24 : mSource( parameters.source )
25 , mOutputFile( outputFile )
26 , mOutputFormat( outputFormat )
29 , mRadius( parameters.radius )
30 , mPixelSize( parameters.pixelSize )
31 , mShape( parameters.shape )
32 , mDecay( parameters.decayRatio )
33 , mOutputValues( parameters.outputValues )
35 , mDatasetH( nullptr )
36 , mRasterBandH( nullptr )
52 if ( mRadiusField >= 0 )
53 requiredAttributes << mRadiusField;
55 if ( mWeightField >= 0 )
56 requiredAttributes << mWeightField;
73 GDALDriverH driver = GDALGetDriverByName( mOutputFormat.toUtf8() );
82 mBounds = calculateBounds();
86 int rows = std::max( std::ceil( mBounds.
height() / mPixelSize ) + 1, 1.0 );
87 int cols = std::max( std::ceil( mBounds.
width() / mPixelSize ) + 1, 1.0 );
89 if ( !createEmptyLayer( driver, mBounds, rows, cols ) )
93 mDatasetH.reset( GDALOpen( mOutputFile.toUtf8().constData(), GA_Update ) );
96 mRasterBandH = GDALGetRasterBand( mDatasetH.get(), 1 );
101 if ( mRadiusField < 0 )
102 mBufferSize = radiusSizeInPixels( mRadius );
110 if ( featureGeometry.
isNull() )
132 double radius = mRadius;
133 int buffer = mBufferSize;
134 if ( mRadiusField >= 0 )
136 radius = feature.
attribute( mRadiusField ).toDouble();
137 buffer = radiusSizeInPixels( radius );
139 int blockSize = 2 * buffer + 1;
143 if ( mWeightField >= 0 )
145 weight = feature.
attribute( mWeightField ).toDouble();
151 for ( QgsMultiPointXY::const_iterator pointIt = multiPoints.constBegin(); pointIt != multiPoints.constEnd(); ++pointIt )
154 if ( !mBounds.
contains( *pointIt ) )
160 unsigned int xPosition = ( ( ( *pointIt ).x() - mBounds.
xMinimum() ) / mPixelSize ) - buffer;
161 unsigned int yPosition = ( ( ( *pointIt ).y() - mBounds.
yMinimum() ) / mPixelSize ) - buffer;
162 unsigned int yPositionIO = ( ( mBounds.
yMaximum() - ( *pointIt ).y() ) / mPixelSize ) - buffer;
166 float *dataBuffer = (
float * ) CPLMalloc(
sizeof(
float ) * blockSize * blockSize );
167 if ( GDALRasterIO( mRasterBandH, GF_Read, xPosition, yPositionIO, blockSize, blockSize,
168 dataBuffer, blockSize, blockSize, GDT_Float32, 0, 0 ) != CE_None )
173 for (
int xp = 0; xp < blockSize; xp++ )
175 for (
int yp = 0; yp < blockSize; yp++ )
177 double pixelCentroidX = ( xPosition + xp + 0.5 ) * mPixelSize + mBounds.
xMinimum();
178 double pixelCentroidY = ( yPosition + yp + 0.5 ) * mPixelSize + mBounds.
yMinimum();
180 double distance = std::sqrt( std::pow( pixelCentroidX - ( *pointIt ).x(), 2.0 ) + std::pow( pixelCentroidY - ( *pointIt ).y(), 2.0 ) );
183 if ( distance > radius )
188 double pixelValue = weight * calculateKernelValue( distance, radius, mShape, mOutputValues );
189 int pos = xp + blockSize * yp;
190 if ( dataBuffer[ pos ] ==
NO_DATA )
192 dataBuffer[ pos ] = 0;
194 dataBuffer[ pos ] += pixelValue;
197 if ( GDALRasterIO( mRasterBandH, GF_Write, xPosition, yPositionIO, blockSize, blockSize,
198 dataBuffer, blockSize, blockSize, GDT_Float32, 0, 0 ) != CE_None )
202 CPLFree( dataBuffer );
211 mRasterBandH =
nullptr;
215 int QgsKernelDensityEstimation::radiusSizeInPixels(
double radius )
const 217 int buffer = radius / mPixelSize;
218 if ( radius - ( mPixelSize * buffer ) > 0.5 )
225 bool QgsKernelDensityEstimation::createEmptyLayer( GDALDriverH driver,
const QgsRectangle &bounds,
int rows,
int columns )
const 227 double geoTransform[6] = { bounds.
xMinimum(), mPixelSize, 0, bounds.
yMaximum(), 0, -mPixelSize };
228 gdal::dataset_unique_ptr emptyDataset( GDALCreate( driver, mOutputFile.toUtf8(), columns, rows, 1, GDT_Float32, nullptr ) );
232 if ( GDALSetGeoTransform( emptyDataset.get(), geoTransform ) != CE_None )
236 if ( GDALSetProjection( emptyDataset.get(), mSource->
sourceCrs().
toWkt().toLocal8Bit().data() ) != CE_None )
239 GDALRasterBandH poBand = GDALGetRasterBand( emptyDataset.get(), 1 );
243 if ( GDALSetRasterNoDataValue( poBand,
NO_DATA ) != CE_None )
246 float *line =
static_cast< float *
>( CPLMalloc(
sizeof(
float ) * columns ) );
247 for (
int i = 0; i < columns; i++ )
252 for (
int i = 0; i < rows ; i++ )
254 if ( GDALRasterIO( poBand, GF_Write, 0, i, columns, 1, line, columns, 1, GDT_Float32, 0, 0 ) != CE_None )
269 return triangularKernel( distance, bandwidth, outputType );
272 return uniformKernel( distance, bandwidth, outputType );
275 return quarticKernel( distance, bandwidth, outputType );
278 return triweightKernel( distance, bandwidth, outputType );
281 return epanechnikovKernel( distance, bandwidth, outputType );
296 Q_UNUSED( distance );
297 switch ( outputType )
302 double k = 2. / ( M_PI * bandwidth );
305 return k * ( 0.5 / bandwidth );
315 switch ( outputType )
320 double k = 116. / ( 5. * M_PI * std::pow( bandwidth, 2 ) );
323 return k * ( 15. / 16. ) * std::pow( 1. - std::pow( distance / bandwidth, 2 ), 2 );
326 return std::pow( 1. - std::pow( distance / bandwidth, 2 ), 2 );
333 switch ( outputType )
338 double k = 128. / ( 35. * M_PI * std::pow( bandwidth, 2 ) );
341 return k * ( 35. / 32. ) * std::pow( 1. - std::pow( distance / bandwidth, 2 ), 3 );
344 return std::pow( 1. - std::pow( distance / bandwidth, 2 ), 3 );
351 switch ( outputType )
356 double k = 8. / ( 3. * M_PI * std::pow( bandwidth, 2 ) );
359 return k * ( 3. / 4. ) * ( 1. - std::pow( distance / bandwidth, 2 ) );
362 return ( 1. - std::pow( distance / bandwidth, 2 ) );
370 switch ( outputType )
379 double k = 3. / ( ( 1. + 2. * mDecay ) * M_PI * std::pow( bandwidth, 2 ) );
382 return k * ( 1. - ( 1. - mDecay ) * ( distance / bandwidth ) );
387 return ( 1. - ( 1. - mDecay ) * ( distance / bandwidth ) );
391 return ( 1. - ( 1. - mDecay ) * ( distance / bandwidth ) );
396 QgsRectangle QgsKernelDensityEstimation::calculateBounds()
const 404 if ( mRadiusField >= 0 )
407 radius = mSource->
maximumValue( mRadiusField ).toDouble();
int lookupField(const QString &fieldName) const
Look up field's index from the field name.
QgsKernelDensityEstimation(const Parameters ¶meters, const QString &outputFile, const QString &outputFormat)
Constructor for QgsKernelDensityEstimation.
Wrapper for iterator of features from vector data provider or vector layer.
bool contains(const QgsRectangle &rect) const
Return true when rectangle contains other rectangle.
virtual QgsRectangle sourceExtent() const
Returns the extent of all geometries from the source.
A rectangle specified with double values.
QString weightField
Field name for weighting field, or empty if not using weights.
virtual QgsFields fields() const =0
Returns the fields associated with features in the source.
bool isMultipart() const
Returns true if WKB of the geometry is of WKBMulti* type.
bool isNull() const
Returns true if the geometry is null (ie, contains no underlying geometry accessible via geometry() )...
void setXMaximum(double x)
Set the maximum x value.
A class to represent a 2D point.
A geometry is the spatial representation of a feature.
QVector< QgsPointXY > QgsMultiPointXY
A collection of QgsPoints that share a common collection of attributes.
The feature class encapsulates a single feature including its id, geometry and a list of field/values...
KernelShape
Kernel shape type.
OutputValues
Output values type.
Input parameters were not valid.
double width() const
Returns the width of the rectangle.
void setYMinimum(double y)
Set the minimum y value.
Result finalise()
Finalises the output file.
This class wraps a request for features to a vector layer (or directly its vector data provider)...
Output the raw KDE values.
QgsGeometry geometry() const
Returns the geometry associated with this feature.
Could not open the driver for the specified format.
Output mathematically correct scaled values.
std::unique_ptr< void, GDALDatasetCloser > dataset_unique_ptr
Scoped GDAL dataset.
virtual QgsCoordinateReferenceSystem sourceCrs() const =0
Returns the coordinate reference system for features in the source.
Operation completed successfully.
double yMinimum() const
Returns the y minimum value (bottom side of rectangle).
double xMaximum() const
Returns the x maximum value (right side of rectangle).
QgsPointXY asPoint() const
Returns contents of the geometry as a point if wkbType is WKBPoint, otherwise returns [0...
QString radiusField
Field for radius, or empty if using a fixed radius.
void setYMaximum(double y)
Set the maximum y value.
Result addFeature(const QgsFeature &feature)
Adds a single feature to the KDE surface.
QString toWkt() const
Returns a WKT representation of this CRS.
bool isNull() const
Test if the rectangle is null (all coordinates zero or after call to setMinimal()).
double xMinimum() const
Returns the x minimum value (left side of rectangle).
double yMaximum() const
Returns the y maximum value (top side of rectangle).
Result run()
Runs the KDE calculation across the whole layer at once.
QgsMultiPointXY asMultiPoint() const
Returns contents of the geometry as a multi point if wkbType is WKBMultiPoint, otherwise an empty lis...
virtual QVariant maximumValue(int fieldIndex) const
Returns the maximum value for an attribute column or an invalid variant in case of error...
QList< int > QgsAttributeList
bool nextFeature(QgsFeature &f)
Result
Result of operation.
Result prepare()
Prepares the output file for writing and setups up the surface calculation.
QVariant attribute(const QString &name) const
Lookup attribute value from attribute name.
Error creating output file.
void setXMinimum(double x)
Set the minimum x value.
virtual QgsFeatureIterator getFeatures(const QgsFeatureRequest &request=QgsFeatureRequest()) const =0
Returns an iterator for the features in the source.
double height() const
Returns the height of the rectangle.