void QgsDelimitedTextProvider::scanFile( bool buildIndexes )
{
QStringList messages;
// assume the layer is invalid until proven otherwise
mLayerValid = false;
mValid = false;
mRescanRequired = false;
clearInvalidLines();
// Initiallize indexes
resetIndexes();
bool buildSpatialIndex = buildIndexes && mSpatialIndex != 0;
// No point building a subset index if there is no geometry, as all
// records will be included.
bool buildSubsetIndex = buildIndexes && mBuildSubsetIndex && mGeomRep != GeomNone;
if ( ! mFile->isValid() )
{
// uri is invalid so the layer must be too...
messages.append( tr( "File cannot be opened or delimiter parameters are not valid" ) );
reportErrors( messages );
QgsDebugMsg( "Delimited text source invalid - filename or delimiter parameters" );
return;
}
// Open the file and get number of rows, etc. We assume that the
// file has a header row and process accordingly. Caller should make
// sure that the delimited file is properly formed.
if ( mGeomRep == GeomAsWkt )
{
mWktFieldIndex = mFile->fieldIndex( mWktFieldName );
if ( mWktFieldIndex < 0 )
{
messages.append( tr( "%0 field %1 is not defined in delimited text file" ).arg( "Wkt" ).arg( mWktFieldName ) );
}
}
else if ( mGeomRep == GeomAsXy )
{
mXFieldIndex = mFile->fieldIndex( mXFieldName );
mYFieldIndex = mFile->fieldIndex( mYFieldName );
if ( mXFieldIndex < 0 )
{
messages.append( tr( "%0 field %1 is not defined in delimited text file" ).arg( "X" ).arg( mWktFieldName ) );
}
if ( mYFieldIndex < 0 )
{
messages.append( tr( "%0 field %1 is not defined in delimited text file" ).arg( "Y" ).arg( mWktFieldName ) );
}
}
if ( messages.size() > 0 )
{
reportErrors( messages );
QgsDebugMsg( "Delimited text source invalid - missing geometry fields" );
return;
}
// Scan the entire file to determine
// 1) the number of fields (this is handled by QgsDelimitedTextFile mFile
// 2) the number of valid features. Note that the selection of valid features
// should match the code in QgsDelimitedTextFeatureIterator
// 3) the geometric extents of the layer
// 4) the type of each field
//
// Also build subset and spatial indexes.
QStringList parts;
long nEmptyRecords = 0;
long nBadFormatRecords = 0;
long nIncompatibleGeometry = 0;
long nInvalidGeometry = 0;
long nEmptyGeometry = 0;
mNumberFeatures = 0;
mExtent = QgsRectangle();
QList<bool> isEmpty;
QList<bool> couldBeInt;
QList<bool> couldBeDouble;
while ( true )
{
QgsDelimitedTextFile::Status status = mFile->nextRecord( parts );
if ( status == QgsDelimitedTextFile::RecordEOF ) break;
if ( status != QgsDelimitedTextFile::RecordOk )
{
nBadFormatRecords++;
recordInvalidLine( tr( "Invalid record format at line %1" ) );
continue;
}
// Skip over empty records
if ( recordIsEmpty( parts ) )
{
nEmptyRecords++;
continue;
}
// Check geometries are valid
bool geomValid = true;
if ( mGeomRep == GeomAsWkt )
{
if ( mWktFieldIndex >= parts.size() || parts[mWktFieldIndex].isEmpty() )
{
nEmptyGeometry++;
geomValid = false;
}
else
{
// Get the wkt - confirm it is valid, get the type, and
// if compatible with the rest of file, add to the extents
QString sWkt = parts[mWktFieldIndex];
QgsGeometry *geom = 0;
if ( !mWktHasPrefix && sWkt.indexOf( WktPrefixRegexp ) >= 0 )
mWktHasPrefix = true;
if ( !mWktHasZM && sWkt.indexOf( WktZMRegexp ) >= 0 )
mWktHasZM = true;
geom = geomFromWkt( sWkt, mWktHasPrefix, mWktHasZM );
if ( geom )
{
QGis::WkbType type = geom->wkbType();
if ( type != QGis::WKBNoGeometry )
{
if ( mGeometryType == QGis::UnknownGeometry || geom->type() == mGeometryType )
{
mGeometryType = geom->type();
if ( mNumberFeatures == 0 )
{
mNumberFeatures++;
mWkbType = type;
mExtent = geom->boundingBox();
}
else
{
mNumberFeatures++;
if ( geom->isMultipart() ) mWkbType = type;
QgsRectangle bbox( geom->boundingBox() );
mExtent.combineExtentWith( &bbox );
}
if ( buildSpatialIndex )
{
QgsFeature f;
f.setFeatureId( mFile->recordId() );
f.setGeometry( geom );
mSpatialIndex->insertFeature( f );
// Feature now has ownership of geometry, so set to null
// here to avoid deleting twice.
geom = 0;
}
}
else
{
nIncompatibleGeometry++;
geomValid = false;
}
}
if ( geom ) delete geom;
}
else
{
geomValid = false;
nInvalidGeometry++;
recordInvalidLine( tr( "Invalid WKT at line %1" ) );
}
}
}
else if ( mGeomRep == GeomAsXy )
{
// Get the x and y values, first checking to make sure they
// aren't null.
QString sX = mXFieldIndex < parts.size() ? parts[mXFieldIndex] : "";
QString sY = mYFieldIndex < parts.size() ? parts[mYFieldIndex] : "";
if ( sX.isEmpty() && sY.isEmpty() )
{
geomValid = false;
nEmptyGeometry++;
}
else
{
QgsPoint pt;
bool ok = pointFromXY( sX, sY, pt, mDecimalPoint, mXyDms );
if ( ok )
{
if ( mNumberFeatures > 0 )
{
mExtent.combineExtentWith( pt.x(), pt.y() );
}
else
{
// Extent for the first point is just the first point
mExtent.set( pt.x(), pt.y(), pt.x(), pt.y() );
mWkbType = QGis::WKBPoint;
mGeometryType = QGis::Point;
}
mNumberFeatures++;
if ( buildSpatialIndex && qIsFinite( pt.x() ) && qIsFinite( pt.y() ) )
{
QgsFeature f;
f.setFeatureId( mFile->recordId() );
f.setGeometry( QgsGeometry::fromPoint( pt ) );
mSpatialIndex->insertFeature( f );
}
}
else
{
geomValid = false;
nInvalidGeometry++;
recordInvalidLine( tr( "Invalid X or Y fields at line %1" ) );
}
}
}
else
{
mWkbType = QGis::WKBNoGeometry;
mNumberFeatures++;
}
if ( ! geomValid ) continue;
if ( buildSubsetIndex ) mSubsetIndex.append( mFile->recordId() );
// If we are going to use this record, then assess the potential types of each colum
for ( int i = 0; i < parts.size(); i++ )
{
QString &value = parts[i];
if ( value.isEmpty() )
continue;
// try to convert attribute values to integer and double
while ( couldBeInt.size() <= i )
{
isEmpty.append( true );
couldBeInt.append( false );
couldBeDouble.append( false );
}
if ( isEmpty[i] )
{
isEmpty[i] = false;
couldBeInt[i] = true;
couldBeDouble[i] = true;
}
if ( couldBeInt[i] )
{
value.toInt( &couldBeInt[i] );
}
if ( couldBeDouble[i] )
{
if ( ! mDecimalPoint.isEmpty() )
{
value.replace( mDecimalPoint, "." );
}
value.toDouble( &couldBeDouble[i] );
}
}
}
// Now create the attribute fields. Field types are integer by preference,
// failing that double, failing that text.
QStringList fieldNames = mFile->fieldNames();
mFieldCount = fieldNames.size();
attributeColumns.clear();
attributeFields.clear();
QString csvtMessage;
QStringList csvtTypes = readCsvtFieldTypes( mFile->fileName(), &csvtMessage );
for ( int i = 0; i < fieldNames.size(); i++ )
{
// Skip over WKT field ... don't want to display in attribute table
if ( i == mWktFieldIndex ) continue;
// Add the field index lookup for the column
attributeColumns.append( i );
QVariant::Type fieldType = QVariant::String;
QString typeName = "text";
if ( i < csvtTypes.size() )
{
if ( csvtTypes[i] == "integer" )
{
fieldType = QVariant::Int;
typeName = "integer";
}
else if ( csvtTypes[i] == "real" )
{
fieldType = QVariant::Double;
typeName = "double";
}
}
else if ( i < couldBeInt.size() )
{
if ( couldBeInt[i] )
{
fieldType = QVariant::Int;
typeName = "integer";
}
else if ( couldBeDouble[i] )
{
fieldType = QVariant::Double;
typeName = "double";
}
}
attributeFields.append( QgsField( fieldNames[i], fieldType, typeName ) );
}
QgsDebugMsg( "Field count for the delimited text file is " + QString::number( attributeFields.size() ) );
QgsDebugMsg( "geometry type is: " + QString::number( mWkbType ) );
QgsDebugMsg( "feature count is: " + QString::number( mNumberFeatures ) );
QStringList warnings;
if ( ! csvtMessage.isEmpty() ) warnings.append( csvtMessage );
if ( nBadFormatRecords > 0 )
warnings.append( tr( "%1 records discarded due to invalid format" ).arg( nBadFormatRecords ) );
if ( nEmptyGeometry > 0 )
warnings.append( tr( "%1 records discarded due to missing geometry definitions" ).arg( nEmptyGeometry ) );
if ( nInvalidGeometry > 0 )
warnings.append( tr( "%1 records discarded due to invalid geometry definitions" ).arg( nInvalidGeometry ) );
if ( nIncompatibleGeometry > 0 )
warnings.append( tr( "%1 records discarded due to incompatible geometry types" ).arg( nIncompatibleGeometry ) );
reportErrors( warnings );
// Decide whether to use subset ids to index records rather than simple iteration through all
// If more than 10% of records are being skipped, then use index. (Not based on any experimentation,
// could do with some analysis?)
if ( buildSubsetIndex )
{
long recordCount = mFile->recordCount();
recordCount -= recordCount / SUBSET_ID_THRESHOLD_FACTOR;
mUseSubsetIndex = mSubsetIndex.size() < recordCount;
if ( ! mUseSubsetIndex ) mSubsetIndex = QList<quintptr>();
}
mUseSpatialIndex = buildSpatialIndex;
mValid = mGeometryType != QGis::UnknownGeometry;
mLayerValid = mValid;
// If it is valid, then watch for changes to the file
connect( mFile, SIGNAL( fileUpdated() ), this, SLOT( onFileUpdated() ) );
}
bool QgsOgrFeatureIterator::readFeature( gdal::ogr_feature_unique_ptr fet, QgsFeature &feature ) const
{
feature.setId( OGR_F_GetFID( fet.get() ) );
feature.initAttributes( mSource->mFields.count() );
feature.setFields( mSource->mFields ); // allow name-based attribute lookups
bool useIntersect = !mRequest.filterRect().isNull();
bool geometryTypeFilter = mSource->mOgrGeometryTypeFilter != wkbUnknown;
if ( mFetchGeometry || useIntersect || geometryTypeFilter )
{
OGRGeometryH geom = OGR_F_GetGeometryRef( fet.get() );
if ( geom )
{
QgsGeometry g = QgsOgrUtils::ogrGeometryToQgsGeometry( geom );
// Insure that multipart datasets return multipart geometry
if ( QgsWkbTypes::isMultiType( mSource->mWkbType ) && !g.isMultipart() )
{
g.convertToMultiType();
}
feature.setGeometry( g );
}
else
feature.clearGeometry();
if ( mSource->mOgrGeometryTypeFilter == wkbGeometryCollection &&
geom && wkbFlatten( OGR_G_GetGeometryType( geom ) ) == wkbGeometryCollection )
{
// OK
}
else if ( ( useIntersect && ( !feature.hasGeometry()
|| ( mRequest.flags() & QgsFeatureRequest::ExactIntersect && !feature.geometry().intersects( mFilterRect ) )
|| ( !( mRequest.flags() & QgsFeatureRequest::ExactIntersect ) && !feature.geometry().boundingBoxIntersects( mFilterRect ) )
)
)
|| ( geometryTypeFilter && ( !feature.hasGeometry() || QgsOgrProvider::ogrWkbSingleFlatten( ( OGRwkbGeometryType )feature.geometry().wkbType() ) != mSource->mOgrGeometryTypeFilter ) ) )
{
return false;
}
}
if ( !mFetchGeometry )
{
feature.clearGeometry();
}
// fetch attributes
if ( mRequest.flags() & QgsFeatureRequest::SubsetOfAttributes )
{
QgsAttributeList attrs = mRequest.subsetOfAttributes();
for ( QgsAttributeList::const_iterator it = attrs.constBegin(); it != attrs.constEnd(); ++it )
{
getFeatureAttribute( fet.get(), feature, *it );
}
}
else
{
// all attributes
const auto fieldCount = mSource->mFields.count();
for ( int idx = 0; idx < fieldCount; ++idx )
{
getFeatureAttribute( fet.get(), feature, idx );
}
}
return true;
}
void QgsVectorLayerEditBuffer::updateFeatureGeometry( QgsFeature &f )
{
if ( mChangedGeometries.contains( f.id() ) )
f.setGeometry( mChangedGeometries[f.id()] );
}
bool QgsOgrFeatureIterator::readFeature( OGRFeatureH fet, QgsFeature& feature )
{
feature.setFeatureId( OGR_F_GetFID( fet ) );
feature.initAttributes( mSource->mFields.count() );
feature.setFields( &mSource->mFields ); // allow name-based attribute lookups
bool useIntersect = mRequest.flags() & QgsFeatureRequest::ExactIntersect;
bool geometryTypeFilter = mSource->mOgrGeometryTypeFilter != wkbUnknown;
if ( mFetchGeometry || useIntersect || geometryTypeFilter )
{
OGRGeometryH geom = OGR_F_GetGeometryRef( fet );
if ( geom )
{
if ( mGeometrySimplifier )
mGeometrySimplifier->simplifyGeometry( geom );
// get the wkb representation
int memorySize = OGR_G_WkbSize( geom );
unsigned char *wkb = new unsigned char[memorySize];
OGR_G_ExportToWkb( geom, ( OGRwkbByteOrder ) QgsApplication::endian(), wkb );
QgsGeometry* geometry = feature.geometry();
if ( !geometry ) feature.setGeometryAndOwnership( wkb, memorySize ); else geometry->fromWkb( wkb, memorySize );
}
else
feature.setGeometry( 0 );
if (( useIntersect && ( !feature.geometry() || !feature.geometry()->intersects( mRequest.filterRect() ) ) )
|| ( geometryTypeFilter && ( !feature.geometry() || QgsOgrProvider::ogrWkbSingleFlatten(( OGRwkbGeometryType )feature.geometry()->wkbType() ) != mSource->mOgrGeometryTypeFilter ) ) )
{
OGR_F_Destroy( fet );
return false;
}
}
if ( !mFetchGeometry )
{
feature.setGeometry( 0 );
}
// fetch attributes
if ( mRequest.flags() & QgsFeatureRequest::SubsetOfAttributes )
{
const QgsAttributeList& attrs = mRequest.subsetOfAttributes();
for ( QgsAttributeList::const_iterator it = attrs.begin(); it != attrs.end(); ++it )
{
getFeatureAttribute( fet, feature, *it );
}
}
else
{
// all attributes
for ( int idx = 0; idx < mSource->mFields.count(); ++idx )
{
getFeatureAttribute( fet, feature, idx );
}
}
return true;
}
void QgsGeometryTypeCheck::fixError( QgsGeometryCheckError* error, int method, int /*mergeAttributeIndex*/, Changes &changes ) const
{
QgsFeature feature;
if ( !mFeaturePool->get( error->featureId(), feature ) )
{
error->setObsolete();
return;
}
QgsAbstractGeometryV2* geom = feature.geometry()->geometry();
// Check if error still applies
QgsWKBTypes::Type type = QgsWKBTypes::flatType( geom->wkbType() );
if (( mAllowedTypes & ( 1 << type ) ) != 0 )
{
error->setObsolete();
return;
}
// Fix with selected method
if ( method == NoChange )
{
error->setFixed( method );
}
else if ( method == Convert )
{
// Check if corresponding single type is allowed
if ( QgsWKBTypes::isMultiType( type ) && (( 1 << QgsWKBTypes::singleType( type ) ) & mAllowedTypes ) != 0 )
{
// Explode multi-type feature into single-type features
for ( int iPart = 1, nParts = geom->partCount(); iPart < nParts; ++iPart )
{
QgsFeature newFeature;
newFeature.setAttributes( feature.attributes() );
newFeature.setGeometry( new QgsGeometry( QgsGeomUtils::getGeomPart( geom, iPart )->clone() ) );
mFeaturePool->addFeature( newFeature );
changes[newFeature.id()].append( Change( ChangeFeature, ChangeAdded ) );
}
// Recycle feature for part 0
feature.setGeometry( new QgsGeometry( QgsGeomUtils::getGeomPart( geom, 0 )->clone() ) );
mFeaturePool->updateFeature( feature );
changes[feature.id()].append( Change( ChangeFeature, ChangeChanged ) );
}
// Check if corresponding multi type is allowed
else if ( QgsWKBTypes::isSingleType( type ) && (( 1 << QgsWKBTypes::multiType( type ) ) & mAllowedTypes ) != 0 )
{
QgsGeometryCollectionV2* geomCollection = nullptr;
switch ( QgsWKBTypes::multiType( type ) )
{
case QgsWKBTypes::MultiPoint:
{
geomCollection = new QgsMultiPointV2();
break;
}
case QgsWKBTypes::MultiLineString:
{
geomCollection = new QgsMultiLineStringV2();
break;
}
case QgsWKBTypes::MultiPolygon:
{
geomCollection = new QgsMultiPolygonV2();
break;
}
case QgsWKBTypes::MultiCurve:
{
geomCollection = new QgsMultiCurveV2();
break;
}
case QgsWKBTypes::MultiSurface:
{
geomCollection = new QgsMultiSurfaceV2();
break;
}
default:
break;
}
if ( !geomCollection )
{
error->setFixFailed( tr( "Unknown geometry type" ) );
}
else
{
geomCollection->addGeometry( geom->clone() );
feature.setGeometry( new QgsGeometry( geomCollection ) );
mFeaturePool->updateFeature( feature );
changes[feature.id()].append( Change( ChangeFeature, ChangeChanged ) );
}
}
// Delete feature
else
{
mFeaturePool->deleteFeature( feature );
changes[error->featureId()].append( Change( ChangeFeature, ChangeRemoved ) );
}
error->setFixed( method );
}
else if ( method == Delete )
{
mFeaturePool->deleteFeature( feature );
error->setFixed( method );
changes[error->featureId()].append( Change( ChangeFeature, ChangeRemoved ) );
}
else
{
error->setFixFailed( tr( "Unknown method" ) );
}
}
bool QgsGeometryAnalyzer::dissolve( QgsVectorLayer* layer, const QString& shapefileName,
bool onlySelectedFeatures, int uniqueIdField, QProgressDialog* p )
{
if ( !layer )
{
return false;
}
QgsVectorDataProvider* dp = layer->dataProvider();
if ( !dp )
{
return false;
}
bool useField = false;
if ( uniqueIdField == -1 )
{
uniqueIdField = 0;
}
else
{
useField = true;
}
QGis::WkbType outputType = dp->geometryType();
QgsCoordinateReferenceSystem crs = layer->crs();
QgsVectorFileWriter vWriter( shapefileName, dp->encoding(), layer->fields(), outputType, &crs );
QgsFeature currentFeature;
QMultiMap<QString, QgsFeatureId> map;
if ( onlySelectedFeatures )
{
//use QgsVectorLayer::featureAtId
const QgsFeatureIds selection = layer->selectedFeaturesIds();
QgsFeatureIds::const_iterator it = selection.constBegin();
for ( ; it != selection.constEnd(); ++it )
{
if ( !layer->getFeatures( QgsFeatureRequest().setFilterFid( *it ) ).nextFeature( currentFeature ) )
{
continue;
}
map.insert( currentFeature.attribute( uniqueIdField ).toString(), currentFeature.id() );
}
}
else
{
QgsFeatureIterator fit = layer->getFeatures();
while ( fit.nextFeature( currentFeature ) )
{
map.insert( currentFeature.attribute( uniqueIdField ).toString(), currentFeature.id() );
}
}
QgsGeometry *dissolveGeometry = nullptr; //dissolve geometry
QMultiMap<QString, QgsFeatureId>::const_iterator jt = map.constBegin();
QgsFeature outputFeature;
while ( jt != map.constEnd() )
{
QString currentKey = jt.key();
int processedFeatures = 0;
bool first = true;
//take only selection
if ( onlySelectedFeatures )
{
//use QgsVectorLayer::featureAtId
const QgsFeatureIds selection = layer->selectedFeaturesIds();
if ( p )
{
p->setMaximum( selection.size() );
}
while ( jt != map.constEnd() && ( jt.key() == currentKey || !useField ) )
{
if ( p && p->wasCanceled() )
{
break;
}
if ( selection.contains( jt.value() ) )
{
if ( p )
{
p->setValue( processedFeatures );
}
if ( !layer->getFeatures( QgsFeatureRequest().setFilterFid( jt.value() ) ).nextFeature( currentFeature ) )
{
continue;
}
if ( first )
{
outputFeature.setAttributes( currentFeature.attributes() );
first = false;
}
dissolveFeature( currentFeature, processedFeatures, &dissolveGeometry );
++processedFeatures;
}
++jt;
}
}
//take all features
else
{
int featureCount = layer->featureCount();
if ( p )
{
p->setMaximum( featureCount );
}
while ( jt != map.constEnd() && ( jt.key() == currentKey || !useField ) )
{
if ( p )
{
p->setValue( processedFeatures );
}
if ( p && p->wasCanceled() )
{
break;
}
if ( !layer->getFeatures( QgsFeatureRequest().setFilterFid( jt.value() ) ).nextFeature( currentFeature ) )
{
continue;
}
{
outputFeature.setAttributes( currentFeature.attributes() );
first = false;
}
dissolveFeature( currentFeature, processedFeatures, &dissolveGeometry );
++processedFeatures;
++jt;
}
}
outputFeature.setGeometry( dissolveGeometry );
vWriter.addFeature( outputFeature );
}
return true;
}
bool QgsGeometryAnalyzer::buffer( QgsVectorLayer* layer, const QString& shapefileName, double bufferDistance,
bool onlySelectedFeatures, bool dissolve, int bufferDistanceField, QProgressDialog* p )
{
if ( !layer )
{
return false;
}
QgsVectorDataProvider* dp = layer->dataProvider();
if ( !dp )
{
return false;
}
QGis::WkbType outputType = QGis::WKBPolygon;
if ( dissolve )
{
outputType = QGis::WKBMultiPolygon;
}
QgsCoordinateReferenceSystem crs = layer->crs();
QgsVectorFileWriter vWriter( shapefileName, dp->encoding(), layer->fields(), outputType, &crs );
QgsFeature currentFeature;
QgsGeometry *dissolveGeometry = nullptr; //dissolve geometry (if dissolve enabled)
//take only selection
if ( onlySelectedFeatures )
{
//use QgsVectorLayer::featureAtId
const QgsFeatureIds selection = layer->selectedFeaturesIds();
if ( p )
{
p->setMaximum( selection.size() );
}
int processedFeatures = 0;
QgsFeatureIds::const_iterator it = selection.constBegin();
for ( ; it != selection.constEnd(); ++it )
{
if ( p )
{
p->setValue( processedFeatures );
}
if ( p && p->wasCanceled() )
{
break;
}
if ( !layer->getFeatures( QgsFeatureRequest().setFilterFid( *it ) ).nextFeature( currentFeature ) )
{
continue;
}
bufferFeature( currentFeature, processedFeatures, &vWriter, dissolve, &dissolveGeometry, bufferDistance, bufferDistanceField );
++processedFeatures;
}
if ( p )
{
p->setValue( selection.size() );
}
}
//take all features
else
{
QgsFeatureIterator fit = layer->getFeatures();
int featureCount = layer->featureCount();
if ( p )
{
p->setMaximum( featureCount );
}
int processedFeatures = 0;
while ( fit.nextFeature( currentFeature ) )
{
if ( p )
{
p->setValue( processedFeatures );
}
if ( p && p->wasCanceled() )
{
break;
}
bufferFeature( currentFeature, processedFeatures, &vWriter, dissolve, &dissolveGeometry, bufferDistance, bufferDistanceField );
++processedFeatures;
}
if ( p )
{
p->setValue( featureCount );
}
}
if ( dissolve )
{
QgsFeature dissolveFeature;
if ( !dissolveGeometry )
{
QgsDebugMsg( "no dissolved geometry - should not happen" );
return false;
}
dissolveFeature.setGeometry( dissolveGeometry );
vWriter.addFeature( dissolveFeature );
}
return true;
}
bool QgsGeometryAnalyzer::convexHull( QgsVectorLayer* layer, const QString& shapefileName,
bool onlySelectedFeatures, int uniqueIdField, QProgressDialog* p )
{
if ( !layer )
{
return false;
}
QgsVectorDataProvider* dp = layer->dataProvider();
if ( !dp )
{
return false;
}
bool useField = false;
if ( uniqueIdField == -1 )
{
uniqueIdField = 0;
}
else
{
useField = true;
}
QgsFields fields;
fields.append( QgsField( QString( "UID" ), QVariant::String ) );
fields.append( QgsField( QString( "AREA" ), QVariant::Double ) );
fields.append( QgsField( QString( "PERIM" ), QVariant::Double ) );
QGis::WkbType outputType = QGis::WKBPolygon;
QgsCoordinateReferenceSystem crs = layer->crs();
QgsVectorFileWriter vWriter( shapefileName, dp->encoding(), fields, outputType, &crs );
QgsFeature currentFeature;
QgsGeometry* dissolveGeometry = nullptr; //dissolve geometry
QMultiMap<QString, QgsFeatureId> map;
if ( onlySelectedFeatures )
{
//use QgsVectorLayer::featureAtId
const QgsFeatureIds selection = layer->selectedFeaturesIds();
QgsFeatureIds::const_iterator it = selection.constBegin();
for ( ; it != selection.constEnd(); ++it )
{
#if 0
if ( p )
{
p->setValue( processedFeatures );
}
if ( p && p->wasCanceled() )
{
// break; // it may be better to do something else here?
return false;
}
#endif
if ( !layer->getFeatures( QgsFeatureRequest().setFilterFid( *it ) ).nextFeature( currentFeature ) )
{
continue;
}
map.insert( currentFeature.attribute( uniqueIdField ).toString(), currentFeature.id() );
}
}
else
{
QgsFeatureIterator fit = layer->getFeatures();
while ( fit.nextFeature( currentFeature ) )
{
#if 0
if ( p )
{
p->setValue( processedFeatures );
}
if ( p && p->wasCanceled() )
{
// break; // it may be better to do something else here?
return false;
}
#endif
map.insert( currentFeature.attribute( uniqueIdField ).toString(), currentFeature.id() );
}
}
QMultiMap<QString, QgsFeatureId>::const_iterator jt = map.constBegin();
while ( jt != map.constEnd() )
{
QString currentKey = jt.key();
int processedFeatures = 0;
//take only selection
if ( onlySelectedFeatures )
{
//use QgsVectorLayer::featureAtId
const QgsFeatureIds selection = layer->selectedFeaturesIds();
if ( p )
{
p->setMaximum( selection.size() );
}
processedFeatures = 0;
while ( jt != map.constEnd() && ( jt.key() == currentKey || !useField ) )
{
if ( p && p->wasCanceled() )
{
break;
}
if ( selection.contains( jt.value() ) )
{
if ( p )
{
p->setValue( processedFeatures );
}
if ( !layer->getFeatures( QgsFeatureRequest().setFilterFid( jt.value() ) ).nextFeature( currentFeature ) )
{
continue;
}
convexFeature( currentFeature, processedFeatures, &dissolveGeometry );
++processedFeatures;
}
++jt;
}
QList<double> values;
if ( !dissolveGeometry )
{
QgsDebugMsg( "no dissolved geometry - should not happen" );
return false;
}
dissolveGeometry = dissolveGeometry->convexHull();
values = simpleMeasure( dissolveGeometry );
QgsAttributes attributes( 3 );
attributes[0] = QVariant( currentKey );
attributes[1] = values.at( 0 );
attributes[2] = values.at( 1 );
QgsFeature dissolveFeature;
dissolveFeature.setAttributes( attributes );
dissolveFeature.setGeometry( dissolveGeometry );
vWriter.addFeature( dissolveFeature );
}
//take all features
else
{
int featureCount = layer->featureCount();
if ( p )
{
p->setMaximum( featureCount );
}
processedFeatures = 0;
while ( jt != map.constEnd() && ( jt.key() == currentKey || !useField ) )
{
if ( p )
{
p->setValue( processedFeatures );
}
if ( p && p->wasCanceled() )
{
break;
}
if ( !layer->getFeatures( QgsFeatureRequest().setFilterFid( jt.value() ) ).nextFeature( currentFeature ) )
{
continue;
}
convexFeature( currentFeature, processedFeatures, &dissolveGeometry );
++processedFeatures;
++jt;
}
QList<double> values;
// QgsGeometry* tmpGeometry = 0;
if ( !dissolveGeometry )
{
QgsDebugMsg( "no dissolved geometry - should not happen" );
return false;
}
dissolveGeometry = dissolveGeometry->convexHull();
// values = simpleMeasure( tmpGeometry );
values = simpleMeasure( dissolveGeometry );
QgsAttributes attributes;
attributes[0] = QVariant( currentKey );
attributes[1] = QVariant( values[ 0 ] );
attributes[2] = QVariant( values[ 1 ] );
QgsFeature dissolveFeature;
dissolveFeature.setAttributes( attributes );
dissolveFeature.setGeometry( dissolveGeometry );
vWriter.addFeature( dissolveFeature );
}
}
return true;
}
bool QgsGeometryAnalyzer::extent( QgsVectorLayer* layer,
const QString& shapefileName,
bool onlySelectedFeatures,
QProgressDialog * )
{
if ( !layer )
{
return false;
}
QgsVectorDataProvider* dp = layer->dataProvider();
if ( !dp )
{
return false;
}
QGis::WkbType outputType = QGis::WKBPolygon;
QgsCoordinateReferenceSystem crs = layer->crs();
QgsFields fields;
fields.append( QgsField( QString( "MINX" ), QVariant::Double ) );
fields.append( QgsField( QString( "MINY" ), QVariant::Double ) );
fields.append( QgsField( QString( "MAXX" ), QVariant::Double ) );
fields.append( QgsField( QString( "MAXY" ), QVariant::Double ) );
fields.append( QgsField( QString( "CNTX" ), QVariant::Double ) );
fields.append( QgsField( QString( "CNTY" ), QVariant::Double ) );
fields.append( QgsField( QString( "AREA" ), QVariant::Double ) );
fields.append( QgsField( QString( "PERIM" ), QVariant::Double ) );
fields.append( QgsField( QString( "HEIGHT" ), QVariant::Double ) );
fields.append( QgsField( QString( "WIDTH" ), QVariant::Double ) );
QgsVectorFileWriter vWriter( shapefileName, dp->encoding(), fields, outputType, &crs );
QgsRectangle rect;
if ( onlySelectedFeatures ) // take only selection
{
rect = layer->boundingBoxOfSelected();
}
else
{
rect = layer->extent();
}
double minx = rect.xMinimum();
double miny = rect.yMinimum();
double maxx = rect.xMaximum();
double maxy = rect.yMaximum();
double height = rect.height();
double width = rect.width();
double cntx = minx + ( width / 2.0 );
double cnty = miny + ( height / 2.0 );
double area = width * height;
double perim = ( 2 * width ) + ( 2 * height );
QgsFeature feat;
QgsAttributes attrs( 10 );
attrs[0] = QVariant( minx );
attrs[1] = QVariant( miny );
attrs[2] = QVariant( maxx );
attrs[3] = QVariant( maxy );
attrs[4] = QVariant( cntx );
attrs[5] = QVariant( cnty );
attrs[6] = QVariant( area );
attrs[7] = QVariant( perim );
attrs[8] = QVariant( height );
attrs[9] = QVariant( width );
feat.setAttributes( attrs );
feat.setGeometry( QgsGeometry::fromRect( rect ) );
vWriter.addFeature( feat );
return true;
}
void QgsMapToolOffsetCurve::applyOffset()
{
QgsVectorLayer* layer = currentVectorLayer();
if ( !layer )
{
deleteRubberBandAndGeometry();
notifyNotVectorLayer();
return;
}
// no modification
if ( !mGeometryModified )
{
deleteRubberBandAndGeometry();
layer->destroyEditCommand();
deleteDistanceWidget();
return;
}
if ( mMultiPartGeometry )
{
mModifiedGeometry.convertToMultiType();
}
layer->beginEditCommand( tr( "Offset curve" ) );
bool editOk;
if ( mSourceLayerId == layer->id() && !mForceCopy )
{
editOk = layer->changeGeometry( mModifiedFeature, &mModifiedGeometry );
}
else
{
QgsFeature f;
f.setGeometry( mModifiedGeometry );
//add empty values for all fields (allows inserting attribute values via the feature form in the same session)
QgsAttributes attrs( layer->fields().count() );
const QgsFields& fields = layer->fields();
for ( int idx = 0; idx < fields.count(); ++idx )
{
attrs[idx] = QVariant();
}
f.setAttributes( attrs );
editOk = layer->addFeature( f );
}
if ( editOk )
{
layer->endEditCommand();
}
else
{
layer->destroyEditCommand();
}
deleteRubberBandAndGeometry();
deleteDistanceWidget();
delete mSnapVertexMarker;
mSnapVertexMarker = nullptr;
mForceCopy = false;
mCanvas->refresh();
}
bool QgsPostgresFeatureIterator::fetchFeature( QgsFeature& feature )
{
feature.setValid( false );
if ( mClosed )
return false;
if ( mFeatureQueue.empty() )
{
QString fetch = QString( "FETCH FORWARD %1 FROM %2" ).arg( mFeatureQueueSize ).arg( mCursorName );
QgsDebugMsgLevel( QString( "fetching %1 features." ).arg( mFeatureQueueSize ), 4 );
if ( mConn->PQsendQuery( fetch ) == 0 ) // fetch features asynchronously
{
QgsMessageLog::logMessage( QObject::tr( "Fetching from cursor %1 failed\nDatabase error: %2" ).arg( mCursorName ).arg( mConn->PQerrorMessage() ), QObject::tr( "PostGIS" ) );
}
QgsPostgresResult queryResult;
for ( ;; )
{
queryResult = mConn->PQgetResult();
if ( !queryResult.result() )
break;
if ( queryResult.PQresultStatus() != PGRES_TUPLES_OK )
{
QgsMessageLog::logMessage( QObject::tr( "Fetching from cursor %1 failed\nDatabase error: %2" ).arg( mCursorName ).arg( mConn->PQerrorMessage() ), QObject::tr( "PostGIS" ) );
break;
}
int rows = queryResult.PQntuples();
if ( rows == 0 )
continue;
for ( int row = 0; row < rows; row++ )
{
mFeatureQueue.enqueue( QgsFeature() );
getFeature( queryResult, row, mFeatureQueue.back() );
} // for each row in queue
}
}
if ( mFeatureQueue.empty() )
{
QgsDebugMsg( QString( "Finished after %1 features" ).arg( mFetched ) );
close();
mSource->mShared->ensureFeaturesCountedAtLeast( mFetched );
return false;
}
// Now return the next feature from the queue
if ( !mFetchGeometry )
{
feature.setGeometryAndOwnership( 0, 0 );
}
else
{
QgsGeometry* featureGeom = mFeatureQueue.front().geometryAndOwnership();
feature.setGeometry( featureGeom );
}
feature.setFeatureId( mFeatureQueue.front().id() );
feature.setAttributes( mFeatureQueue.front().attributes() );
mFeatureQueue.dequeue();
mFetched++;
feature.setValid( true );
feature.setFields( &mSource->mFields ); // allow name-based attribute lookups
return true;
}
void QgsGeometryAngleCheck::fixError( QgsGeometryCheckError *error, int method, int /*mergeAttributeIndex*/, Changes &changes ) const
{
QgsFeature feature;
if ( !mFeaturePool->get( error->featureId(), feature ) )
{
error->setObsolete();
return;
}
QgsGeometry g = feature.geometry();
QgsAbstractGeometry *geometry = g.geometry();
QgsVertexId vidx = error->vidx();
// Check if point still exists
if ( !vidx.isValid( geometry ) )
{
error->setObsolete();
return;
}
// Check if error still applies
int n = QgsGeometryCheckerUtils::polyLineSize( geometry, vidx.part, vidx.ring );
if ( n == 0 )
{
error->setObsolete();
return;
}
const QgsPoint &p1 = geometry->vertexAt( QgsVertexId( vidx.part, vidx.ring, ( vidx.vertex - 1 + n ) % n ) );
const QgsPoint &p2 = geometry->vertexAt( vidx );
const QgsPoint &p3 = geometry->vertexAt( QgsVertexId( vidx.part, vidx.ring, ( vidx.vertex + 1 ) % n ) );
QgsVector v21, v23;
try
{
v21 = QgsVector( p1.x() - p2.x(), p1.y() - p2.y() ).normalized();
v23 = QgsVector( p3.x() - p2.x(), p3.y() - p2.y() ).normalized();
}
catch ( const QgsException & )
{
error->setObsolete();
return;
}
double angle = std::acos( v21 * v23 ) / M_PI * 180.0;
if ( angle >= mMinAngle )
{
error->setObsolete();
return;
}
// Fix error
if ( method == NoChange )
{
error->setFixed( method );
}
else if ( method == DeleteNode )
{
if ( !QgsGeometryCheckerUtils::canDeleteVertex( geometry, vidx.part, vidx.ring ) )
{
error->setFixFailed( tr( "Resulting geometry is degenerate" ) );
}
else if ( !geometry->deleteVertex( error->vidx() ) )
{
error->setFixFailed( tr( "Failed to delete vertex" ) );
}
else
{
changes[error->featureId()].append( Change( ChangeNode, ChangeRemoved, vidx ) );
if ( QgsGeometryUtils::sqrDistance2D( p1, p3 ) < QgsGeometryCheckPrecision::tolerance() * QgsGeometryCheckPrecision::tolerance()
&& QgsGeometryCheckerUtils::canDeleteVertex( geometry, vidx.part, vidx.ring ) &&
geometry->deleteVertex( error->vidx() ) ) // error->vidx points to p3 after removing p2
{
changes[error->featureId()].append( Change( ChangeNode, ChangeRemoved, QgsVertexId( vidx.part, vidx.ring, ( vidx.vertex + 1 ) % n ) ) );
}
feature.setGeometry( g );
mFeaturePool->updateFeature( feature );
error->setFixed( method );
}
}
else
{
error->setFixFailed( tr( "Unknown method" ) );
}
}
