;

    }

    else

    {

      geod_position( &line, d, &lat, &lon, &t );

    }


    if ( breakLine && ( ( prevLon < -120 && lon > 120 ) || ( prevLon > 120 && lon < -120 ) ) )

    {

      // when breaking the geodesic at the antimeridian, we need to calculate the latitude

      // at which the geodesic intersects the antimeridian, and add points to both line segments at this latitude

      // on the antimeridian.

      double fraction;

      const double lat180 = latitudeGeodesicCrossesAntimeridian( QgsPointXY( prevLon, prevLat ), QgsPointXY( lon, lat ), fraction );


      try

      {

        QgsPointXY p;

        if ( prevLon < -120 )

          p = sourceToEllipsoidTransform.transform( QgsPointXY( -180, lat180 ), Qgis::TransformDirection::Reverse );

        else

          p = sourceToEllipsoidTransform.transform( QgsPointXY( 180, lat180 ), Qgis::TransformDirection::Reverse );


        if ( std::isfinite( p.x() ) && std::isfinite( p.y() ) )

          currentPart << p;

      }

      catch ( QgsCsException & )

      {

        QgsMessageLog::logMessage( QObject::tr( "Caught a coordinate system exception while trying to transform a point." ) );

      }


      res << currentPart;

      currentPart.clear();

      try

      {

        QgsPointXY p;

        if ( lon < -120 )

          p = sourceToEllipsoidTransform.transform( QgsPointXY( -180, lat180 ), Qgis::TransformDirection::Reverse );

        else

          p = sourceToEllipsoidTransform.transform( QgsPointXY( 180, lat180 ), Qgis::TransformDirection::Reverse );


        if ( std::isfinite( p.x() ) && std::isfinite( p.y() ) )

          currentPart << p;

      }

      catch ( QgsCsException & )

      {

        QgsMessageLog::logMessage( QObject::tr( "Caught a coordinate system exception while trying to transform a point." ) );

      }

    }


    prevLon = lon;

    prevLat = lat;


    try

    {

      currentPart << sourceToEllipsoidTransform.transform( QgsPointXY( lon, lat ), Qgis::TransformDirection::Reverse );

    }

    catch ( QgsCsException & )

    {

      QgsMessageLog::logMessage( QObject::tr( "Caught a coordinate system exception while trying to transform a point." ) );

    }


    if ( lastRun )

      break;


    d += interval;

    if ( d >= totalDist )

      lastRun = true;

  }

  res << currentPart;

  return res;

}


Qgis::DistanceUnit QgsDistanceArea::lengthUnits() const

{

  return willUseEllipsoid() ? Qgis::DistanceUnit::Meters : sourceToEllipsoid().sourceCrs().mapUnits();

}


Qgis::AreaUnit QgsDistanceArea::areaUnits() const

{

  return willUseEllipsoid() ? Qgis::AreaUnit::SquareMeters : QgsUnitTypes::distanceToAreaUnit( sourceToEllipsoid().sourceCrs().mapUnits() );

}


double QgsDistanceArea::measurePolygon( const QgsCurve *curve ) const

{

  if ( !curve )

  {

    return 0.0;

  }


  QgsPointSequence linePointsV2;

  curve->points( linePointsV2 );

  QVector<QgsPointXY> linePoints;

  QgsGeometry::convertPointList( linePointsV2, linePoints );

  return measurePolygon( linePoints );

}


double QgsDistanceArea::measurePolygon( const QVector<QgsPointXY> &points ) const

{

  if ( willUseEllipsoid() )

  {

    QVector<QgsPointXY> pts;

    for ( QVector<QgsPointXY>::const_iterator i = points.constBegin(); i != points.constEnd(); ++i )

    {

      pts.append( sourceToEllipsoid().transform( *i ) );

    }

    return computePolygonArea( pts );

  }

  else

  {

    return computePolygonArea( points );

  }

}


double QgsDistanceArea::bearing( const QgsPointXY &p1, const QgsPointXY &p2 ) const

{

  QgsPointXY pp1 = p1, pp2 = p2;

  double bearing;


  if ( willUseEllipsoid() )

  {

    QgsCoordinateTransform sourceToEllipsoidTransform = sourceToEllipsoid();

    pp1 = sourceToEllipsoidTransform.transform( p1 );

    pp2 = sourceToEllipsoidTransform.transform( p2 );


    if ( !mGeod )

      computeAreaInit();

    Q_ASSERT_X( static_cast<bool>( mGeod ), "QgsDistanceArea::bearing()", "Error creating geod_geodesic object" );

    if ( !mGeod )

      return 0;


    double distance = 0;

    double azimuth1 = 0;

    double azimuth2 = 0;

    geod_inverse( mGeod.get(), pp1.y(), pp1.x(), pp2.y(), pp2.x(), &distance, &azimuth1, &azimuth2 );


    bearing = DEG2RAD( azimuth1 );

  }

  else //compute simple planar azimuth

  {

    const double dx = p2.x() - p1.x();

    const double dy = p2.y() - p1.y();

    // Note: the prototype of std::atan2 is (y,x), to return the angle of

    // vector (x,y) from the horizontal axis in counter-clock-wise orientation.

    // But a bearing is expressed in clock-wise order from the vertical axis, so

    // M_PI / 2 - std::atan2( dy, dx ) == std::atan2( dx, dy )

    bearing = std::atan2( dx, dy );

  }


  return bearing;

}


void QgsDistanceArea::computeAreaInit() const

{

  //don't try to perform calculations if no ellipsoid

  if ( mEllipsoid == Qgis::geoNone() )

  {

    mGeod.reset();

    return;

  }


  mGeod = std::make_unique<geod_geodesic>();

  geod_init( mGeod.get(), mSemiMajor, 1 / mInvFlattening );

}


void QgsDistanceArea::setFromParams( const QgsEllipsoidUtils::EllipsoidParameters &params )

{

  mCoordTransformDirty = true;


  mSemiMajor = params.semiMajor;

  mSemiMinor = params.semiMinor;

  mInvFlattening = params.inverseFlattening;

  mDestinationCrs = params.crs;


  computeAreaInit();

}


double QgsDistanceArea::computePolygonArea( const QVector<QgsPointXY> &points ) const

{

  if ( points.isEmpty() )

  {

    return 0;

  }


  QgsDebugMsgLevel( "Ellipsoid: " + mEllipsoid, 3 );

  if ( !willUseEllipsoid() )

  {

    return computePolygonFlatArea( points );

  }


  if ( !mGeod )

    computeAreaInit();

  Q_ASSERT_X( static_cast<bool>( mGeod ), "QgsDistanceArea::computePolygonArea()", "Error creating geod_geodesic object" );

  if ( !mGeod )

    return 0;


  struct geod_polygon p;

  geod_polygon_init( &p, 0 );


  const bool isClosed = points.constFirst() == points.constLast();


  /* GeographicLib does not need a closed ring,

   * see example for geod_polygonarea() in geodesic.h */

  /* add points in reverse order */

  int i = points.size();

  while ( ( isClosed && --i ) || ( !isClosed && --i >= 0 ) )

    geod_polygon_addpoint( mGeod.get(), &p, points.at( i ).y(), points.at( i ).x() );


  double area = 0;

  double perimeter = 0;

  geod_polygon_compute( mGeod.get(), &p, 0, 1, &area, &perimeter );


  return std::fabs( area );

}


double QgsDistanceArea::computePolygonFlatArea( const QVector<QgsPointXY> &points ) const

{

  // Normal plane area calculations.

  double area = 0.0;

  int i, size;


  size = points.size();


  // QgsDebugMsgLevel("New area calc, nr of points: " + QString::number(size), 2);

  for ( i = 0; i < size; i++ )

  {

    // QgsDebugMsgLevel("Area from point: " + (points[i]).toString(2), 2);

    // Using '% size', so that we always end with the starting point

    // and thus close the polygon.

    area = area + points[i].x() * points[( i + 1 ) % size].y() - points[( i + 1 ) % size].x() * points[i].y();

  }

  // QgsDebugMsgLevel("Area from point: " + (points[i % size]).toString(2), 2);

  area = area / 2.0;

  return std::fabs( area ); // All areas are positive!

}


QString QgsDistanceArea::formatDistance( double distance, int decimals, Qgis::DistanceUnit unit, bool keepBaseUnit )

{

  return QgsUnitTypes::formatDistance( distance, decimals, unit, keepBaseUnit );

}


QString QgsDistanceArea::formatArea( double area, int decimals, Qgis::AreaUnit unit, bool keepBaseUnit )

{

  return QgsUnitTypes::formatArea( area, decimals, unit, keepBaseUnit );

}


double QgsDistanceArea::convertLengthMeasurement( double length, Qgis::DistanceUnit toUnits ) const

{

  // get the conversion factor between the specified units

  const Qgis::DistanceUnit measureUnits = lengthUnits();

  const double factorUnits = QgsUnitTypes::fromUnitToUnitFactor( measureUnits, toUnits );


  const double result = length * factorUnits;

  QgsDebugMsgLevel( u"Converted length of %1 %2 to %3 %4"_s.arg( length ).arg( QgsUnitTypes::toString( measureUnits ) ).arg( result ).arg( QgsUnitTypes::toString( toUnits ) ), 3 );

  return result;

}


double QgsDistanceArea::convertAreaMeasurement( double area, Qgis::AreaUnit toUnits ) const

{

  // get the conversion factor between the specified units

  const Qgis::AreaUnit measureUnits = areaUnits();

  const double factorUnits = QgsUnitTypes::fromUnitToUnitFactor( measureUnits, toUnits );


  const double result = area * factorUnits;

  QgsDebugMsgLevel( u"Converted area of %1 %2 to %3 %4"_s.arg( area ).arg( QgsUnitTypes::toString( measureUnits ) ).arg( result ).arg( QgsUnitTypes::toString( toUnits ) ), 3 );

  return result;

}


QgsCoordinateTransform QgsDistanceArea::sourceToEllipsoid() const

{

  if ( mCoordTransformDirty )

  {

    mCachedSourceToEllipsoid = QgsCoordinateTransform( mSourceCrs, mDestinationCrs, mCoordTransformContext );

    mCoordTransformDirty = false;

  }

  return mCachedSourceToEllipsoid;

}

Qgis::DistanceUnit
DistanceUnit
Units of distance.
Definition qgis.h:5416

Qgis::DistanceUnit::Meters
@ Meters
Meters.
Definition qgis.h:5417

Qgis::AreaUnit
AreaUnit
Units of area.
Definition qgis.h:5493

Qgis::AreaUnit::SquareMeters
@ SquareMeters
Square meters.
Definition qgis.h:5494

Qgis::GeometryType::Line
@ Line
Lines.
Definition qgis.h:381

Qgis::geoNone
static QString geoNone()
Constant that holds the string representation for "No ellipse/No CRS".
Definition qgis.h:6984

Qgis::TransformDirection::Reverse
@ Reverse
Reverse/inverse transform (from destination to source).
Definition qgis.h:2833

QgsAbstractGeometry
Abstract base class for all geometries.
Definition qgsabstractgeometry.h:82

QgsAbstractGeometry::isMeasure
bool isMeasure() const
Returns true if the geometry contains m values.
Definition qgsabstractgeometry.h:276

QgsAbstractGeometry::is3D
bool is3D() const
Returns true if the geometry is 3D and contains a z-value.
Definition qgsabstractgeometry.h:267

QgsAbstractGeometry::perimeter
virtual double perimeter() const
Returns the planar, 2-dimensional perimeter of the geometry.
Definition qgsabstractgeometry.cpp:202

QgsAbstractGeometry::length
virtual double length() const
Returns the planar, 2-dimensional length of the geometry.
Definition qgsabstractgeometry.cpp:197

QgsAbstractGeometry::dimension
virtual int dimension() const =0
Returns the inherent dimension of the geometry.

QgsAbstractGeometry::area
virtual double area() const
Returns the planar, 2-dimensional area of the geometry.
Definition qgsabstractgeometry.cpp:207

QgsCoordinateReferenceSystem
Represents a coordinate reference system (CRS).
Definition qgscoordinatereferencesystem.h:216

QgsCoordinateReferenceSystem::toProj
QString toProj() const
Returns a Proj string representation of this CRS.
Definition qgscoordinatereferencesystem.cpp:1336

QgsCoordinateReferenceSystem::isGeographic
bool isGeographic
Definition qgscoordinatereferencesystem.h:220

QgsCoordinateTransformContext
Contains information about the context in which a coordinate transform is executed.
Definition qgscoordinatetransformcontext.h:61

QgsCoordinateTransform
Handles coordinate transforms between two coordinate systems.
Definition qgscoordinatetransform.h:62

QgsCoordinateTransform::sourceCrs
QgsCoordinateReferenceSystem sourceCrs() const
Returns the source coordinate reference system, which the transform will transform coordinates from.
Definition qgscoordinatetransform.cpp:293

QgsCoordinateTransform::transform
QgsPointXY transform(const QgsPointXY &point, Qgis::TransformDirection direction=Qgis::TransformDirection::Forward) const
Transform the point from the source CRS to the destination CRS.
Definition qgscoordinatetransform.cpp:303

QgsCoordinateTransform::transformInPlace
void transformInPlace(double &x, double &y, double &z, Qgis::TransformDirection direction=Qgis::TransformDirection::Forward) const
Transforms an array of x, y and z double coordinates in place, from the source CRS to the destination...
Definition qgscoordinatetransform.cpp:395

QgsCoordinateTransform::destinationCrs
QgsCoordinateReferenceSystem destinationCrs() const
Returns the destination coordinate reference system, which the transform will transform coordinates t...
Definition qgscoordinatetransform.cpp:298

QgsCsException
Custom exception class for Coordinate Reference System related exceptions.
Definition qgsexception.h:60

QgsCurvePolygon
Curve polygon geometry type.
Definition qgscurvepolygon.h:41

QgsCurvePolygon::numInteriorRings
int numInteriorRings() const
Returns the number of interior rings contained with the curve polygon.
Definition qgscurvepolygon.h:172

QgsCurvePolygon::exteriorRing
const QgsCurve * exteriorRing() const
Returns the curve polygon's exterior ring.
Definition qgscurvepolygon.h:182

QgsCurvePolygon::interiorRing
const QgsCurve * interiorRing(int i) const
Retrieves an interior ring from the curve polygon.
Definition qgscurvepolygon.h:208

QgsCurvePolygon::surfaceToPolygon
virtual QgsPolygon * surfaceToPolygon() const
Gets a polygon representation of this surface.
Definition qgscurvepolygon.cpp:541

QgsCurve
Abstract base class for curved geometry type.
Definition qgscurve.h:36

QgsCurve::points
virtual void points(QgsPointSequence &pt) const =0
Returns a list of points within the curve.

QgsCurve::curveToLine
virtual QgsLineString * curveToLine(double tolerance=M_PI_2/90, SegmentationToleranceType toleranceType=MaximumAngle) const =0
Returns a new line string geometry corresponding to a segmentized approximation of the curve.

QgsDistanceArea::operator=
QgsDistanceArea & operator=(const QgsDistanceArea &other)
Definition qgsdistancearea.cpp:91

QgsDistanceArea::~QgsDistanceArea
~QgsDistanceArea()

QgsDistanceArea::latitudeGeodesicCrossesAntimeridian
double latitudeGeodesicCrossesAntimeridian(const QgsPointXY &p1, const QgsPointXY &p2, double &fractionAlongLine) const
Calculates the latitude at which the geodesic line joining p1 and p2 crosses the antimeridian (longit...
Definition qgsdistancearea.cpp:509

QgsDistanceArea::formatDistance
static QString formatDistance(double distance, int decimals, Qgis::DistanceUnit unit, bool keepBaseUnit=false)
Returns an distance formatted as a friendly string.
Definition qgsdistancearea.cpp:1011

QgsDistanceArea::sourceCrs
QgsCoordinateReferenceSystem sourceCrs() const
Returns the source spatial reference system.
Definition qgsdistancearea.h:82

QgsDistanceArea::measureArea
double measureArea(const QgsGeometry &geometry) const
Measures the area of a geometry.
Definition qgsdistancearea.cpp:265

QgsDistanceArea::convertLengthMeasurement
double convertLengthMeasurement(double length, Qgis::DistanceUnit toUnits) const
Takes a length measurement calculated by this QgsDistanceArea object and converts it to a different d...
Definition qgsdistancearea.cpp:1021

QgsDistanceArea::geodesicLine
QVector< QVector< QgsPointXY > > geodesicLine(const QgsPointXY &p1, const QgsPointXY &p2, double interval, bool breakLine=false) const
Calculates the geodesic line between p1 and p2, which represents the shortest path on the ellipsoid b...
Definition qgsdistancearea.cpp:727

QgsDistanceArea::measurePerimeter
double measurePerimeter(const QgsGeometry &geometry) const
Measures the perimeter of a polygon geometry.
Definition qgsdistancearea.cpp:283

QgsDistanceArea::measureLength
double measureLength(const QgsGeometry &geometry) const
Measures the length of a geometry.
Definition qgsdistancearea.cpp:274

QgsDistanceArea::bearing
double bearing(const QgsPointXY &p1, const QgsPointXY &p2) const
Computes the bearing (in radians) between two points.
Definition qgsdistancearea.cpp:889

QgsDistanceArea::ellipsoid
QString ellipsoid() const
Returns ellipsoid's acronym.
Definition qgsdistancearea.h:118

QgsDistanceArea::measureLine
double measureLine(const QVector< QgsPointXY > &points) const
Measures the length of a line with multiple segments.
Definition qgsdistancearea.cpp:359

QgsDistanceArea::setSourceCrs
void setSourceCrs(const QgsCoordinateReferenceSystem &crs, const QgsCoordinateTransformContext &context)
Sets source spatial reference system crs.
Definition qgsdistancearea.cpp:134

QgsDistanceArea::splitGeometryAtAntimeridian
QgsGeometry splitGeometryAtAntimeridian(const QgsGeometry &geometry) const
Splits a (Multi)LineString geometry at the antimeridian (longitude +/- 180 degrees).
Definition qgsdistancearea.cpp:598

QgsDistanceArea::lengthUnits
Qgis::DistanceUnit lengthUnits() const
Returns the units of distance for length calculations made by this object.
Definition qgsdistancearea.cpp:846

QgsDistanceArea::measurePolygon
double measurePolygon(const QVector< QgsPointXY > &points) const
Measures the area of the polygon described by a set of points.
Definition qgsdistancearea.cpp:871

QgsDistanceArea::measureLineProjected
double measureLineProjected(const QgsPointXY &p1, double distance=1, double azimuth=M_PI_2, QgsPointXY *projectedPoint=nullptr) const
Calculates the distance from one point with distance in meters and azimuth (direction) When the sourc...
Definition qgsdistancearea.cpp:447

QgsDistanceArea::setEllipsoid
bool setEllipsoid(const QString &ellipsoid)
Sets the ellipsoid by its acronym.
Definition qgsdistancearea.cpp:141

QgsDistanceArea::QgsDistanceArea
QgsDistanceArea()
Definition qgsdistancearea.cpp:48

QgsDistanceArea::computeSpheroidProject
QgsPointXY computeSpheroidProject(const QgsPointXY &p1, double distance=1, double azimuth=M_PI_2) const
Given a location, an azimuth and a distance, computes the location of the projected point.
Definition qgsdistancearea.cpp:494

QgsDistanceArea::willUseEllipsoid
bool willUseEllipsoid() const
Returns whether calculations will use the ellipsoid.
Definition qgsdistancearea.cpp:129

QgsDistanceArea::convertAreaMeasurement
double convertAreaMeasurement(double area, Qgis::AreaUnit toUnits) const
Takes an area measurement calculated by this QgsDistanceArea object and converts it to a different ar...
Definition qgsdistancearea.cpp:1032

QgsDistanceArea::formatArea
static QString formatArea(double area, int decimals, Qgis::AreaUnit unit, bool keepBaseUnit=false)
Returns an area formatted as a friendly string.
Definition qgsdistancearea.cpp:1016

QgsDistanceArea::areaUnits
Qgis::AreaUnit areaUnits() const
Returns the units of area for areal calculations made by this object.
Definition qgsdistancearea.cpp:851

QgsEllipsoidUtils::ellipsoidParameters
static EllipsoidParameters ellipsoidParameters(const QString &ellipsoid)
Returns the parameters for the specified ellipsoid.
Definition qgsellipsoidutils.cpp:46

QgsGeometryCollection::numGeometries
int numGeometries() const
Returns the number of geometries within the collection.
Definition qgsgeometrycollection.h:119

QgsGeometryCollection::geometryN
const QgsAbstractGeometry * geometryN(int n) const
Returns a const reference to a geometry from within the collection.
Definition qgsgeometrycollection.h:149

QgsGeometry
A geometry is the spatial representation of a feature.
Definition qgsgeometry.h:178

QgsGeometry::const_parts_begin
QgsAbstractGeometry::const_part_iterator const_parts_begin() const
Returns STL-style const iterator pointing to the first part of the geometry.
Definition qgsgeometry.cpp:2666

QgsGeometry::constGet
const QgsAbstractGeometry * constGet() const
Returns a non-modifiable (const) reference to the underlying abstract geometry primitive.
Definition qgsgeometry.cpp:135

QgsGeometry::convertToStraightSegment
void convertToStraightSegment(double tolerance=M_PI/180., QgsAbstractGeometry::SegmentationToleranceType toleranceType=QgsAbstractGeometry::MaximumAngle)
Converts the geometry to straight line segments, if it is a curved geometry type.
Definition qgsgeometry.cpp:4017

QgsGeometry::const_parts_end
QgsAbstractGeometry::const_part_iterator const_parts_end() const
Returns STL-style iterator pointing to the imaginary part after the last part of the geometry.
Definition qgsgeometry.cpp:2673

QgsGeometry::convertPointList
static void convertPointList(const QVector< QgsPointXY > &input, QgsPointSequence &output)
Upgrades a point list from QgsPointXY to QgsPoint.
Definition qgsgeometry.cpp:4268

QgsGeometry::wkbType
Qgis::WkbType wkbType() const
Returns type of the geometry as a WKB type (point / linestring / polygon etc.).
Definition qgsgeometry.cpp:481

QgsGeometry::isNull
bool isNull
Definition qgsgeometry.h:180

QgsLineString
Line string geometry type, with support for z-dimension and m-values.
Definition qgslinestring.h:48

QgsLineString::isEmpty
bool isEmpty() const override
Returns true if the geometry is empty.
Definition qgslinestring.cpp:295

QgsLineString::numPoints
int numPoints() const override
Returns the number of points in the curve.
Definition qgslinestring.cpp:1194

QgsLineString::pointN
QgsPoint pointN(int i) const
Returns the specified point from inside the line string.
Definition qgslinestring.cpp:1204

QgsLineString::clone
QgsLineString * clone() const override
Clones the geometry by performing a deep copy.
Definition qgslinestring.cpp:280

QgsMessageLog::logMessage
static void logMessage(const QString &message, const QString &tag=QString(), Qgis::MessageLevel level=Qgis::MessageLevel::Warning, bool notifyUser=true, const char *file=__builtin_FILE(), const char *function=__builtin_FUNCTION(), int line=__builtin_LINE(), Qgis::StringFormat format=Qgis::StringFormat::PlainText)
Adds a message to the log instance (and creates it if necessary).
Definition qgsmessagelog.cpp:35

QgsMultiSurface
Multi surface geometry collection.
Definition qgsmultisurface.h:31

QgsPointXY
Represents a 2D point.
Definition qgspointxy.h:62

QgsPointXY::project
QgsPointXY project(double distance, double bearing) const
Returns a new point which corresponds to this point projected by a specified distance in a specified ...
Definition qgspointxy.cpp:92

QgsPointXY::toString
QString toString(int precision=-1) const
Returns a string representation of the point (x, y) with a preset precision.
Definition qgspointxy.cpp:56

QgsPointXY::distance
double distance(double x, double y) const
Returns the distance between this point and a specified x, y coordinate.
Definition qgspointxy.h:209

QgsPointXY::asWkt
QString asWkt() const
Returns the well known text representation for the point (e.g.
Definition qgspointxy.cpp:74

QgsPointXY::y
double y
Definition qgspointxy.h:66

QgsPointXY::x
double x
Definition qgspointxy.h:65

QgsPointXY::setX
void setX(double x)
Sets the x value of the point.
Definition qgspointxy.h:122

QgsPoint
Point geometry type, with support for z-dimension and m-values.
Definition qgspoint.h:53

QgsPoint::setY
void setY(double y)
Sets the point's y-coordinate.
Definition qgspoint.h:387

QgsPoint::addMValue
bool addMValue(double mValue=0) override
Adds a measure to the geometry, initialized to a preset value.
Definition qgspoint.cpp:610

QgsPoint::addZValue
bool addZValue(double zValue=0) override
Adds a z-dimension to the geometry, initialized to a preset value.
Definition qgspoint.cpp:599

QgsPoint::setX
void setX(double x)
Sets the point's x-coordinate.
Definition qgspoint.h:376

QgsPoint::z
double z
Definition qgspoint.h:58

QgsPoint::x
double x
Definition qgspoint.h:56

QgsPoint::m
double m
Definition qgspoint.h:59

QgsPoint::y
double y
Definition qgspoint.h:57

QgsPolygon
Polygon geometry type.
Definition qgspolygon.h:37

QgsSurface
Surface geometry type.
Definition qgssurface.h:34

QgsUnitTypes::toString
static Q_INVOKABLE QString toString(Qgis::DistanceUnit unit)
Returns a translated string representing a distance unit.
Definition qgsunittypes.cpp:401

QgsUnitTypes::formatArea
static Q_INVOKABLE QString formatArea(double area, int decimals, Qgis::AreaUnit unit, bool keepBaseUnit=false)
Returns an area formatted as a friendly string.
Definition qgsunittypes.cpp:3382

QgsUnitTypes::fromUnitToUnitFactor
static Q_INVOKABLE double fromUnitToUnitFactor(Qgis::DistanceUnit fromUnit, Qgis::DistanceUnit toUnit)
Returns the conversion factor between the specified distance units.
Definition qgsunittypes.cpp:868

QgsUnitTypes::formatDistance
static Q_INVOKABLE QString formatDistance(double distance, int decimals, Qgis::DistanceUnit unit, bool keepBaseUnit=false)
Returns an distance formatted as a friendly string.
Definition qgsunittypes.cpp:3362

QgsUnitTypes::distanceToAreaUnit
static Q_INVOKABLE Qgis::AreaUnit distanceToAreaUnit(Qgis::DistanceUnit distanceUnit)
Converts a distance unit to its corresponding area unit, e.g., meters to square meters.
Definition qgsunittypes.cpp:1550

QgsWkbTypes::geometryType
static Qgis::GeometryType geometryType(Qgis::WkbType type)
Returns the geometry type for a WKB type, e.g., both MultiPolygon and CurvePolygon would have a Polyg...
Definition qgswkbtypes.h:967

QgsWkbTypes::isCurvedType
static Q_INVOKABLE bool isCurvedType(Qgis::WkbType type)
Returns true if the WKB type is a curved type or can contain curved geometries.
Definition qgswkbtypes.h:899

qgis.h

qgsDoubleToString
QString qgsDoubleToString(double a, int precision=17)
Returns a string representation of a double.
Definition qgis.h:7175

qgsgeometry_cast
T qgsgeometry_cast(QgsAbstractGeometry *geom)
Definition qgsabstractgeometry.h:1235

QgsPointSequence
QVector< QgsPoint > QgsPointSequence
Definition qgsabstractgeometry.h:57

qgscoordinatereferencesystem.h

qgscoordinatetransform.h

qgscurvepolygon.h

RAD2DEG
#define RAD2DEG(r)
Definition qgsdistancearea.cpp:45

DEG2RAD
#define DEG2RAD(x)
Definition qgsdistancearea.cpp:44

qgsdistancearea.h

qgsexception.h

qgsgeometry.h

qgsgeometrycollection.h

qgslinestring.h

qgslogger.h

QgsDebugMsgLevel
#define QgsDebugMsgLevel(str, level)
Definition qgslogger.h:63

qgsmessagelog.h

qgsmultilinestring.h

qgsmultisurface.h

qgspointxy.h

qgspolygon.h

qgssurface.h

qgsunittypes.h

QgsEllipsoidUtils::EllipsoidParameters
Contains parameters for an ellipsoid.
Definition qgsellipsoidutils.h:40

QgsEllipsoidUtils::EllipsoidParameters::semiMajor
double semiMajor
Semi-major axis, in meters.
Definition qgsellipsoidutils.h:45

QgsEllipsoidUtils::EllipsoidParameters::valid
bool valid
Whether ellipsoid parameters are valid.
Definition qgsellipsoidutils.h:42

QgsEllipsoidUtils::EllipsoidParameters::semiMinor
double semiMinor
Semi-minor axis, in meters.
Definition qgsellipsoidutils.h:47

QgsEllipsoidUtils::EllipsoidParameters::crs
QgsCoordinateReferenceSystem crs
Associated coordinate reference system.
Definition qgsellipsoidutils.h:56

QgsEllipsoidUtils::EllipsoidParameters::inverseFlattening
double inverseFlattening
Inverse flattening.
Definition qgsellipsoidutils.h:53