Example #1
0
QVariantMap QgsTransectAlgorithm::processAlgorithm( const QVariantMap &parameters, QgsProcessingContext &context, QgsProcessingFeedback *feedback )
{
  Side orientation = static_cast< QgsTransectAlgorithm::Side >( parameterAsInt( parameters, QStringLiteral( "SIDE" ), context ) );
  double angle = fabs( parameterAsDouble( parameters, QStringLiteral( "ANGLE" ), context ) );
  bool dynamicAngle = QgsProcessingParameters::isDynamic( parameters, QStringLiteral( "ANGLE" ) );
  QgsProperty angleProperty;
  if ( dynamicAngle )
    angleProperty = parameters.value( QStringLiteral( "ANGLE" ) ).value< QgsProperty >();

  double length = parameterAsDouble( parameters, QStringLiteral( "LENGTH" ), context );
  bool dynamicLength = QgsProcessingParameters::isDynamic( parameters, QStringLiteral( "LENGTH" ) );
  QgsProperty lengthProperty;
  if ( dynamicLength )
    lengthProperty = parameters.value( QStringLiteral( "LENGTH" ) ).value< QgsProperty >();

  if ( orientation == QgsTransectAlgorithm::Both )
    length /= 2.0;

  std::unique_ptr< QgsFeatureSource > source( parameterAsSource( parameters, QStringLiteral( "INPUT" ), context ) );
  if ( !source )
    throw QgsProcessingException( invalidSourceError( parameters, QStringLiteral( "INPUT" ) ) );

  QgsExpressionContext expressionContext = createExpressionContext( parameters, context, dynamic_cast< QgsProcessingFeatureSource * >( source.get() ) );

  QgsFields fields = source->fields();

  fields.append( QgsField( QStringLiteral( "TR_FID" ), QVariant::Int, QString(), 20 ) );
  fields.append( QgsField( QStringLiteral( "TR_ID" ), QVariant::Int, QString(), 20 ) );
  fields.append( QgsField( QStringLiteral( "TR_SEGMENT" ), QVariant::Int, QString(), 20 ) );
  fields.append( QgsField( QStringLiteral( "TR_ANGLE" ), QVariant::Double, QString(), 5, 2 ) );
  fields.append( QgsField( QStringLiteral( "TR_LENGTH" ), QVariant::Double, QString(), 20, 6 ) );
  fields.append( QgsField( QStringLiteral( "TR_ORIENT" ), QVariant::Int, QString(), 1 ) );

  QgsWkbTypes::Type outputWkb = QgsWkbTypes::LineString;
  if ( QgsWkbTypes::hasZ( source->wkbType() ) )
    outputWkb = QgsWkbTypes::addZ( outputWkb );
  if ( QgsWkbTypes::hasM( source->wkbType() ) )
    outputWkb = QgsWkbTypes::addM( outputWkb );

  QString dest;
  std::unique_ptr< QgsFeatureSink > sink( parameterAsSink( parameters, QStringLiteral( "OUTPUT" ), context, dest, fields,
                                          outputWkb, source->sourceCrs(), QgsFeatureSink::RegeneratePrimaryKey ) );
  if ( !sink )
    throw QgsProcessingException( invalidSinkError( parameters, QStringLiteral( "OUTPUT" ) ) );

  QgsFeatureIterator features = source->getFeatures( );

  int current = -1;
  int number = 0;
  double step =  source->featureCount() > 0 ? 100.0 / source->featureCount() : 1;
  QgsFeature feat;


  while ( features.nextFeature( feat ) )
  {
    current++;
    if ( feedback->isCanceled() )
    {
      break;
    }

    feedback->setProgress( current * step );
    if ( !feat.hasGeometry() )
      continue;

    QgsGeometry inputGeometry = feat.geometry();

    if ( dynamicLength || dynamicAngle )
    {
      expressionContext.setFeature( feat );
    }

    double evaluatedLength = length;
    if ( dynamicLength )
      evaluatedLength = lengthProperty.valueAsDouble( context.expressionContext(), length );
    double evaluatedAngle = angle;
    if ( dynamicAngle )
      evaluatedAngle = angleProperty.valueAsDouble( context.expressionContext(), angle );

    inputGeometry.convertToMultiType();
    const QgsMultiLineString *multiLine = static_cast< const QgsMultiLineString *  >( inputGeometry.constGet() );
    for ( int id = 0; id < multiLine->numGeometries(); ++id )
    {
      const QgsLineString *line = static_cast< const QgsLineString * >( multiLine->geometryN( id ) );
      QgsAbstractGeometry::vertex_iterator it = line->vertices_begin();
      while ( it != line->vertices_end() )
      {
        QgsVertexId vertexId = it.vertexId();
        int i = vertexId.vertex;
        QgsFeature outFeat;
        QgsAttributes attrs = feat.attributes();
        attrs << current << number << i + 1 << evaluatedAngle <<
              ( ( orientation == QgsTransectAlgorithm::Both ) ? evaluatedLength * 2 : evaluatedLength ) <<
              orientation;
        outFeat.setAttributes( attrs );
        double angleAtVertex = line->vertexAngle( vertexId );
        outFeat.setGeometry( calcTransect( *it, angleAtVertex, evaluatedLength, orientation, evaluatedAngle ) );
        sink->addFeature( outFeat, QgsFeatureSink::FastInsert );
        number++;
        it++;
      }
    }
  }

  QVariantMap outputs;
  outputs.insert( QStringLiteral( "OUTPUT" ), dest );
  return outputs;
}
QVariantMap QgsJoinWithLinesAlgorithm::processAlgorithm( const QVariantMap &parameters, QgsProcessingContext &context, QgsProcessingFeedback *feedback )
{
  if ( parameters.value( QStringLiteral( "SPOKES" ) ) == parameters.value( QStringLiteral( "HUBS" ) ) )
    throw QgsProcessingException( QObject::tr( "Same layer given for both hubs and spokes" ) );

  std::unique_ptr< QgsProcessingFeatureSource > hubSource( parameterAsSource( parameters, QStringLiteral( "HUBS" ), context ) );
  if ( !hubSource )
    throw QgsProcessingException( invalidSourceError( parameters, QStringLiteral( "HUBS" ) ) );

  std::unique_ptr< QgsProcessingFeatureSource > spokeSource( parameterAsSource( parameters, QStringLiteral( "SPOKES" ), context ) );
  if ( !hubSource || !spokeSource )
    throw QgsProcessingException( invalidSourceError( parameters, QStringLiteral( "SPOKES" ) ) );

  QString fieldHubName = parameterAsString( parameters, QStringLiteral( "HUB_FIELD" ), context );
  int fieldHubIndex = hubSource->fields().lookupField( fieldHubName );
  const QStringList hubFieldsToCopy = parameterAsFields( parameters, QStringLiteral( "HUB_FIELDS" ), context );

  QString fieldSpokeName = parameterAsString( parameters, QStringLiteral( "SPOKE_FIELD" ), context );
  int fieldSpokeIndex = spokeSource->fields().lookupField( fieldSpokeName );
  const QStringList spokeFieldsToCopy = parameterAsFields( parameters, QStringLiteral( "SPOKE_FIELDS" ), context );

  if ( fieldHubIndex < 0 || fieldSpokeIndex < 0 )
    throw QgsProcessingException( QObject::tr( "Invalid ID field" ) );

  const bool geodesic = parameterAsBool( parameters, QStringLiteral( "GEODESIC" ), context );
  const double geodesicDistance = parameterAsDouble( parameters, QStringLiteral( "GEODESIC_DISTANCE" ), context ) * 1000;
  bool dynamicGeodesicDistance = QgsProcessingParameters::isDynamic( parameters, QStringLiteral( "GEODESIC_DISTANCE" ) );
  QgsExpressionContext expressionContext = createExpressionContext( parameters, context, hubSource.get() );
  QgsProperty geodesicDistanceProperty;
  if ( dynamicGeodesicDistance )
  {
    geodesicDistanceProperty = parameters.value( QStringLiteral( "GEODESIC_DISTANCE" ) ).value< QgsProperty >();
  }

  const bool splitAntimeridian = parameterAsBool( parameters, QStringLiteral( "ANTIMERIDIAN_SPLIT" ), context );
  QgsDistanceArea da;
  da.setSourceCrs( hubSource->sourceCrs(), context.transformContext() );
  da.setEllipsoid( context.project()->ellipsoid() );

  QgsFields hubOutFields;
  QgsAttributeList hubFieldIndices;
  if ( hubFieldsToCopy.empty() )
  {
    hubOutFields = hubSource->fields();
    hubFieldIndices.reserve( hubOutFields.count() );
    for ( int i = 0; i < hubOutFields.count(); ++i )
    {
      hubFieldIndices << i;
    }
  }
  else
  {
    hubFieldIndices.reserve( hubOutFields.count() );
    for ( const QString &field : hubFieldsToCopy )
    {
      int index = hubSource->fields().lookupField( field );
      if ( index >= 0 )
      {
        hubFieldIndices << index;
        hubOutFields.append( hubSource->fields().at( index ) );
      }
    }
  }

  QgsAttributeList hubFields2Fetch = hubFieldIndices;
  hubFields2Fetch << fieldHubIndex;

  QgsFields spokeOutFields;
  QgsAttributeList spokeFieldIndices;
  if ( spokeFieldsToCopy.empty() )
  {
    spokeOutFields = spokeSource->fields();
    spokeFieldIndices.reserve( spokeOutFields.count() );
    for ( int i = 0; i < spokeOutFields.count(); ++i )
    {
      spokeFieldIndices << i;
    }
  }
  else
  {
    for ( const QString &field : spokeFieldsToCopy )
    {
      int index = spokeSource->fields().lookupField( field );
      if ( index >= 0 )
      {
        spokeFieldIndices << index;
        spokeOutFields.append( spokeSource->fields().at( index ) );
      }
    }
  }

  QgsAttributeList spokeFields2Fetch = spokeFieldIndices;
  spokeFields2Fetch << fieldSpokeIndex;


  QgsFields fields = QgsProcessingUtils::combineFields( hubOutFields, spokeOutFields );

  QgsWkbTypes::Type outType = geodesic ? QgsWkbTypes::MultiLineString : QgsWkbTypes::LineString;
  bool hasZ = false;
  if ( QgsWkbTypes::hasZ( hubSource->wkbType() ) || QgsWkbTypes::hasZ( spokeSource->wkbType() ) )
  {
    outType = QgsWkbTypes::addZ( outType );
    hasZ = true;
  }
  bool hasM = false;
  if ( QgsWkbTypes::hasM( hubSource->wkbType() ) || QgsWkbTypes::hasM( spokeSource->wkbType() ) )
  {
    outType = QgsWkbTypes::addM( outType );
    hasM = true;
  }

  QString dest;
  std::unique_ptr< QgsFeatureSink > sink( parameterAsSink( parameters, QStringLiteral( "OUTPUT" ), context, dest, fields,
                                          outType, hubSource->sourceCrs(), QgsFeatureSink::RegeneratePrimaryKey ) );
  if ( !sink )
    throw QgsProcessingException( invalidSinkError( parameters, QStringLiteral( "OUTPUT" ) ) );

  auto getPointFromFeature = [hasZ, hasM]( const QgsFeature & feature )->QgsPoint
  {
    QgsPoint p;
    if ( feature.geometry().type() == QgsWkbTypes::PointGeometry && !feature.geometry().isMultipart() )
      p = *static_cast< const QgsPoint *>( feature.geometry().constGet() );
    else
      p = *static_cast< const QgsPoint *>( feature.geometry().pointOnSurface().constGet() );
    if ( hasZ && !p.is3D() )
      p.addZValue( 0 );
    if ( hasM && !p.isMeasure() )
      p.addMValue( 0 );
    return p;
  };

  QgsFeatureIterator hubFeatures = hubSource->getFeatures( QgsFeatureRequest().setSubsetOfAttributes( hubFields2Fetch ), QgsProcessingFeatureSource::FlagSkipGeometryValidityChecks );
  double step = hubSource->featureCount() > 0 ? 100.0 / hubSource->featureCount() : 1;
  int i = 0;
  QgsFeature hubFeature;
  while ( hubFeatures.nextFeature( hubFeature ) )
  {
    i++;
    if ( feedback->isCanceled() )
    {
      break;
    }

    feedback->setProgress( i * step );

    if ( !hubFeature.hasGeometry() )
      continue;

    QgsPoint hubPoint = getPointFromFeature( hubFeature );

    // only keep selected attributes
    QgsAttributes hubAttributes;
    for ( int j = 0; j < hubFeature.attributes().count(); ++j )
    {
      if ( !hubFieldIndices.contains( j ) )
        continue;
      hubAttributes << hubFeature.attribute( j );
    }

    QgsFeatureRequest spokeRequest = QgsFeatureRequest().setDestinationCrs( hubSource->sourceCrs(), context.transformContext() );
    spokeRequest.setSubsetOfAttributes( spokeFields2Fetch );
    spokeRequest.setFilterExpression( QgsExpression::createFieldEqualityExpression( fieldSpokeName, hubFeature.attribute( fieldHubIndex ) ) );

    QgsFeatureIterator spokeFeatures = spokeSource->getFeatures( spokeRequest, QgsProcessingFeatureSource::FlagSkipGeometryValidityChecks );
    QgsFeature spokeFeature;
    while ( spokeFeatures.nextFeature( spokeFeature ) )
    {
      if ( feedback->isCanceled() )
      {
        break;
      }
      if ( !spokeFeature.hasGeometry() )
        continue;

      QgsPoint spokePoint = getPointFromFeature( spokeFeature );
      QgsGeometry line;
      if ( !geodesic )
      {
        line = QgsGeometry( new QgsLineString( QVector< QgsPoint >() << hubPoint << spokePoint ) );
        if ( splitAntimeridian )
          line = da.splitGeometryAtAntimeridian( line );
      }
      else
      {
        double distance = geodesicDistance;
        if ( dynamicGeodesicDistance )
        {
          expressionContext.setFeature( hubFeature );
          distance = geodesicDistanceProperty.valueAsDouble( expressionContext, distance );
        }

        std::unique_ptr< QgsMultiLineString > ml = qgis::make_unique< QgsMultiLineString >();
        std::unique_ptr< QgsLineString > l = qgis::make_unique< QgsLineString >( QVector< QgsPoint >() << hubPoint );
        QVector< QVector< QgsPointXY > > points = da.geodesicLine( QgsPointXY( hubPoint ), QgsPointXY( spokePoint ), distance, splitAntimeridian );
        QVector< QgsPointXY > points1 = points.at( 0 );
        points1.pop_front();
        if ( points.count() == 1 )
          points1.pop_back();

        QgsLineString geodesicPoints( points1 );
        l->append( &geodesicPoints );
        if ( points.count() == 1 )
          l->addVertex( spokePoint );

        ml->addGeometry( l.release() );
        if ( points.count() > 1 )
        {
          QVector< QgsPointXY > points2 = points.at( 1 );
          points2.pop_back();
          l = qgis::make_unique< QgsLineString >( points2 );
          if ( hasZ )
            l->addZValue( std::numeric_limits<double>::quiet_NaN() );
          if ( hasM )
            l->addMValue( std::numeric_limits<double>::quiet_NaN() );

          l->addVertex( spokePoint );
          ml->addGeometry( l.release() );
        }
        line = QgsGeometry( std::move( ml ) );
      }

      QgsFeature outFeature;
      QgsAttributes outAttributes = hubAttributes;

      // only keep selected attributes
      QgsAttributes spokeAttributes;
      for ( int j = 0; j < spokeFeature.attributes().count(); ++j )
      {
        if ( !spokeFieldIndices.contains( j ) )
          continue;
        spokeAttributes << spokeFeature.attribute( j );
      }

      outAttributes.append( spokeAttributes );
      outFeature.setAttributes( outAttributes );
      outFeature.setGeometry( line );
      sink->addFeature( outFeature, QgsFeatureSink::FastInsert );
    }
  }

  QVariantMap outputs;
  outputs.insert( QStringLiteral( "OUTPUT" ), dest );
  return outputs;
}
Example #3
0
QVariantMap QgsBufferAlgorithm::processAlgorithm( const QVariantMap &parameters, QgsProcessingContext &context, QgsProcessingFeedback *feedback )
{
  std::unique_ptr< QgsFeatureSource > source( parameterAsSource( parameters, QStringLiteral( "INPUT" ), context ) );
  if ( !source )
    throw QgsProcessingException( invalidSourceError( parameters, QStringLiteral( "INPUT" ) ) );

  QString dest;
  std::unique_ptr< QgsFeatureSink > sink( parameterAsSink( parameters, QStringLiteral( "OUTPUT" ), context, dest, source->fields(), QgsWkbTypes::Polygon, source->sourceCrs() ) );
  if ( !sink )
    throw QgsProcessingException( invalidSinkError( parameters, QStringLiteral( "OUTPUT" ) ) );

  // fixed parameters
  bool dissolve = parameterAsBool( parameters, QStringLiteral( "DISSOLVE" ), context );
  int segments = parameterAsInt( parameters, QStringLiteral( "SEGMENTS" ), context );
  QgsGeometry::EndCapStyle endCapStyle = static_cast< QgsGeometry::EndCapStyle >( 1 + parameterAsInt( parameters, QStringLiteral( "END_CAP_STYLE" ), context ) );
  QgsGeometry::JoinStyle joinStyle = static_cast< QgsGeometry::JoinStyle>( 1 + parameterAsInt( parameters, QStringLiteral( "JOIN_STYLE" ), context ) );
  double miterLimit = parameterAsDouble( parameters, QStringLiteral( "MITER_LIMIT" ), context );
  double bufferDistance = parameterAsDouble( parameters, QStringLiteral( "DISTANCE" ), context );
  bool dynamicBuffer = QgsProcessingParameters::isDynamic( parameters, QStringLiteral( "DISTANCE" ) );
  QgsExpressionContext expressionContext = createExpressionContext( parameters, context, dynamic_cast< QgsProcessingFeatureSource * >( source.get() ) );
  QgsProperty bufferProperty;
  if ( dynamicBuffer )
  {
    bufferProperty = parameters.value( QStringLiteral( "DISTANCE" ) ).value< QgsProperty >();
  }

  long count = source->featureCount();

  QgsFeature f;
  QgsFeatureIterator it = source->getFeatures();

  double step = count > 0 ? 100.0 / count : 1;
  int current = 0;

  QVector< QgsGeometry > bufferedGeometriesForDissolve;
  QgsAttributes dissolveAttrs;

  while ( it.nextFeature( f ) )
  {
    if ( feedback->isCanceled() )
    {
      break;
    }
    if ( dissolveAttrs.isEmpty() )
      dissolveAttrs = f.attributes();

    QgsFeature out = f;
    if ( out.hasGeometry() )
    {
      double distance =  bufferDistance;
      if ( dynamicBuffer )
      {
        expressionContext.setFeature( f );
        distance = bufferProperty.valueAsDouble( expressionContext, bufferDistance );
      }

      QgsGeometry outputGeometry = f.geometry().buffer( distance, segments, endCapStyle, joinStyle, miterLimit );
      if ( !outputGeometry )
      {
        QgsMessageLog::logMessage( QObject::tr( "Error calculating buffer for feature %1" ).arg( f.id() ), QObject::tr( "Processing" ), Qgis::Warning );
      }
      if ( dissolve )
        bufferedGeometriesForDissolve << outputGeometry;
      else
        out.setGeometry( outputGeometry );
    }

    if ( !dissolve )
      sink->addFeature( out, QgsFeatureSink::FastInsert );

    feedback->setProgress( current * step );
    current++;
  }

  if ( dissolve )
  {
    QgsGeometry finalGeometry = QgsGeometry::unaryUnion( bufferedGeometriesForDissolve );
    QgsFeature f;
    f.setGeometry( finalGeometry );
    f.setAttributes( dissolveAttrs );
    sink->addFeature( f, QgsFeatureSink::FastInsert );
  }

  QVariantMap outputs;
  outputs.insert( QStringLiteral( "OUTPUT" ), dest );
  return outputs;
}