bool QgsMemoryProvider::addAttributes( const QList<QgsField> &attributes )
{
for ( QList<QgsField>::const_iterator it = attributes.begin(); it != attributes.end(); ++it )
{
switch ( it->type() )
{
case QVariant::Int:
case QVariant::Double:
case QVariant::String:
case QVariant::Date:
case QVariant::Time:
case QVariant::DateTime:
case QVariant::LongLong:
break;
default:
QgsDebugMsg( "Field type not supported: " + it->typeName() );
continue;
}
// add new field as a last one
mFields.append( *it );
for ( QgsFeatureMap::iterator fit = mFeatures.begin(); fit != mFeatures.end(); ++fit )
{
QgsFeature& f = fit.value();
QgsAttributes attr = f.attributes();
attr.append( QVariant() );
f.setAttributes( attr );
}
}
return true;
}
QgsVectorLayer *QgsFeatureSource::materialize( const QgsFeatureRequest &request, QgsFeedback *feedback )
{
QgsWkbTypes::Type outWkbType = request.flags() & QgsFeatureRequest::NoGeometry ? QgsWkbTypes::NoGeometry : wkbType();
QgsCoordinateReferenceSystem crs = request.destinationCrs().isValid() ? request.destinationCrs() : sourceCrs();
QgsAttributeList requestedAttrs = request.subsetOfAttributes();
QgsFields outFields;
if ( request.flags() & QgsFeatureRequest::SubsetOfAttributes )
{
int i = 0;
const QgsFields sourceFields = fields();
for ( const QgsField &field : sourceFields )
{
if ( requestedAttrs.contains( i ) )
outFields.append( field );
i++;
}
}
else
{
outFields = fields();
}
std::unique_ptr< QgsVectorLayer > layer( QgsMemoryProviderUtils::createMemoryLayer(
sourceName(),
outFields,
outWkbType,
crs ) );
QgsFeature f;
QgsFeatureIterator it = getFeatures( request );
int fieldCount = fields().count();
while ( it.nextFeature( f ) )
{
if ( feedback && feedback->isCanceled() )
break;
if ( request.flags() & QgsFeatureRequest::SubsetOfAttributes )
{
// remove unused attributes
QgsAttributes attrs;
for ( int i = 0; i < fieldCount; ++i )
{
if ( requestedAttrs.contains( i ) )
{
attrs.append( f.attributes().at( i ) );
}
}
f.setAttributes( attrs );
}
layer->dataProvider()->addFeature( f, QgsFeatureSink::FastInsert );
}
return layer.release();
}
QVariantMap QgsJoinWithLinesAlgorithm::processAlgorithm( const QVariantMap ¶meters, 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;
}
QVariantMap QgsLineIntersectionAlgorithm::processAlgorithm( const QVariantMap ¶meters, QgsProcessingContext &context, QgsProcessingFeedback *feedback )
{
std::unique_ptr< QgsFeatureSource > sourceA( parameterAsSource( parameters, QStringLiteral( "INPUT" ), context ) );
if ( !sourceA )
throw QgsProcessingException( invalidSourceError( parameters, QStringLiteral( "INPUT" ) ) );
std::unique_ptr< QgsFeatureSource > sourceB( parameterAsSource( parameters, QStringLiteral( "INTERSECT" ), context ) );
if ( !sourceB )
throw QgsProcessingException( invalidSourceError( parameters, QStringLiteral( "INTERSECT" ) ) );
const QStringList fieldsA = parameterAsFields( parameters, QStringLiteral( "INPUT_FIELDS" ), context );
const QStringList fieldsB = parameterAsFields( parameters, QStringLiteral( "INTERSECT_FIELDS" ), context );
QgsAttributeList fieldIndicesA = QgsProcessingUtils::fieldNamesToIndices( fieldsA, sourceA->fields() );
QgsAttributeList fieldIndicesB = QgsProcessingUtils::fieldNamesToIndices( fieldsB, sourceB->fields() );
QString intersectFieldsPrefix = parameterAsString( parameters, QStringLiteral( "INTERSECT_FIELDS_PREFIX" ), context );
QgsFields outFields = QgsProcessingUtils::combineFields(
QgsProcessingUtils::indicesToFields( fieldIndicesA, sourceA->fields() ),
QgsProcessingUtils::indicesToFields( fieldIndicesB, sourceB->fields() ),
intersectFieldsPrefix );
QString dest;
std::unique_ptr< QgsFeatureSink > sink( parameterAsSink( parameters, QStringLiteral( "OUTPUT" ), context, dest, outFields, QgsWkbTypes::Point, sourceA->sourceCrs(), QgsFeatureSink::RegeneratePrimaryKey ) );
if ( !sink )
throw QgsProcessingException( invalidSinkError( parameters, QStringLiteral( "OUTPUT" ) ) );
QgsSpatialIndex spatialIndex( sourceB->getFeatures( QgsFeatureRequest().setNoAttributes().setDestinationCrs( sourceA->sourceCrs(), context.transformContext() ) ), feedback );
QgsFeature outFeature;
QgsFeatureIterator features = sourceA->getFeatures( QgsFeatureRequest().setSubsetOfAttributes( fieldIndicesA ) );
double step = sourceA->featureCount() > 0 ? 100.0 / sourceA->featureCount() : 1;
int i = 0;
QgsFeature inFeatureA;
while ( features.nextFeature( inFeatureA ) )
{
i++;
if ( feedback->isCanceled() )
{
break;
}
if ( !inFeatureA.hasGeometry() )
continue;
QgsGeometry inGeom = inFeatureA.geometry();
QgsFeatureIds lines = spatialIndex.intersects( inGeom.boundingBox() ).toSet();
if ( !lines.empty() )
{
// use prepared geometries for faster intersection tests
std::unique_ptr< QgsGeometryEngine > engine( QgsGeometry::createGeometryEngine( inGeom.constGet() ) );
engine->prepareGeometry();
QgsFeatureRequest request = QgsFeatureRequest().setFilterFids( lines );
request.setDestinationCrs( sourceA->sourceCrs(), context.transformContext() );
request.setSubsetOfAttributes( fieldIndicesB );
QgsFeature inFeatureB;
QgsFeatureIterator featuresB = sourceB->getFeatures( request );
while ( featuresB.nextFeature( inFeatureB ) )
{
if ( feedback->isCanceled() )
{
break;
}
QgsGeometry tmpGeom = inFeatureB.geometry();
if ( engine->intersects( tmpGeom.constGet() ) )
{
QgsMultiPointXY points;
QgsGeometry intersectGeom = inGeom.intersection( tmpGeom );
QgsAttributes outAttributes;
for ( int a : qgis::as_const( fieldIndicesA ) )
{
outAttributes.append( inFeatureA.attribute( a ) );
}
for ( int b : qgis::as_const( fieldIndicesB ) )
{
outAttributes.append( inFeatureB.attribute( b ) );
}
if ( QgsWkbTypes::flatType( intersectGeom.wkbType() ) == QgsWkbTypes::GeometryCollection )
{
const QVector<QgsGeometry> geomCollection = intersectGeom.asGeometryCollection();
for ( const QgsGeometry &part : geomCollection )
{
if ( part.type() == QgsWkbTypes::PointGeometry )
{
if ( part.isMultipart() )
{
points = part.asMultiPoint();
}
else
{
points.append( part.asPoint() );
}
}
}
}
else if ( intersectGeom.type() == QgsWkbTypes::PointGeometry )
{
if ( intersectGeom.isMultipart() )
{
points = intersectGeom.asMultiPoint();
}
else
{
points.append( intersectGeom.asPoint() );
}
}
for ( const QgsPointXY &j : qgis::as_const( points ) )
{
outFeature.setGeometry( QgsGeometry::fromPointXY( j ) );
outFeature.setAttributes( outAttributes );
sink->addFeature( outFeature, QgsFeatureSink::FastInsert );
}
}
}
}
feedback->setProgress( i * step );
}
QVariantMap outputs;
outputs.insert( QStringLiteral( "OUTPUT" ), dest );
return outputs;
}
QVariantMap QgsShortestPathPointToLayerAlgorithm::processAlgorithm( const QVariantMap ¶meters, QgsProcessingContext &context, QgsProcessingFeedback *feedback )
{
loadCommonParams( parameters, context, feedback );
QgsPointXY startPoint = parameterAsPoint( parameters, QStringLiteral( "START_POINT" ), context, mNetwork->sourceCrs() );
std::unique_ptr< QgsFeatureSource > endPoints( parameterAsSource( parameters, QStringLiteral( "END_POINTS" ), context ) );
if ( !endPoints )
throw QgsProcessingException( invalidSourceError( parameters, QStringLiteral( "END_POINTS" ) ) );
QgsFields fields = endPoints->fields();
fields.append( QgsField( QStringLiteral( "start" ), QVariant::String ) );
fields.append( QgsField( QStringLiteral( "end" ), QVariant::String ) );
fields.append( QgsField( QStringLiteral( "cost" ), QVariant::Double ) );
QString dest;
std::unique_ptr< QgsFeatureSink > sink( parameterAsSink( parameters, QStringLiteral( "OUTPUT" ), context, dest, fields, QgsWkbTypes::LineString, mNetwork->sourceCrs() ) );
if ( !sink )
throw QgsProcessingException( invalidSinkError( parameters, QStringLiteral( "OUTPUT" ) ) );
QVector< QgsPointXY > points;
points.push_front( startPoint );
QHash< int, QgsAttributes > sourceAttributes;
loadPoints( endPoints.get(), points, sourceAttributes, context, feedback );
feedback->pushInfo( QObject::tr( "Building graph…" ) );
QVector< QgsPointXY > snappedPoints;
mDirector->makeGraph( mBuilder.get(), points, snappedPoints, feedback );
feedback->pushInfo( QObject::tr( "Calculating shortest paths…" ) );
QgsGraph *graph = mBuilder->graph();
int idxStart = graph->findVertex( snappedPoints[0] );
int idxEnd;
QVector< int > tree;
QVector< double > costs;
QgsGraphAnalyzer::dijkstra( graph, idxStart, 0, &tree, &costs );
QVector<QgsPointXY> route;
double cost;
QgsFeature feat;
feat.setFields( fields );
QgsAttributes attributes;
int step = points.size() > 0 ? 100.0 / points.size() : 1;
for ( int i = 1; i < points.size(); i++ )
{
if ( feedback->isCanceled() )
{
break;
}
idxEnd = graph->findVertex( snappedPoints[i] );
if ( tree.at( idxEnd ) == -1 )
{
feedback->reportError( QObject::tr( "There is no route from start point (%1) to end point (%2)." )
.arg( startPoint.toString(),
points[i].toString() ) );
feat.clearGeometry();
attributes = sourceAttributes.value( i );
attributes.append( QVariant() );
attributes.append( points[i].toString() );
feat.setAttributes( attributes );
sink->addFeature( feat, QgsFeatureSink::FastInsert );
continue;
}
route.clear();
route.push_front( graph->vertex( idxEnd ).point() );
cost = costs.at( idxEnd );
while ( idxEnd != idxStart )
{
idxEnd = graph->edge( tree.at( idxEnd ) ).fromVertex();
route.push_front( graph->vertex( idxEnd ).point() );
}
QgsGeometry geom = QgsGeometry::fromPolylineXY( route );
QgsFeature feat;
feat.setFields( fields );
attributes = sourceAttributes.value( i );
attributes.append( startPoint.toString() );
attributes.append( points[i].toString() );
attributes.append( cost / mMultiplier );
feat.setAttributes( attributes );
feat.setGeometry( geom );
sink->addFeature( feat, QgsFeatureSink::FastInsert );
feedback->setProgress( i * step );
}
QVariantMap outputs;
outputs.insert( QStringLiteral( "OUTPUT" ), dest );
return outputs;
}
QVariantMap QgsJoinWithLinesAlgorithm::processAlgorithm( const QVariantMap ¶meters, 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< QgsFeatureSource > hubSource( parameterAsSource( parameters, QStringLiteral( "HUBS" ), context ) );
std::unique_ptr< QgsFeatureSource > spokeSource( parameterAsSource( parameters, QStringLiteral( "SPOKES" ), context ) );
if ( !hubSource || !spokeSource )
return QVariantMap();
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" ) );
QgsFields hubOutFields;
QgsAttributeList hubFieldIndices;
if ( hubFieldsToCopy.empty() )
{
hubOutFields = hubSource->fields();
for ( int i = 0; i < hubOutFields.count(); ++i )
{
hubFieldIndices << i;
}
}
else
{
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();
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 = 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() ) );
if ( !sink )
return QVariantMap();
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 ) );
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 );
QgsFeature spokeFeature;
while ( spokeFeatures.nextFeature( spokeFeature ) )
{
if ( feedback->isCanceled() )
{
break;
}
if ( !spokeFeature.hasGeometry() )
continue;
QgsPoint spokePoint = getPointFromFeature( spokeFeature );
QgsGeometry line( new QgsLineString( QVector< QgsPoint >() << hubPoint << spokePoint ) );
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;
}
QgsRasterIdentifyResult QgsAmsProvider::identify( const QgsPointXY &point, QgsRaster::IdentifyFormat format, const QgsRectangle &extent, int width, int height, int dpi )
{
// http://resources.arcgis.com/en/help/rest/apiref/identify.html
QgsDataSourceUri dataSource( dataSourceUri() );
QUrl queryUrl( dataSource.param( QStringLiteral( "url" ) ) + "/identify" );
queryUrl.addQueryItem( QStringLiteral( "f" ), QStringLiteral( "json" ) );
queryUrl.addQueryItem( QStringLiteral( "geometryType" ), QStringLiteral( "esriGeometryPoint" ) );
queryUrl.addQueryItem( QStringLiteral( "geometry" ), QStringLiteral( "{x: %1, y: %2}" ).arg( point.x(), 0, 'f' ).arg( point.y(), 0, 'f' ) );
// queryUrl.addQueryItem( "sr", mCrs.postgisSrid() );
queryUrl.addQueryItem( QStringLiteral( "layers" ), QStringLiteral( "all:%1" ).arg( dataSource.param( QStringLiteral( "layer" ) ) ) );
queryUrl.addQueryItem( QStringLiteral( "imageDisplay" ), QStringLiteral( "%1,%2,%3" ).arg( width ).arg( height ).arg( dpi ) );
queryUrl.addQueryItem( QStringLiteral( "mapExtent" ), QStringLiteral( "%1,%2,%3,%4" ).arg( extent.xMinimum(), 0, 'f' ).arg( extent.yMinimum(), 0, 'f' ).arg( extent.xMaximum(), 0, 'f' ).arg( extent.yMaximum(), 0, 'f' ) );
queryUrl.addQueryItem( QStringLiteral( "tolerance" ), QStringLiteral( "10" ) );
const QString authcfg = dataSource.param( QStringLiteral( "authcfg" ) );
const QVariantList queryResults = QgsArcGisRestUtils::queryServiceJSON( queryUrl, authcfg, mErrorTitle, mError ).value( QStringLiteral( "results" ) ).toList();
QMap<int, QVariant> entries;
if ( format == QgsRaster::IdentifyFormatText )
{
for ( const QVariant &result : queryResults )
{
const QVariantMap resultMap = result.toMap();
QVariantMap attributesMap = resultMap[QStringLiteral( "attributes" )].toMap();
QString valueStr;
for ( auto it = attributesMap.constBegin(); it != attributesMap.constEnd(); ++it )
{
valueStr += QStringLiteral( "%1 = %2\n" ).arg( it.key(), it.value().toString() );
}
entries.insert( entries.size(), valueStr );
}
}
else if ( format == QgsRaster::IdentifyFormatFeature )
{
for ( const QVariant &result : queryResults )
{
const QVariantMap resultMap = result.toMap();
QgsFields fields;
const QVariantMap attributesMap = resultMap[QStringLiteral( "attributes" )].toMap();
QgsAttributes featureAttributes;
for ( auto it = attributesMap.constBegin(); it != attributesMap.constEnd(); ++it )
{
fields.append( QgsField( it.key(), QVariant::String, QStringLiteral( "string" ) ) );
featureAttributes.append( it.value().toString() );
}
QgsCoordinateReferenceSystem crs;
std::unique_ptr< QgsAbstractGeometry > geometry = QgsArcGisRestUtils::parseEsriGeoJSON( resultMap[QStringLiteral( "geometry" )].toMap(), resultMap[QStringLiteral( "geometryType" )].toString(), false, false, &crs );
QgsFeature feature( fields );
feature.setGeometry( QgsGeometry( std::move( geometry ) ) );
feature.setAttributes( featureAttributes );
feature.setValid( true );
QgsFeatureStore store( fields, crs );
QMap<QString, QVariant> params;
params[QStringLiteral( "sublayer" )] = resultMap[QStringLiteral( "layerName" )].toString();
params[QStringLiteral( "featureType" )] = attributesMap[resultMap[QStringLiteral( "displayFieldName" )].toString()].toString();
store.setParams( params );
store.addFeature( feature );
entries.insert( entries.size(), qVariantFromValue( QList<QgsFeatureStore>() << store ) );
}
}
return QgsRasterIdentifyResult( format, entries );
}
