bool SelectionBase::ExpressionPart::match(const SPFeatureI &feature,SelectionBase *operation) const
{
if ( _type == ExpressionPart::ptFEATURETYPE){
return hasType(feature->geometryType(), _geometryType);
}
if ( _type == ExpressionPart::ptENVELOPE && _envelope.isValid()) {
return _envelope.contains(feature->geometry().get());
}
if ( _type == ExpressionPart::ptPOLYGON && _polygon.get() != 0) {
return _polygon->contains(feature->geometry().get());
}
if ( _type == ExpressionPart::ptATTRIBUTESELECTION ) {
QVariant val = feature(_leftSide);
ColumnDefinition coldef = feature->attributedefinition(_leftSide);
if ( coldef.datadef().domain()->ilwisType() == itITEMDOMAIN){
val = coldef.datadef().domain()->impliedValue(val);
}
if ( QString(val.typeName()) == "QString" && QString(_rightSide.typeName()) == "QString"){
return operation->compare1(_operator,val.toString(), _rightSide.toString());
} else {
bool ok1,ok2;
double v1 = val.toDouble(&ok1);
double v2 = _rightSide.toDouble(&ok2);
bool ok3 = operation->compare2(_operator, v1, v2, true);
return ok1&& ok2 && ok3;
}
}
return false;
}
bool GdalFeatureConnector::store(IlwisObject *obj, const IOOptions& )
{
if (!loadDriver())
return false;
IFeatureCoverage coverage;
coverage.set(static_cast<FeatureCoverage *>(obj));
std::vector<SourceHandles> datasources(3);
std::vector<bool> validAttributes;
if(!setDataSourceAndLayers(coverage, datasources, validAttributes))
return false;
std::vector<ColumnDefinition> defs;
for(int i=0; i < coverage->attributeTable()->columnCount(); ++i){
defs.push_back(coverage->attributeTable()->columndefinition(i));
}
FeatureIterator fiter(coverage);
FeatureIterator endIter = end(coverage);
for(; fiter != endIter; ++fiter) {
SPFeatureI feature = *fiter;
IlwisTypes geomType = feature->geometryType();
if ( geomType != 0){
OGRLayerH lyr = datasources[ilwisType2Index(geomType)]._layers[0];
OGRFeatureH hfeature = gdal()->createFeature(gdal()->getLayerDef(lyr));
if (hfeature) {
setAttributes(hfeature, feature, validAttributes, defs);
const geos::geom::Geometry* geometry = feature->geometry().get();
if (gdal()->setGeometryDirectly(hfeature,createFeature(geometry)) != OGRERR_NONE)
ERROR2(ERR_COULD_NOT_ALLOCATE_2, TR("geometry"), _filename.toString());
if (gdal()->addFeature2Layer(lyr, hfeature) != OGRERR_NONE) {
ERROR2(ERR_COULD_NOT_ALLOCATE_2, TR("feature"), _filename.toString());
}
gdal()->destroyFeature(hfeature);
};
}
}
for(auto& datasource : datasources){
if ( datasource._source != 0)
gdal()->destroyDataSource(datasource._source);
}
return true;
}
SPFeatureI FeatureCoverage::newFeatureFrom(const SPFeatureI& existingFeature, const ICoordinateSystem& csySource) {
Locker<> lock(_mutex);
auto transform = [&](const UPGeometry& geom)->geos::geom::Geometry * {
if ( geom.get() == 0)
return 0;
geos::geom::Geometry *newgeom = geom->clone();
if ( csySource.isValid() && !csySource->isEqual(coordinateSystem().ptr())){
CsyTransform trans(csySource, coordinateSystem());
newgeom->apply_rw(&trans);
newgeom->geometryChangedAction();
}
GeometryHelper::setCoordinateSystem(newgeom, coordinateSystem().ptr());
return newgeom;
};
if (!connector()->dataIsLoaded()) {
connector()->loadData(this);
}
auto *newfeature = createNewFeature(existingFeature->geometryType());
const UPGeometry& geom = existingFeature->geometry();
newfeature->geometry(transform(geom)) ;
auto variantIndexes = _attributeDefinition.indexes();
for(auto index : variantIndexes){
const auto& variant = existingFeature[index];
auto *variantFeature = createNewFeature(variant->geometryType());
const auto& geom = variant->geometry();
variantFeature->geometry(transform(geom)) ;
newfeature->setSubFeature(index, variantFeature);
}
_features.push_back(newfeature);
return _features.back();
}
