25 QString QgsLineDensityAlgorithm::name()
const
27 return QStringLiteral(
"linedensity" );
30 QString QgsLineDensityAlgorithm::displayName()
const
32 return QObject::tr(
"Line density" );
35 QStringList QgsLineDensityAlgorithm::tags()
const
37 return QObject::tr(
"density,kernel,line,line density,interpolation,weight" ).split(
',' );
40 QString QgsLineDensityAlgorithm::group()
const
42 return QObject::tr(
"Interpolation" );
45 QString QgsLineDensityAlgorithm::groupId()
const
47 return QStringLiteral(
"interpolation" );
50 void QgsLineDensityAlgorithm::initAlgorithm(
const QVariantMap & )
54 addParameter(
new QgsProcessingParameterDistance( QStringLiteral(
"RADIUS" ), QObject::tr(
"Search radius" ), 10, QStringLiteral(
"INPUT" ),
false, 0 ) );
55 addParameter(
new QgsProcessingParameterDistance( QStringLiteral(
"PIXEL_SIZE" ), QObject::tr(
"Pixel size" ), 10, QStringLiteral(
"INPUT" ),
false ) );
60 QString QgsLineDensityAlgorithm::shortHelpString()
const
62 return QObject::tr(
"The line density interpolation algorithm calculates a density measure of linear features "
63 "which is obtained in a circular neighborhood within each raster cell. "
64 "First, the length of the segment of each line that is intersected by the circular neighborhood "
65 "is multiplied with the lines weight factor. In a second step, all length values are summed and "
66 "divided by the area of the circular neighborhood. This process is repeated for all raster cells."
70 QgsLineDensityAlgorithm *QgsLineDensityAlgorithm::createInstance()
const
72 return new QgsLineDensityAlgorithm();
78 mSource.reset( parameterAsSource( parameters, QStringLiteral(
"INPUT" ), context ) );
82 mWeightField = parameterAsString( parameters, QStringLiteral(
"WEIGHT" ), context );
84 mPixelSize = parameterAsDouble( parameters, QStringLiteral(
"PIXEL_SIZE" ), context );
86 mSearchRadius = parameterAsDouble( parameters, QStringLiteral(
"RADIUS" ), context );
87 if ( mSearchRadius < 0.5 * mPixelSize * std::sqrt( 2 ) )
88 throw QgsProcessingException( QObject::tr(
"Raster cells must be fully contained by the search circle. Therefore, "
89 "the search radius must not be smaller than half of the pixel diagonal." ) );
91 mExtent = mSource->sourceExtent();
92 mCrs = mSource->sourceCrs();
98 const QgsPoint firstCellMidpoint =
QgsPoint( mExtent.xMinimum() + ( mPixelSize / 2 ), mExtent.yMaximum() - ( mPixelSize / 2 ) );
109 const QStringList weightName = QStringList( mWeightField );
110 const QgsFields attrFields = mSource->fields();
122 if ( !mWeightField.isEmpty() )
124 const double analysisWeight = f.
attribute( mWeightField ).toDouble();
125 mFeatureWeights.insert( f.
id(), analysisWeight );
129 const QString outputFile = parameterAsOutputLayer( parameters, QStringLiteral(
"OUTPUT" ), context );
130 const QFileInfo fi( outputFile );
133 const int rows = std::max( std::ceil( mExtent.height() / mPixelSize ), 1.0 );
134 const int cols = std::max( std::ceil( mExtent.width() / mPixelSize ), 1.0 );
138 const QgsRectangle rasterExtent =
QgsRectangle( mExtent.xMinimum(), mExtent.yMaximum() - ( rows * mPixelSize ), mExtent.xMinimum() + ( cols * mPixelSize ), mExtent.yMaximum() );
146 if ( !provider->isValid() )
149 provider->setNoDataValue( 1, -9999 );
154 std::unique_ptr< QgsRasterBlock > rasterDataLine = std::make_unique< QgsRasterBlock >(
Qgis::DataType::Float32, cols, 1 );
156 for (
int row = 0; row < rows; row++ )
158 for (
int col = 0; col < cols; col++ )
166 mSearchGeometry.translate( mPixelSize, 0 );
168 const QList<QgsFeatureId> fids = mIndex.intersects( mSearchGeometry.boundingBox() );
170 if ( !fids.isEmpty() )
173 engine->prepareGeometry();
175 double absDensity = 0;
178 const QgsGeometry lineGeom = mIndex.geometry(
id );
180 if ( engine->intersects( lineGeom.
constGet() ) )
182 const double analysisLineLength = mDa.measureLength(
QgsGeometry( engine->intersection( mIndex.geometry(
id ).constGet() ) ) );
185 if ( !mWeightField.isEmpty() )
187 weight = mFeatureWeights.value(
id );
190 absDensity += ( analysisLineLength * weight );
194 double lineDensity = 0;
195 if ( absDensity > 0 )
198 const double analysisSearchGeometryArea = mDa.measureArea( mSearchGeometry );
199 lineDensity = absDensity / analysisSearchGeometryArea;
201 rasterDataLine->setValue( 0, col, lineDensity );
206 rasterDataLine->setValue( 0, col, 0.0 );
209 feedback->
setProgress(
static_cast<double>( cellcnt ) /
static_cast<double>( totalCellcnt ) * 100 );
212 provider->writeBlock( rasterDataLine.get(), 1, 0, row );
215 mSearchGeometry.translate( ( cols - 1 ) * -mPixelSize, -mPixelSize );
219 outputs.insert( QStringLiteral(
"OUTPUT" ), outputFile );
@ Float32
Thirty two bit floating point (float)
A general purpose distance and area calculator, capable of performing ellipsoid based calculations.
virtual QgsPolygon * toPolygon(unsigned int segments=36) const
Returns a segmented polygon.
Wrapper for iterator of features from vector data provider or vector layer.
bool nextFeature(QgsFeature &f)
This class wraps a request for features to a vector layer (or directly its vector data provider).
QgsFeatureRequest & setSubsetOfAttributes(const QgsAttributeList &attrs)
Set a subset of attributes that will be fetched.
@ FastInsert
Use faster inserts, at the cost of updating the passed features to reflect changes made at the provid...
The feature class encapsulates a single feature including its unique ID, geometry and a list of field...
QVariant attribute(const QString &name) const
Lookup attribute value by attribute name.
bool isCanceled() const SIP_HOLDGIL
Tells whether the operation has been canceled already.
void setProgress(double progress)
Sets the current progress for the feedback object.
Container of fields for a vector layer.
A geometry is the spatial representation of a feature.
const QgsAbstractGeometry * constGet() const SIP_HOLDGIL
Returns a non-modifiable (const) reference to the underlying abstract geometry primitive.
static QgsGeometryEngine * createGeometryEngine(const QgsAbstractGeometry *geometry)
Creates and returns a new geometry engine representing the specified geometry.
Point geometry type, with support for z-dimension and m-values.
Contains information about the context in which a processing algorithm is executed.
QgsCoordinateTransformContext transformContext() const
Returns the coordinate transform context.
QString ellipsoid() const
Returns the ellipsoid to use for distance and area calculations.
Custom exception class for processing related exceptions.
Base class for providing feedback from a processing algorithm.
A double numeric parameter for distance values.
An input feature source (such as vector layers) parameter for processing algorithms.
A vector layer or feature source field parameter for processing algorithms.
@ Numeric
Accepts numeric fields.
A raster layer destination parameter, for specifying the destination path for a raster layer created ...
@ TypeVectorLine
Vector line layers.
The raster file writer which allows you to save a raster to a new file.
static QString driverForExtension(const QString &extension)
Returns the GDAL driver name for a specified file extension.
void setOutputProviderKey(const QString &key)
QgsRasterDataProvider * createOneBandRaster(Qgis::DataType dataType, int width, int height, const QgsRectangle &extent, const QgsCoordinateReferenceSystem &crs)
Create a raster file with one band without initializing the pixel data.
void setOutputFormat(const QString &format)
A rectangle specified with double values.
A spatial index for QgsFeature objects.
@ FlagStoreFeatureGeometries
Indicates that the spatial index should also store feature geometries. This requires more memory,...
unsigned long long qgssize
Qgssize is used instead of size_t, because size_t is stdlib type, unknown by SIP, and it would be har...
qint64 QgsFeatureId
64 bit feature ids negative numbers are used for uncommitted/newly added features