def simpleMeasure(geom, method=0, ellips=None, crs=None): # Method defines calculation type: # 0 - layer CRS # 1 - project CRS # 2 - ellipsoidal if geom.type() == QgsWkbTypes.PointGeometry: if not geom.isMultipart(): pt = geom.geometry() attr1 = pt.x() attr2 = pt.y() else: pt = geom.asMultiPoint() attr1 = pt[0].x() attr2 = pt[0].y() else: measure = QgsDistanceArea() if method == 2: measure.setSourceCrs(crs) measure.setEllipsoid(ellips) measure.setEllipsoidalMode(True) if geom.type() == QgsWkbTypes.PolygonGeometry: attr1 = measure.measureArea(geom) attr2 = measure.measurePerimeter(geom) else: attr1 = measure.measureLength(geom) attr2 = None return (attr1, attr2)
def processAlgorithm(self, parameters, context, feedback): if parameters[self.INPUT] == parameters[self.HUBS]: raise QgsProcessingException( self.tr('Same layer given for both hubs and spokes')) point_source = self.parameterAsSource(parameters, self.INPUT, context) hub_source = self.parameterAsSource(parameters, self.HUBS, context) fieldName = self.parameterAsString(parameters, self.FIELD, context) units = self.UNITS[self.parameterAsEnum(parameters, self.UNIT, context)] fields = point_source.fields() fields.append(QgsField('HubName', QVariant.String)) fields.append(QgsField('HubDist', QVariant.Double)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, QgsWkbTypes.Point, point_source.sourceCrs()) index = QgsSpatialIndex(hub_source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes([]).setDestinationCrs(point_source.sourceCrs(), context.transformContext()))) distance = QgsDistanceArea() distance.setSourceCrs(point_source.sourceCrs(), context.transformContext()) distance.setEllipsoid(context.project().ellipsoid()) # Scan source points, find nearest hub, and write to output file features = point_source.getFeatures() total = 100.0 / point_source.featureCount() if point_source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break if not f.hasGeometry(): sink.addFeature(f, QgsFeatureSink.FastInsert) continue src = f.geometry().boundingBox().center() neighbors = index.nearestNeighbor(src, 1) ft = next(hub_source.getFeatures(QgsFeatureRequest().setFilterFid(neighbors[0]).setSubsetOfAttributes([fieldName], hub_source.fields()).setDestinationCrs(point_source.sourceCrs(), context.transformContext()))) closest = ft.geometry().boundingBox().center() hubDist = distance.measureLine(src, closest) if units != self.LAYER_UNITS: hub_dist_in_desired_units = distance.convertLengthMeasurement(hubDist, units) else: hub_dist_in_desired_units = hubDist attributes = f.attributes() attributes.append(ft[fieldName]) attributes.append(hub_dist_in_desired_units) feat = QgsFeature() feat.setAttributes(attributes) feat.setGeometry(QgsGeometry.fromPointXY(src)) sink.addFeature(feat, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def prepareAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, 'INPUT', context) mapping = self.parameterAsFieldsMapping(parameters, self.FIELDS_MAPPING, context) self.fields = QgsFields() self.expressions = [] da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs()) da.setEllipsoid(context.project().ellipsoid()) # create an expression context using thread safe processing context self.expr_context = self.createExpressionContext(parameters, context, source) for field_def in mapping: self.fields.append(QgsField(name=field_def['name'], type=field_def['type'], typeName="", len=field_def.get('length', 0), prec=field_def.get('precision', 0))) expression = QgsExpression(field_def['expression']) expression.setGeomCalculator(da) expression.setDistanceUnits(context.project().distanceUnits()) expression.setAreaUnits(context.project().areaUnits()) if expression.hasParserError(): raise QgsProcessingException( self.tr(u'Parser error in expression "{}": {}') .format(str(expression.expression()), str(expression.parserErrorString()))) self.expressions.append(expression) return True
def simpleMeasure(geom, method=0, ellips=None, crs=None): # Method defines calculation type: # 0 - layer CRS # 1 - project CRS # 2 - ellipsoidal if geom.wkbType() in [QGis.WKBPoint, QGis.WKBPoint25D]: pt = geom.asPoint() attr1 = pt.x() attr2 = pt.y() elif geom.wkbType() in [QGis.WKBMultiPoint, QGis.WKBMultiPoint25D]: pt = geom.asMultiPoint() attr1 = pt[0].x() attr2 = pt[0].y() else: measure = QgsDistanceArea() if method == 2: measure.setSourceCrs(crs) measure.setEllipsoid(ellips) measure.setEllipsoidalMode(True) attr1 = measure.measure(geom) if geom.type() == QGis.Polygon: attr2 = measure.measurePerimeter(geom) else: attr2 = None return (attr1, attr2)
def testRenderMetersInMapUnits(self): crs_wsg84 = QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:4326') rt_extent = QgsRectangle(13.37768985634235, 52.51625705830762, 13.37771931686235, 52.51628651882762) point_berlin_wsg84 = QgsPointXY(13.37770458660236, 52.51627178856762) length_wsg84_mapunits = 0.00001473026350140572 meters_test = 2.40 da_wsg84 = QgsDistanceArea() da_wsg84.setSourceCrs(crs_wsg84, QgsProject.instance().transformContext()) if (da_wsg84.sourceCrs().isGeographic()): da_wsg84.setEllipsoid(da_wsg84.sourceCrs().ellipsoidAcronym()) length_meter_mapunits = da_wsg84.measureLineProjected(point_berlin_wsg84, 1.0, (math.pi / 2)) meters_test_mapunits = meters_test * length_wsg84_mapunits meters_test_pixel = meters_test * length_wsg84_mapunits ms = QgsMapSettings() ms.setDestinationCrs(crs_wsg84) ms.setExtent(rt_extent) r = QgsRenderContext.fromMapSettings(ms) r.setExtent(rt_extent) self.assertEqual(r.extent().center().toString(7), point_berlin_wsg84.toString(7)) c = QgsMapUnitScale() r.setDistanceArea(da_wsg84) result_test_painterunits = r.convertToPainterUnits(meters_test, QgsUnitTypes.RenderMetersInMapUnits, c) self.assertEqual(QgsDistanceArea.formatDistance(result_test_painterunits, 7, QgsUnitTypes.DistanceUnknownUnit, True), QgsDistanceArea.formatDistance(meters_test_mapunits, 7, QgsUnitTypes.DistanceUnknownUnit, True)) result_test_mapunits = r.convertToMapUnits(meters_test, QgsUnitTypes.RenderMetersInMapUnits, c) self.assertEqual(QgsDistanceArea.formatDistance(result_test_mapunits, 7, QgsUnitTypes.DistanceDegrees, True), QgsDistanceArea.formatDistance(meters_test_mapunits, 7, QgsUnitTypes.DistanceDegrees, True)) result_test_meters = r.convertFromMapUnits(meters_test_mapunits, QgsUnitTypes.RenderMetersInMapUnits) self.assertEqual(QgsDistanceArea.formatDistance(result_test_meters, 1, QgsUnitTypes.DistanceMeters, True), QgsDistanceArea.formatDistance(meters_test, 1, QgsUnitTypes.DistanceMeters, True))
def _calc_north(self): extent = self.canvas.extent() if self.canvas.layerCount() == 0 or extent.isEmpty(): print "No layers or extent" return 0 outcrs = self.canvas.mapSettings().destinationCrs() if outcrs.isValid() and not outcrs.geographicFlag(): crs = QgsCoordinateReferenceSystem() crs.createFromOgcWmsCrs("EPSG:4326") transform = QgsCoordinateTransform(outcrs, crs) p1 = QgsPoint(extent.center()) p2 = QgsPoint(p1.x(), p1.y() + extent.height() * 0.25) try: pp1 = transform.transform(p1) pp2 = transform.transform(p2) except QgsCsException: roam.utils.warning("North arrow. Error transforming.") return None area = QgsDistanceArea() area.setEllipsoid(crs.ellipsoidAcronym()) area.setEllipsoidalMode(True) area.setSourceCrs(crs) distance, angle, _ = area.computeDistanceBearing(pp1, pp2) angle = math.degrees(angle) return angle else: return 0
def processAlgorithm(self, parameters, context, feedback): layerPoints = QgsProcessingUtils.mapLayerFromString(self.getParameterValue(self.POINTS), context) layerHubs = QgsProcessingUtils.mapLayerFromString(self.getParameterValue(self.HUBS), context) fieldName = self.getParameterValue(self.FIELD) units = self.UNITS[self.getParameterValue(self.UNIT)] if layerPoints.source() == layerHubs.source(): raise GeoAlgorithmExecutionException( self.tr('Same layer given for both hubs and spokes')) fields = layerPoints.fields() fields.append(QgsField('HubName', QVariant.String)) fields.append(QgsField('HubDist', QVariant.Double)) writer = self.getOutputFromName(self.OUTPUT).getVectorWriter(fields, QgsWkbTypes.LineString, layerPoints.crs(), context) index = QgsProcessingUtils.createSpatialIndex(layerHubs, context) distance = QgsDistanceArea() distance.setSourceCrs(layerPoints.crs()) distance.setEllipsoid(QgsProject.instance().ellipsoid()) # Scan source points, find nearest hub, and write to output file features = QgsProcessingUtils.getFeatures(layerPoints, context) total = 100.0 / layerPoints.featureCount() if layerPoints.featureCount() else 0 for current, f in enumerate(features): src = f.geometry().boundingBox().center() neighbors = index.nearestNeighbor(src, 1) ft = next(layerHubs.getFeatures(QgsFeatureRequest().setFilterFid(neighbors[0]).setSubsetOfAttributes([fieldName], layerHubs.fields()))) closest = ft.geometry().boundingBox().center() hubDist = distance.measureLine(src, closest) attributes = f.attributes() attributes.append(ft[fieldName]) if units == 'Feet': attributes.append(hubDist * 3.2808399) elif units == 'Miles': attributes.append(hubDist * 0.000621371192) elif units == 'Kilometers': attributes.append(hubDist / 1000.0) elif units != 'Meters': attributes.append(sqrt( pow(src.x() - closest.x(), 2.0) + pow(src.y() - closest.y(), 2.0))) else: attributes.append(hubDist) feat = QgsFeature() feat.setAttributes(attributes) feat.setGeometry(QgsGeometry.fromPolyline([src, closest])) writer.addFeature(feat, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) del writer
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) layer = self.parameterAsVectorLayer(parameters, self.INPUT, context) field_name = self.parameterAsString(parameters, self.FIELD_NAME, context) field_type = self.TYPES[self.parameterAsEnum(parameters, self.FIELD_TYPE, context)] width = self.parameterAsInt(parameters, self.FIELD_LENGTH, context) precision = self.parameterAsInt(parameters, self.FIELD_PRECISION, context) new_field = self.parameterAsBool(parameters, self.NEW_FIELD, context) formula = self.parameterAsString(parameters, self.FORMULA, context) expression = QgsExpression(formula) da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs()) da.setEllipsoid(context.project().ellipsoid()) expression.setGeomCalculator(da) expression.setDistanceUnits(context.project().distanceUnits()) expression.setAreaUnits(context.project().areaUnits()) fields = source.fields() field_index = fields.lookupField(field_name) if new_field or field_index < 0: fields.append(QgsField(field_name, field_type, '', width, precision)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, source.wkbType(), source.sourceCrs()) exp_context = self.createExpressionContext(parameters, context) if layer is not None: exp_context.appendScope(QgsExpressionContextUtils.layerScope(layer)) if not expression.prepare(exp_context): raise QgsProcessingException( self.tr('Evaluation error: {0}').format(expression.parserErrorString())) features = source.getFeatures() total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break rownum = current + 1 exp_context.setFeature(f) exp_context.lastScope().setVariable("row_number", rownum) value = expression.evaluate(exp_context) if expression.hasEvalError(): feedback.reportError(expression.evalErrorString()) else: attrs = f.attributes() if new_field or field_index < 0: attrs.append(value) else: attrs[field_index] = value f.setAttributes(attrs) sink.addFeature(f, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def testCrs(self): # test setting/getting the source CRS da = QgsDistanceArea() # try setting using a CRS object crs = QgsCoordinateReferenceSystem(3111, QgsCoordinateReferenceSystem.EpsgCrsId) da.setSourceCrs(crs, QgsProject.instance().transformContext()) self.assertEqual(da.sourceCrs().srsid(), crs.srsid())
def calculateDistance(self, p1, p2): distance = QgsDistanceArea() distance.setSourceCrs(self.iface.activeLayer().crs()) distance.setEllipsoidalMode(True) # Sirgas 2000 distance.setEllipsoid('GRS1980') m = distance.measureLine(p1, p2) return m
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException(self.invalidSourceError(parameters, self.INPUT)) output_file = self.parameterAsFileOutput(parameters, self.OUTPUT_HTML_FILE, context) spatialIndex = QgsSpatialIndex(source, feedback) distance = QgsDistanceArea() distance.setSourceCrs(source.sourceCrs(), context.transformContext()) distance.setEllipsoid(context.project().ellipsoid()) sumDist = 0.00 A = source.sourceExtent() A = float(A.width() * A.height()) features = source.getFeatures() count = source.featureCount() total = 100.0 / count if count else 1 for current, feat in enumerate(features): if feedback.isCanceled(): break neighbourID = spatialIndex.nearestNeighbor( feat.geometry().asPoint(), 2)[1] request = QgsFeatureRequest().setFilterFid(neighbourID).setSubsetOfAttributes([]) neighbour = next(source.getFeatures(request)) sumDist += distance.measureLine(neighbour.geometry().asPoint(), feat.geometry().asPoint()) feedback.setProgress(int(current * total)) do = float(sumDist) / count de = float(0.5 / math.sqrt(count / A)) d = float(do / de) SE = float(0.26136 / math.sqrt(count ** 2 / A)) zscore = float((do - de) / SE) results = {} results[self.OBSERVED_MD] = do results[self.EXPECTED_MD] = de results[self.NN_INDEX] = d results[self.POINT_COUNT] = count results[self.Z_SCORE] = zscore if output_file: data = [] data.append('Observed mean distance: ' + str(do)) data.append('Expected mean distance: ' + str(de)) data.append('Nearest neighbour index: ' + str(d)) data.append('Number of points: ' + str(count)) data.append('Z-Score: ' + str(zscore)) self.createHTML(output_file, data) results[self.OUTPUT_HTML_FILE] = output_file return results
def testLengthMeasureAndUnits(self): """Test a variety of length measurements in different CRS and ellipsoid modes, to check that the calculated lengths and units are always consistent """ da = QgsDistanceArea() da.setSourceCrs(QgsCoordinateReferenceSystem.fromSrsId(3452), QgsProject.instance().transformContext()) da.setEllipsoid("NONE") # We check both the measured length AND the units, in case the logic regarding # ellipsoids and units changes in future distance = da.measureLine(QgsPointXY(1, 1), QgsPointXY(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) assert ((abs(distance - 2.23606797) < 0.00000001 and units == QgsUnitTypes.DistanceDegrees) or (abs(distance - 248.52) < 0.01 and units == QgsUnitTypes.DistanceMeters)) da.setEllipsoid("WGS84") distance = da.measureLine(QgsPointXY(1, 1), QgsPointXY(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) # should always be in Meters self.assertAlmostEqual(distance, 247555.57, delta=0.01) self.assertEqual(units, QgsUnitTypes.DistanceMeters) # test converting the resultant length distance = da.convertLengthMeasurement(distance, QgsUnitTypes.DistanceNauticalMiles) self.assertAlmostEqual(distance, 133.669, delta=0.01) # now try with a source CRS which is in feet da.setSourceCrs(QgsCoordinateReferenceSystem.fromSrsId(27469), QgsProject.instance().transformContext()) da.setEllipsoid("NONE") # measurement should be in feet distance = da.measureLine(QgsPointXY(1, 1), QgsPointXY(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) self.assertAlmostEqual(distance, 2.23606797, delta=0.000001) self.assertEqual(units, QgsUnitTypes.DistanceFeet) # test converting the resultant length distance = da.convertLengthMeasurement(distance, QgsUnitTypes.DistanceMeters) self.assertAlmostEqual(distance, 0.6815, delta=0.001) da.setEllipsoid("WGS84") # now should be in Meters again distance = da.measureLine(QgsPointXY(1, 1), QgsPointXY(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) self.assertAlmostEqual(distance, 0.67953772, delta=0.000001) self.assertEqual(units, QgsUnitTypes.DistanceMeters) # test converting the resultant length distance = da.convertLengthMeasurement(distance, QgsUnitTypes.DistanceFeet) self.assertAlmostEqual(distance, 2.2294, delta=0.001)
def get_distance_area(self, layer): destination = layer.crs() distance_area = QgsDistanceArea() distance_area.setSourceCrs(layer.crs()) distance_area.setEllipsoid(destination.ellipsoidAcronym()) # sets whether coordinates must be projected to ellipsoid before measuring distance_area.setEllipsoidalMode(True) return distance_area
def testLengthMeasureAndUnits(self): """Test a variety of length measurements in different CRS and ellipsoid modes, to check that the calculated lengths and units are always consistent """ da = QgsDistanceArea() da.setSourceCrs(3452) da.setEllipsoidalMode(False) da.setEllipsoid("NONE") daCRS = QgsCoordinateReferenceSystem() daCRS.createFromSrsId(da.sourceCrs()) # We check both the measured length AND the units, in case the logic regarding # ellipsoids and units changes in future distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print "measured {} in {}".format(distance, QgsUnitTypes.toString(units)) assert ((abs(distance - 2.23606797) < 0.00000001 and units == QGis.Degrees) or (abs(distance - 248.52) < 0.01 and units == QGis.Meters)) da.setEllipsoid("WGS84") distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print "measured {} in {}".format(distance, QgsUnitTypes.toString(units)) assert ((abs(distance - 2.23606797) < 0.00000001 and units == QGis.Degrees) or (abs(distance - 248.52) < 0.01 and units == QGis.Meters)) da.setEllipsoidalMode(True) distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print "measured {} in {}".format(distance, QgsUnitTypes.toString(units)) # should always be in Meters self.assertAlmostEqual(distance, 247555.57, delta=0.01) self.assertEqual(units, QGis.Meters) # now try with a source CRS which is in feet da.setSourceCrs(27469) da.setEllipsoidalMode(False) # measurement should be in feet distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print "measured {} in {}".format(distance, QgsUnitTypes.toString(units)) self.assertAlmostEqual(distance, 2.23606797, delta=0.000001) self.assertEqual(units, QGis.Feet) da.setEllipsoidalMode(True) # now should be in Meters again distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print "measured {} in {}".format(distance, QgsUnitTypes.toString(units)) self.assertAlmostEqual(distance, 0.67953772, delta=0.000001) self.assertEqual(units, QGis.Meters)
def regularMatrix(self, parameters, context, source, inField, target_source, targetField, nPoints, feedback): distArea = QgsDistanceArea() distArea.setSourceCrs(source.sourceCrs(), context.transformContext()) distArea.setEllipsoid(context.project().ellipsoid()) inIdx = source.fields().lookupField(inField) targetIdx = target_source.fields().lookupField(targetField) index = QgsSpatialIndex(target_source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes([]).setDestinationCrs(source.sourceCrs(), context.transformContext())), feedback) first = True sink = None dest_id = None features = source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes([inIdx])) total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, inFeat in enumerate(features): if feedback.isCanceled(): break inGeom = inFeat.geometry() if first: featList = index.nearestNeighbor(inGeom.asPoint(), nPoints) first = False fields = QgsFields() input_id_field = source.fields()[inIdx] input_id_field.setName('ID') fields.append(input_id_field) for f in target_source.getFeatures(QgsFeatureRequest().setFilterFids(featList).setSubsetOfAttributes([targetIdx]).setDestinationCrs(source.sourceCrs(), context.transformContext())): fields.append(QgsField(str(f[targetField]), QVariant.Double)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, source.wkbType(), source.sourceCrs()) if sink is None: raise QgsProcessingException(self.invalidSinkError(parameters, self.OUTPUT)) data = [inFeat[inField]] for target in target_source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes([]).setFilterFids(featList).setDestinationCrs(source.sourceCrs(), context.transformContext())): if feedback.isCanceled(): break outGeom = target.geometry() dist = distArea.measureLine(inGeom.asPoint(), outGeom.asPoint()) data.append(dist) out_feature = QgsFeature() out_feature.setGeometry(inGeom) out_feature.setAttributes(data) sink.addFeature(out_feature, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def testCrs(self): # test setting/getting the source CRS da = QgsDistanceArea() # try setting using a crs id da.setSourceCrs(3452) self.assertEqual(da.sourceCrsId(), 3452) # try setting using a CRS object crs = QgsCoordinateReferenceSystem(3111, QgsCoordinateReferenceSystem.EpsgCrsId) da.setSourceCrs(crs) self.assertEqual(da.sourceCrsId(), crs.srsid())
def calculate( self, layer, fieldName, expression ): if ( layer.featureCount() == 0 ): self.msg.show( "[Info] * No existing features on layer " + layer.name() + " to calculate expression.", 'info', True ) return expression = QgsExpression( expression ) if expression.hasParserError(): self.msg.show( QApplication.translate( "AutoFields-FieldCalculator", "[Error] (Parsing) " ) + \ expression.parserErrorString(), 'critical' ) return context = QgsExpressionContext() context.appendScope( QgsExpressionContextUtils.globalScope() ) context.appendScope( QgsExpressionContextUtils.projectScope() ) context.appendScope( QgsExpressionContextUtils.layerScope( layer ) ) context.setFields( layer.fields() ) if expression.needsGeometry(): if self.iface: # This block was borrowed from QGIS/python/plugins/processing/algs/qgis/FieldsCalculator.py da = QgsDistanceArea() da.setSourceCrs( layer.crs().srsid() ) da.setEllipsoidalMode( self.iface.mapCanvas().mapSettings().hasCrsTransformEnabled() ) da.setEllipsoid( QgsProject.instance().readEntry( 'Measure', '/Ellipsoid', GEO_NONE )[0] ) expression.setGeomCalculator( da ) if QGis.QGIS_VERSION_INT >= 21400: # Methods added in QGIS 2.14 expression.setDistanceUnits( QgsProject.instance().distanceUnits() ) expression.setAreaUnits( QgsProject.instance().areaUnits() ) expression.prepare( context ) fieldIndex = layer.fieldNameIndex( fieldName ) if fieldIndex == -1: return field = layer.fields()[fieldIndex] dictResults = {} for feature in layer.getFeatures(): context.setFeature( feature ) result = expression.evaluate( context ) if expression.hasEvalError(): self.msg.show( QApplication.translate( "AutoFields-FieldCalculator", "[Error] (Evaluating) " ) + \ expression.evalErrorString(), 'critical' ) return dictResults[feature.id()] = { fieldIndex: field.convertCompatible( result ) } layer.dataProvider().changeAttributeValues( dictResults ) self.msg.show( "[Info] * An expression was calculated on existing features of layer " + layer.name() + ", field " + fieldName + ".", 'info', True )
def prepareAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException(self.invalidSourceError(parameters, self.INPUT)) group_by = self.parameterAsExpression(parameters, self.GROUP_BY, context) aggregates = self.parameterAsAggregates(parameters, self.AGGREGATES, context) da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) self.source = source self.group_by = group_by self.group_by_expr = self.createExpression(group_by, da, context) self.geometry_expr = self.createExpression('collect($geometry, {})'.format(group_by), da, context) self.fields = QgsFields() self.fields_expr = [] for field_def in aggregates: self.fields.append(QgsField(name=field_def['name'], type=field_def['type'], typeName="", len=field_def['length'], prec=field_def['precision'])) aggregate = field_def['aggregate'] if aggregate == 'first_value': expression = field_def['input'] elif aggregate == 'concatenate': expression = ('{}({}, {}, {}, \'{}\')' .format(field_def['aggregate'], field_def['input'], group_by, 'TRUE', field_def['delimiter'])) else: expression = '{}({}, {})'.format(field_def['aggregate'], field_def['input'], group_by) expr = self.createExpression(expression, da, context) self.fields_expr.append(expr) return True
def impact_table(self): """Return data as dictionary""" # prepare area calculator object area_calc = QgsDistanceArea() area_calc.setSourceCrs(self.impact_layer.crs()) area_calc.setEllipsoid('WGS84') area_calc.setEllipsoidalMode(True) impacted_table = FlatTable('landcover', 'hazard', 'zone') for f in self.impact_layer.getFeatures(): area = area_calc.measure(f.geometry()) / 1e4 zone = f[self.zone_field] if self.zone_field is not None else None impacted_table.add_value( area, landcover=f[self.land_cover_field], hazard=f[self.target_field], zone=zone) return impacted_table.to_dict()
def evaluation(self=None, parameters={},feature=None): from PyQt4.QtCore import QVariant from qgis.core import QgsDistanceArea, QgsCoordinateReferenceSystem ar = NULL per = NULL id = NULL flr = NULL usage = NULL kind = NULL da_engine=QgsDistanceArea() da_engine.setSourceCrs(QgsCoordinateReferenceSystem(int(config.project_crs.split(':')[-1]), QgsCoordinateReferenceSystem.EpsgCrsId)) da_engine.setEllipsoid(config.project_ellipsoid) da_engine.setEllipsoidalMode(True) if feature: geometry = feature.geometry() #print geometry ar = da_engine.measureArea(geometry) per =da_engine.measurePerimeter(geometry) id = feature[config.building_id_key] #necessary to safe dependency check flr = feature[u'FLRS_ALK'] # necessary to safe dependency check usage = feature[u'FUNC_ALK'] # necessary to safe dependency check kind = feature[u'KIND_ALK'] # necessary to safe dependency check #print ar #print per #print id return {config.building_id_key: {'type': QVariant.String, 'value': id}, 'AREA_ALK': {'type': QVariant.Double, 'value': ar}, 'PERI_ALK': {'type': QVariant.Double, 'value': per}, 'FLRS_ALK': {'type': QVariant.Double, 'value': flr}, 'FUNC_ALK': {'type': QVariant.Double, 'value': usage}, 'KIND_ALK': {'type': QVariant.Double, 'value': kind}, }
def _newDialog(self, cloneFeature): feature = QgsFeature() if (cloneFeature): feature = QgsFeature(self._feature) else: feature = self._feature context = QgsAttributeEditorContext() myDa = QgsDistanceArea() myDa.setSourceCrs(self._layer.crs()) myDa.setEllipsoidalMode(self._iface.mapCanvas().mapSettings().hasCrsTransformEnabled()) myDa.setEllipsoid(QgsProject.instance().readEntry('Measure', '/Ellipsoid', GEO_NONE)[0]) context.setDistanceArea(myDa) context.setVectorLayerTools(self._iface.vectorLayerTools()) dialog = QgsAttributeDialog(self._layer, feature, cloneFeature, None, True, context) if (self._layer.actions().size() > 0): dialog.setContextMenuPolicy(Qt.ActionsContextMenu) a = QAction(self.tr('Run actions'), dialog) a.setEnabled(False) dialog.addAction(a) i = 0 for action in self._layer.actions(): if (action.runable()): a = FeatureAction(action.name(), feature, self._layer, i, -1, self._iface, dialog) dialog.addAction(a) a.triggered.connect(a.execute) pb = dialog.findChild(action.name()) if (pb): pb.clicked.connect(a.execute) i += 1 return dialog
def simpleMeasure( self, inGeom, calcType, ellips, crs ): if inGeom.wkbType() in ( QGis.WKBPoint, QGis.WKBPoint25D ): pt = inGeom.asPoint() attr1 = pt.x() attr2 = pt.y() elif inGeom.wkbType() in ( QGis.WKBMultiPoint, QGis.WKBMultiPoint25D ): pt = inGeom.asMultiPoint() attr1 = pt[ 0 ].x() attr2 = pt[ 0 ].y() else: measure = QgsDistanceArea() if calcType == 2: measure.setSourceCrs( crs ) measure.setEllipsoid( ellips ) measure.setEllipsoidalMode( True ) attr1 = measure.measure( inGeom ) if inGeom.type() == QGis.Polygon: attr2 = self.perimMeasure( inGeom, measure ) else: attr2 = attr1 return ( attr1, attr2 )
def setCustomExpression( self ): """ Initialize and show the expression builder dialog """ layer = None if len( self.tblLayers.selectedItems() ) / 3 == 1: # Single layer selected? for item in self.tblLayers.selectedItems(): if item.column() == 1: # It's the layer name item layer = QgsMapLayerRegistry.instance().mapLayer( item.data( Qt.UserRole ) ) if not self.expressionDlg: self.expressionDlg = ExpressionBuilderDialog( self.iface.mainWindow() ) context = QgsExpressionContext() context.appendScope( QgsExpressionContextUtils.globalScope() ) context.appendScope( QgsExpressionContextUtils.projectScope() ) # Initialize dialog with layer-based names and variables if single layer selected if len( self.tblLayers.selectedItems() ) / 3 == 1: context.appendScope( QgsExpressionContextUtils.layerScope( layer ) ) self.expressionDlg.expressionBuilderWidget.setLayer( layer ) self.expressionDlg.expressionBuilderWidget.loadFieldNames() # This block was borrowed from QGIS/python/plugins/processing/algs/qgis/FieldsCalculator.py da = QgsDistanceArea() da.setSourceCrs( layer.crs().srsid() ) da.setEllipsoidalMode( self.iface.mapCanvas().mapSettings().hasCrsTransformEnabled() ) da.setEllipsoid( QgsProject.instance().readEntry( 'Measure', '/Ellipsoid', GEO_NONE )[0] ) self.expressionDlg.expressionBuilderWidget.setGeomCalculator( da ) # If this layer-field is an AutoField, get its expression if self.optExistingField.isChecked(): fieldName = self.cboField.currentText() expression = self.autoFieldManager.getFieldExpression( layer, fieldName ) self.expressionDlg.expressionBuilderWidget.setExpressionText( expression ) self.expressionDlg.expression = expression # To remember it when closing/opening self.expressionDlg.expressionBuilderWidget.setExpressionContext( context ) self.expressionDlg.show()
def processAlgorithm(self, progress): layer = dataobjects.getObjectFromUri(self.getParameterValue(self.INPUT_LAYER)) fieldName = self.getParameterValue(self.FIELD_NAME) fieldType = self.TYPES[self.getParameterValue(self.FIELD_TYPE)] width = self.getParameterValue(self.FIELD_LENGTH) precision = self.getParameterValue(self.FIELD_PRECISION) newField = self.getParameterValue(self.NEW_FIELD) formula = self.getParameterValue(self.FORMULA) output = self.getOutputFromName(self.OUTPUT_LAYER) fields = layer.fields() if newField: fields.append(QgsField(fieldName, fieldType, '', width, precision)) writer = output.getVectorWriter(fields, layer.wkbType(), layer.crs()) exp = QgsExpression(formula) da = QgsDistanceArea() da.setSourceCrs(layer.crs().srsid()) da.setEllipsoidalMode( iface.mapCanvas().mapSettings().hasCrsTransformEnabled()) da.setEllipsoid(QgsProject.instance().readEntry( 'Measure', '/Ellipsoid', GEO_NONE)[0]) exp.setGeomCalculator(da) exp.setDistanceUnits(QgsProject.instance().distanceUnits()) exp.setAreaUnits(QgsProject.instance().areaUnits()) exp_context = QgsExpressionContext() exp_context.appendScope(QgsExpressionContextUtils.globalScope()) exp_context.appendScope(QgsExpressionContextUtils.projectScope()) exp_context.appendScope(QgsExpressionContextUtils.layerScope(layer)) if not exp.prepare(exp_context): raise GeoAlgorithmExecutionException( self.tr('Evaluation error: %s' % exp.evalErrorString())) outFeature = QgsFeature() outFeature.initAttributes(len(fields)) outFeature.setFields(fields) error = '' calculationSuccess = True features = vector.features(layer) total = 100.0 / len(features) rownum = 1 for current, f in enumerate(features): rownum = current + 1 exp_context.setFeature(f) exp_context.lastScope().setVariable("row_number", rownum) value = exp.evaluate(exp_context) if exp.hasEvalError(): calculationSuccess = False error = exp.evalErrorString() break else: outFeature.setGeometry(f.geometry()) for fld in f.fields(): outFeature[fld.name()] = f[fld.name()] outFeature[fieldName] = value writer.addFeature(outFeature) progress.setPercentage(int(current * total)) del writer if not calculationSuccess: raise GeoAlgorithmExecutionException( self.tr('An error occurred while evaluating the calculation ' 'string:\n%s' % error))
def linearMatrix(self, parameters, context, source, inField, target_source, targetField, same_source_and_target, matType, nPoints, feedback): if same_source_and_target: # need to fetch an extra point from the index, since the closest match will always be the same # as the input feature nPoints += 1 inIdx = source.fields().lookupField(inField) outIdx = target_source.fields().lookupField(targetField) fields = QgsFields() input_id_field = source.fields()[inIdx] input_id_field.setName('InputID') fields.append(input_id_field) if matType == 0: target_id_field = target_source.fields()[outIdx] target_id_field.setName('TargetID') fields.append(target_id_field) fields.append(QgsField('Distance', QVariant.Double)) else: fields.append(QgsField('MEAN', QVariant.Double)) fields.append(QgsField('STDDEV', QVariant.Double)) fields.append(QgsField('MIN', QVariant.Double)) fields.append(QgsField('MAX', QVariant.Double)) out_wkb = QgsWkbTypes.multiType(source.wkbType()) if matType == 0 else source.wkbType() (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, out_wkb, source.sourceCrs()) if sink is None: raise QgsProcessingException(self.invalidSinkError(parameters, self.OUTPUT)) index = QgsSpatialIndex(target_source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes([]).setDestinationCrs(source.sourceCrs(), context.transformContext())), feedback) distArea = QgsDistanceArea() distArea.setSourceCrs(source.sourceCrs(), context.transformContext()) distArea.setEllipsoid(context.project().ellipsoid()) features = source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes([inIdx])) total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, inFeat in enumerate(features): if feedback.isCanceled(): break inGeom = inFeat.geometry() inID = str(inFeat.attributes()[inIdx]) featList = index.nearestNeighbor(inGeom.asPoint(), nPoints) distList = [] vari = 0.0 request = QgsFeatureRequest().setFilterFids(featList).setSubsetOfAttributes([outIdx]).setDestinationCrs(source.sourceCrs(), context.transformContext()) for outFeat in target_source.getFeatures(request): if feedback.isCanceled(): break if same_source_and_target and inFeat.id() == outFeat.id(): continue outID = outFeat.attributes()[outIdx] outGeom = outFeat.geometry() dist = distArea.measureLine(inGeom.asPoint(), outGeom.asPoint()) if matType == 0: out_feature = QgsFeature() out_geom = QgsGeometry.unaryUnion([inFeat.geometry(), outFeat.geometry()]) out_feature.setGeometry(out_geom) out_feature.setAttributes([inID, outID, dist]) sink.addFeature(out_feature, QgsFeatureSink.FastInsert) else: distList.append(float(dist)) if matType != 0: mean = sum(distList) / len(distList) for i in distList: vari += (i - mean) * (i - mean) vari = math.sqrt(vari / len(distList)) out_feature = QgsFeature() out_feature.setGeometry(inFeat.geometry()) out_feature.setAttributes([inID, mean, vari, min(distList), max(distList)]) sink.addFeature(out_feature, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def processAlgorithm(self, feedback): layer = dataobjects.getObjectFromUri( self.getParameterValue(self.INPUT_LAYER)) fieldName = self.getParameterValue(self.FIELD_NAME) fieldType = self.TYPES[self.getParameterValue(self.FIELD_TYPE)] width = self.getParameterValue(self.FIELD_LENGTH) precision = self.getParameterValue(self.FIELD_PRECISION) newField = self.getParameterValue(self.NEW_FIELD) formula = self.getParameterValue(self.FORMULA) output = self.getOutputFromName(self.OUTPUT_LAYER) fields = layer.fields() if newField: fields.append(QgsField(fieldName, fieldType, '', width, precision)) writer = output.getVectorWriter(fields, layer.wkbType(), layer.crs()) exp = QgsExpression(formula) da = QgsDistanceArea() da.setSourceCrs(layer.crs()) da.setEllipsoidalMode(True) da.setEllipsoid(QgsProject.instance().readEntry( 'Measure', '/Ellipsoid', GEO_NONE)[0]) exp.setGeomCalculator(da) exp.setDistanceUnits(QgsProject.instance().distanceUnits()) exp.setAreaUnits(QgsProject.instance().areaUnits()) exp_context = QgsExpressionContext( QgsExpressionContextUtils.globalProjectLayerScopes(layer)) if not exp.prepare(exp_context): raise GeoAlgorithmExecutionException( self.tr('Evaluation error: {0}').format(exp.evalErrorString())) outFeature = QgsFeature() outFeature.initAttributes(len(fields)) outFeature.setFields(fields) error = '' calculationSuccess = True features = vector.features(layer) total = 100.0 / len(features) rownum = 1 for current, f in enumerate(features): rownum = current + 1 exp_context.setFeature(f) exp_context.lastScope().setVariable("row_number", rownum) value = exp.evaluate(exp_context) if exp.hasEvalError(): calculationSuccess = False error = exp.evalErrorString() break else: outFeature.setGeometry(f.geometry()) for fld in f.fields(): outFeature[fld.name()] = f[fld.name()] outFeature[fieldName] = value writer.addFeature(outFeature) feedback.setProgress(int(current * total)) del writer if not calculationSuccess: raise GeoAlgorithmExecutionException( self.tr('An error occurred while evaluating the calculation ' 'string:\n{0}').format(error))
class PositionMarker(QgsMapCanvasItem): ''' MapCanvasItem for showing the MobileItem on the MapCanvas Can have different appearences, fixed ones like corss, x or box or a userdefined shape. Can display also a label on the canvas ''' MIN_SIZE = 30 CIRLCE_SIZE = 30 def __init__(self, canvas, params={}): ''' Constructor :param iface: An interface instance that will be passed to this class which provides the hook by which you can manipulate the QGIS application at run time. :type iface: QgsInterface :param params: A dictionary defining all the properties of the position marker :type params: dictionary ''' self.canvas = canvas self.type = params.get('type', 'BOX').upper() self.size = int(params.get('size', 16)) self.showLabel = bool(params.get('showLabel', True)) s = (self.size - 1) / 2 self.length = float(params.get('length', 98.0)) self.width = float(params.get('width', 17.0)) self.offsetX = float(params.get('offsetX', 0.0)) self.offsetY = float(params.get('offsetY', 0.0)) self.shape = params.get('shape', ((0.0, -0.5), (0.5, -0.3), (0.5, 0.5), (-0.5, 0.50), (-0.5, -0.3))) self.paintShape = QPolygonF( [QPointF(-s, -s), QPointF(s, -s), QPointF(s, s), QPointF(-s, s)]) self.color = self.getColor(params.get('color', 'black')) self.fillColor = self.getColor(params.get('fillColor', 'lime')) self.defaultIcon = bool(params.get('defaultIcon', True)) self.defaultIconFilled = bool(params.get('defaultIconFilled', False)) self.paintCircle = False self.penWidth = int(params.get('penWidth', 1)) spw = s + self.penWidth + 1 self.bounding = QRectF(-spw, -spw, spw * 2, spw * 2) if self.type in ('CROSS', 'X'): self.penWidth = 5 self.trackLen = int(params.get('trackLength', 100)) self.trackColor = self.getColor( params.get('trackColor', self.fillColor)) self.track = deque() self.position = None self.heading = 0 self.northAlign = 0.0 super(PositionMarker, self).__init__(canvas) self.setZValue(int(params.get('zValue', 100))) self.distArea = QgsDistanceArea() self.distArea.setEllipsoid(u'WGS84') if self.showLabel: self.label = MarkerLabel(self.canvas, params) self.label.setZValue(self.zValue() + 0.1) self.updateSize() def properties(self): return { 'type': self.type, 'size': self.size, 'length': self.length, 'width': self.width, 'defaultIcon': self.defaultIcon, 'defaultIconFilled': self.defaultIconFilled, 'offsetX': self.offsetX, 'offsetY': self.offsetY, 'shape': self.shape, 'color': self.color.rgba(), 'fillColor': self.fillColor.rgba(), 'penWidth': self.penWidth, 'trackLength': self.trackLen, 'trackColor': self.trackColor.rgba(), 'zValue': self.zValue(), 'showLabel': self.showLabel } def setMapPosition(self, pos): if self.position != pos: self.updateTrack() self.position = pos self.setPos(self.toCanvasCoordinates(self.position)) if self.showLabel: self.label.setMapPosition(pos) self.update() def newHeading(self, heading): if self.heading != heading: self.heading = heading self.setRotation(self.canvas.rotation() + self.heading - self.northAlign) self.update() def resetPosition(self): self.position = None if self.showLabel: self.label.resetPosition() def updatePosition(self): if self.position: self.prepareGeometryChange() self.updateSize() self.setPos(self.toCanvasCoordinates(self.position)) self.setRotation(self.canvas.rotation() + self.heading - self.northAlign) def updateMapMagnification(self): self.updatePosition() if self.showLabel: self.label.updatePosition() for tp in self.track: tp[0].updatePosition() def updateSize(self): if self.type != 'SHAPE': return s = self.canvas.mapSettings() self.distArea.setSourceCrs(s.destinationCrs(), QgsProject.instance().transformContext()) try: if self.position: p1 = self.position p = self.toCanvasCoordinates(self.position) p2 = self.toMapCoordinates(QPoint(p.x(), p.y() + 100.0)) else: p = self.canvas.viewport().rect().center() p1 = self.toMapCoordinates(p) p2 = self.toMapCoordinates(QPoint(p.x(), p.y() + 100)) lngth = self.distArea.measureLine(p1, p2) f = 100.0 / lngth self.northAlign = fmod( self.distArea.bearing(p2, p1) * 180.0 / pi + self.canvas.rotation(), 360.0) except Exception: f = s.outputDpi() / 0.0254 / s.scale() paintLength = max(self.length * f, self.MIN_SIZE) paintWidth = paintLength * self.width / self.length offsY = self.offsetX / self.length * paintLength offsX = self.offsetY / self.width * paintWidth self.paintShape.clear() if (self.length * f) < self.MIN_SIZE and self.defaultIcon: self.paintCircle = True self.bounding = QRectF(-self.CIRLCE_SIZE * 0.5, -self.CIRLCE_SIZE - 2, self.CIRLCE_SIZE, self.CIRLCE_SIZE * 1.5) else: self.paintCircle = False for v in self.shape: self.paintShape << QPointF(v[0] * paintWidth - offsX, v[1] * paintLength + offsY) self.bounding = self.paintShape.boundingRect() self.size = max(paintLength, paintWidth) def newTrackPoint(self, pos): tp = QgsVertexMarker(self.canvas) tp.setCenter(pos) tp.setIconType(QgsVertexMarker.ICON_CROSS) tp.setColor(self.trackColor) tp.setZValue(self.zValue() - 0.1) tp.setIconSize(3) tp.setPenWidth(3) return tp def updateTrack(self): if self.position and self.trackLen: if len(self.track) >= self.trackLen: tpr = self.track.popleft() self.canvas.scene().removeItem(tpr[0]) del (tpr) tp = self.newTrackPoint(self.position) self.track.append((tp, self.position)) def setVisible(self, visible): for tp in self.track: tp[0].setVisible(visible) QgsMapCanvasItem.setVisible(self, visible) if self.showLabel: self.label.setVisible(visible) def deleteTrack(self): for tp in self.track: self.canvas.scene().removeItem(tp[0]) self.track.clear() def setTrack(self, track): self.track.clear() for tp in track: tpn = self.newTrackPoint(tp) self.track.append((tpn, tp)) def paint(self, painter, xxx, xxx2): if not self.position: return s = (self.size - 1) / 2 pen = QPen(self.color) pen.setWidth(self.penWidth) painter.setPen(pen) painter.setRenderHint(QPainter.Antialiasing, True) if self.type == 'CROSS': painter.drawLine(QLineF(-s, 0, s, 0)) painter.drawLine(QLineF(0, -s, 0, s)) elif self.type == 'X': painter.drawLine(QLineF(-s, -s, s, s)) painter.drawLine(QLineF(-s, s, s, -s)) elif self.type == 'BOX': brush = QBrush(self.fillColor) painter.setBrush(brush) painter.drawConvexPolygon(self.paintShape) elif self.type == 'SHAPE': if self.paintCircle: pen.setWidth(self.penWidth * 2) if self.defaultIconFilled: brush = QBrush(self.fillColor) painter.setBrush(brush) painter.setPen(pen) painter.drawEllipse(QPointF(0, 0), self.CIRLCE_SIZE * 0.4, self.CIRLCE_SIZE * 0.4) painter.drawLine( QLineF(0, -self.CIRLCE_SIZE * 0.4, 0, -self.CIRLCE_SIZE)) else: brush = QBrush(self.fillColor) painter.setBrush(brush) painter.drawConvexPolygon(self.paintShape) def boundingRect(self): return self.bounding def getColor(self, value): try: return QColor.fromRgba(int(value)) except ValueError: return QColor(value) def removeFromCanvas(self): self.deleteTrack() if self.showLabel: self.canvas.scene().removeItem(self.label) self.canvas.scene().removeItem(self)
def processAlgorithm(self, parameters, context, progress): vlayer = self.parameterAsVectorLayer(parameters, self.Points, context) SelectedFeaturesOnly = self.parameterAsBool(parameters, self.SelectedFeaturesOnly, context) Cluster_Type = self.parameterAsEnum(parameters, self.Cluster_Type, context) RandomSeed = self.parameterAsInt(parameters, self.RandomSeed, context) Linkage = self.parameterAsEnum(parameters, self.Linkage, context) Distance_Type = self.parameterAsEnum(parameters, self.Distance_Type, context) NumberOfClusters = self.parameterAsInt(parameters, self.NumberOfClusters, context) random.seed(RandomSeed) provider = vlayer.dataProvider() if provider.featureCount() < NumberOfClusters: raise GeoAlgorithmExecutionException( "Error initializing cluster analysis:\nToo little features available" ) sRs = provider.crs() d = QgsDistanceArea() d.setSourceCrs(sRs, context.transformContext()) d.setEllipsoid(context.project().ellipsoid()) # retrieve input features infeat = QgsFeature() if SelectedFeaturesOnly: fit = vlayer.getSelectedFeatures() else: fit = provider.getFeatures() # initialize points for clustering points = {} key = 0 while fit.nextFeature(infeat): points[key] = infeat.geometry().asPoint() key += 1 if NumberOfClusters > key: raise GeoAlgorithmExecutionException( "Too little points available for %i clusters") % ( NumberOfClusters) # do the clustering if Cluster_Type == 0: if Linkage != 0: progress.pushInfo(self.tr("Linkage not used for K-Means")) # K-means clustering clusters = self.kmeans(progress, points, NumberOfClusters, d, 10 * float_info.epsilon, Distance_Type == 1) del points cluster_id = {} for idx, cluster in enumerate(clusters): for key in cluster.ids: cluster_id[key] = idx else: # Hierarchical clustering if Linkage == 0: clusters = self.hcluster_wards(progress, points, NumberOfClusters, d, Distance_Type == 1) elif Linkage == 1: clusters = self.hcluster_single(progress, points, NumberOfClusters, d, Distance_Type == 1) elif Linkage == 2: clusters = self.hcluster_complete(progress, points, NumberOfClusters, d, Distance_Type == 1) elif Linkage == 3: clusters = self.hcluster_average(progress, points, NumberOfClusters, d, Distance_Type == 1) else: raise GeoAlgorithmExecutionException( "Linkage must be Ward's, Single, Complete or Average") del points cluster_id = {} for idx, cluster in enumerate(clusters): for key in cluster: cluster_id[key] = idx # write results to input file progress.pushInfo(self.tr("Writing output field Cluster_ID")) if not vlayer.isEditable(): vlayer.startEditing() fieldList = provider.fields() if "Cluster_ID" in [field.name() for field in fieldList]: icl = fieldList.indexFromName("Cluster_ID") provider.deleteAttributes([icl]) provider.addAttributes([QgsField("Cluster_ID", QVariant.Int)]) vlayer.updateFields() # assign the output points to the clusters if SelectedFeaturesOnly: fit = vlayer.getSelectedFeatures() else: fit = provider.getFeatures() key = 0 while fit.nextFeature(infeat): atMap = infeat.attributes() atMap[-1] = cluster_id[key] infeat.setAttributes(atMap) vlayer.updateFeature(infeat) key += 1 vlayer.commitChanges() progress.setProgress(100) return {self.Points: "Cluster_ID"}
class MeasureDistanceTool(QgsMapTool): finished = pyqtSignal() def __init__(self, canvas, msglog): super().__init__(canvas) self.canvas = canvas self.msglog = msglog self.start_point = self.end_point = None self.rubber_band = QgsRubberBand(self.canvas, QgsWkbTypes.LineGeometry) self.rubber_band.setColor(QColor(255, 0, 0, 100)) self.rubber_band.setWidth(3) self.rubber_band_points = QgsRubberBand(self.canvas, QgsWkbTypes.PointGeometry) self.rubber_band_points.setIcon(QgsRubberBand.ICON_CIRCLE) self.rubber_band_points.setIconSize(10) self.rubber_band_points.setColor(QColor(255, 0, 0, 150)) crs = self.canvas.mapSettings().destinationCrs() self.distance_calc = QgsDistanceArea() self.distance_calc.setSourceCrs( crs, QgsProject.instance().transformContext()) self.distance_calc.setEllipsoid(crs.ellipsoidAcronym()) self.reset() def reset(self): self.msglog.logMessage("") self.start_point = self.end_point = None self.rubber_band.reset(QgsWkbTypes.LineGeometry) self.rubber_band_points.reset(QgsWkbTypes.PointGeometry) def canvasPressEvent(self, event): pass def canvasReleaseEvent(self, event): transform = self.canvas.getCoordinateTransform() point = transform.toMapCoordinates(event.pos().x(), event.pos().y()) if self.start_point: self.end_point = point self.rubber_band.addPoint(self.end_point) self.rubber_band_points.addPoint(self.end_point) distance = self.distance_calc.measureLine( [self.start_point, self.end_point]) bearing = self.distance_calc.bearing(self.start_point, point) distancemsg = QMessageBox(self.parent()) distancemsg.finished.connect(self.deactivate) distancemsg.setWindowTitle("Measure tool") distancemsg.setText("Distance: {:.3F} m. Bearing: {:.3F} º".format( distance, degrees(bearing))) distancemsg.exec() self.finish() else: self.start_point = point self.rubber_band.addPoint(self.start_point) self.rubber_band_points.addPoint(self.start_point) def canvasMoveEvent(self, e): if self.start_point and not self.end_point: transform = self.canvas.getCoordinateTransform() point = transform.toMapCoordinates(e.pos().x(), e.pos().y()) self.rubber_band.movePoint(point) distance = self.distance_calc.measureLine( [self.start_point, point]) bearing = self.distance_calc.bearing(self.start_point, point) self.msglog.logMessage("") self.msglog.logMessage( "Current distance: {:.3F} m. Bearing: {:.3F} º".format( distance, degrees(bearing)), "Measure distance:", 0) def keyPressEvent(self, event): """ When escape key is pressed, line is restarted """ if event.key() == Qt.Key_Escape: self.reset() def finish(self): self.reset() self.finished.emit()
class GuidanceDock(QDockWidget, FORM_CLASS): ''' classdocs ''' def __init__(self, parent=None): ''' Constructor ''' super(GuidanceDock, self).__init__(parent) self.setupUi(self) self.setStyleSheet("QLabel { padding-left: 5px; padding-right: 5px; }") self.compass = CompassWidget() self.compass.setMinimumHeight(80) self.verticalLayout.addWidget(self.compass) self.verticalLayout.setStretch(5, 8) self.distArea = QgsDistanceArea() self.distArea.setEllipsoid(u'WGS84') self.distArea.setSourceCrs(QgsCoordinateReferenceSystem('EPSG:4326'), QgsProject.instance().transformContext()) self.fontSize = 11 self.source = None self.target = None self.srcPos = [None, 0.0] self.trgPos = [None, 0.0] self.srcHeading = 0.0 self.trgHeading = 0.0 s = QSettings() self.format = s.value('PosiView/Guidance/Format', defaultValue=1, type=int) self.showUtc = s.value('PosiView/Misc/ShowUtcClock', defaultValue=False, type=bool) self.timer = 0 self.setUtcClock() self.layer = None def setUtcClock(self): if self.showUtc: if not self.timer: self.timer = self.startTimer(1000) self.frameUtcClock.show() else: self.frameUtcClock.hide() self.killTimer(self.timer) self.timer = 0 def setMobiles(self, mobiles): self.reset() self.mobiles = mobiles self.comboBoxSource.blockSignals(True) self.comboBoxTarget.blockSignals(True) mobs = sorted(mobiles.keys()) self.comboBoxSource.clear() self.comboBoxSource.addItems(mobs) self.comboBoxSource.setCurrentIndex(-1) self.comboBoxTarget.clear() self.comboBoxTarget.addItems(mobs) self.comboBoxTarget.setCurrentIndex(-1) self.comboBoxSource.blockSignals(False) self.comboBoxTarget.blockSignals(False) s = QSettings() m = s.value('PosiView/Guidance/Source') if m in self.mobiles: self.comboBoxSource.setCurrentText(m) # Index(self.comboBoxSource.findText(m)) m = s.value('PosiView/Guidance/Target') if m in self.mobiles: self.comboBoxTarget.setCurrentText(m) # Index(self.comboBoxTarget.findText(m)) self.showUtc = s.value('PosiView/Misc/ShowUtcClock', defaultValue=False, type=bool) self.setUtcClock() @pyqtSlot(name='on_pushButtonFormat_clicked') def switchCoordinateFormat(self): self.format = (self.format + 1) % 3 s = QSettings() s.setValue('PosiView/Guidance/Format', self.format) if self.trgPos[0]: lon, lat = self.posToStr(self.trgPos[0]) self.labelTargetLat.setText(lat) self.labelTargetLon.setText(lon) if self.srcPos[0]: lon, lat = self.posToStr(self.srcPos[0]) self.labelSourceLat.setText(lat) self.labelSourceLon.setText(lon) def posToStr(self, pos): if self.format == 0: return "{:.6f}".format(pos.x()), "{:.6f}".format(pos.y()) if self.format == 1: return QgsCoordinateFormatter.format(pos, QgsCoordinateFormatter.FormatDegreesMinutes, 4).split(',') if self.format == 2: return QgsCoordinateFormatter.format(pos, QgsCoordinateFormatter.FormatDegreesMinutesSeconds, 2).split(',') @pyqtSlot(str, name='on_comboBoxSource_currentIndexChanged') def sourceChanged(self, mob): if self.source is not None: try: self.source.newPosition.disconnect(self.onNewSourcePosition) self.source.newAttitude.disconnect(self.onNewSourceAttitude) except TypeError: pass if mob in self.mobiles: try: self.source = self.mobiles[mob] self.source.newPosition.connect(self.onNewSourcePosition) self.source.newAttitude.connect(self.onNewSourceAttitude) s = QSettings() s.setValue('PosiView/Guidance/Source', mob) except KeyError: self.source = None self.resetSource() elif self.layer: for f in self.layer.getFeatures(): if f['name'] == mob[:-2]: pos = f.geometry().asPoint() self.resetSource() self.onNewSourcePosition(None, pos, -9999, -9999) @pyqtSlot(str, name='on_comboBoxTarget_currentIndexChanged') def targetChanged(self, mob): if self.target is not None: try: self.target.newPosition.disconnect(self.onNewTargetPosition) self.target.newAttitude.disconnect(self.onNewTargetAttitude) except TypeError: pass if mob in self.mobiles: try: self.target = self.mobiles[mob] self.target.newPosition.connect(self.onNewTargetPosition) self.target.newAttitude.connect(self.onNewTargetAttitude) s = QSettings() s.setValue('PosiView/Guidance/Target', mob) except KeyError: self.target = None self.resetTarget() elif self.layer: for f in self.layer.getFeatures(): if f['name'] == mob[:-2]: pos = f.geometry().asPoint() self.resetTarget() self.onNewTargetPosition(None, pos, -9999, -9999) @pyqtSlot(float, QgsPointXY, float, float) def onNewSourcePosition(self, fix, pos, depth, altitude): if [pos, depth] != self.srcPos: lon, lat = self.posToStr(pos) self.labelSourceLat.setText(lat) self.labelSourceLon.setText(lon) if depth > -9999: self.labelSourceDepth.setText('{:.1f}'.format(depth)) if self.trgPos[0] is not None: if depth > -9999 and self.trgPos[1] > -9999: self.labelVertDistance.setText('{:.1f}'.format(self.trgPos[1] - depth)) dist = self.distArea.measureLine(self.trgPos[0], pos) self.labelDistance.setText('{:.1f}'.format(dist)) if dist != 0: bearing = self.distArea.bearing(pos, self.trgPos[0]) * 180 / pi if bearing < 0: bearing += 360 else: bearing = 0.0 self.labelDirection.setText('{:.1f}'.format(bearing)) self.srcPos = [pos, depth] @pyqtSlot(float, QgsPointXY, float, float) def onNewTargetPosition(self, fix, pos, depth, altitude): if [pos, depth] != self.trgPos: lon, lat = self.posToStr(pos) self.labelTargetLat.setText(lat) self.labelTargetLon.setText(lon) if depth > -9999: self.labelTargetDepth.setText('{:.1f}'.format(depth)) if self.srcPos[0] is not None: if depth > -9999 and self.srcPos[1] > -9999: self.labelVertDistance.setText('{:.1f}'.format(depth - self.srcPos[1])) dist = self.distArea.measureLine(pos, self.srcPos[0]) self.labelDistance.setText('{:.1f}'.format(dist)) if dist != 0: bearing = self.distArea.bearing(self.srcPos[0], pos) * 180 / pi if bearing < 0: bearing += 360 else: bearing = 0.0 self.labelDirection.setText('{:.1f}'.format(bearing)) self.trgPos = [pos, depth] @pyqtSlot(float, float, float) def onNewTargetAttitude(self, heading, pitch, roll): if self.trgHeading != heading: self.trgHeading = heading self.labelTargetHeading.setText('{:.1f}'.format(heading)) self.compass.setAngle2(heading) @pyqtSlot(float, float, float) def onNewSourceAttitude(self, heading, pitch, roll): if self.srcHeading != heading: self.srcHeading = heading self.labelSourceHeading.setText('{:.1f}'.format(heading)) self.compass.setAngle(heading) @pyqtSlot(QgsMapLayer) def onActiveLayerChanged(self, layer): if self.cleanComboBox(self.comboBoxSource): self.resetSource() if self.cleanComboBox(self.comboBoxTarget): self.resetTarget() self.layer = None if not layer: return if layer.type() == QgsMapLayer.VectorLayer and layer.wkbType() == QgsWkbTypes.Point: if layer.fields().indexOf('name') != -1: self.layer = layer self.comboBoxSource.blockSignals(True) self.comboBoxTarget.blockSignals(True) items = sorted([f['name'] + ' ' for f in layer.getFeatures()]) self.comboBoxSource.addItems(items) self.comboBoxTarget.addItems(items) self.comboBoxSource.blockSignals(False) self.comboBoxTarget.blockSignals(False) def reset(self): try: if self.source is not None: self.source.newPosition.disconnect(self.onNewSourcePosition) self.source.newAttitude.disconnect(self.onNewSourceAttitude) if self.target is not None: self.target.newPosition.disconnect(self.onNewTargetPosition) self.target.newAttitude.disconnect(self.onNewTargetAttitude) except TypeError: pass self.source = None self.target = None self.resetSource() self.resetTarget() self.resetDistBearing() def resetSource(self): self.srcPos = [None, 0.0] self.srcHeading = -9999.0 self.labelSourceLat.setText('---') self.labelSourceLon.setText('---') self.labelSourceHeading.setText('---') self.labelSourceDepth.setText('---') self.compass.reset(1) self.resetDistBearing() def resetTarget(self): self.trgPos = [None, 0.0] self.trgHeading = -9999.0 self.labelTargetLat.setText('---') self.labelTargetLon.setText('---') self.labelTargetHeading.setText('---') self.labelTargetDepth.setText('---') self.compass.reset(2) self.resetDistBearing() def cleanComboBox(self, comboBox): comboBox.blockSignals(True) ct = comboBox.currentText() for _ in range(comboBox.count() - len(self.mobiles)): comboBox.removeItem(len(self.mobiles)) if ct not in self.mobiles: comboBox.setCurrentIndex(-1) res = True else: res = False comboBox.blockSignals(False) return res def resetDistBearing(self): self.labelDirection.setText('---') self.labelDistance.setText('---') self.labelVertDistance.setText('---') def resizeEvent(self, event): fsize = max(8, event.size().width() / 50) if fsize != self.fontSize: self.fontSize = fsize self.dockWidgetContents.setStyleSheet("font-weight: bold; font-size: {}pt;".format(self.fontSize)) return QDockWidget.resizeEvent(self, event) def timerEvent(self, event): dt = QDateTime.currentDateTimeUtc() self.labelTimeUtc.setText(dt.time().toString(u'hh:mm:ss'))
def testMeasureLineProjected(self): # +-+ # | | # +-+ + # test setting/getting the source CRS da_3068 = QgsDistanceArea() da_wsg84 = QgsDistanceArea() da_3068.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:3068'), QgsProject.instance().transformContext()) if (da_3068.sourceCrs().isGeographic()): da_3068.setEllipsoid(da_3068.sourceCrs().ellipsoidAcronym()) print(("setting [{}] srid [{}] description [{}]".format(u'Soldner Berlin', da_3068.sourceCrs().authid(), da_3068.sourceCrs().description()))) self.assertEqual(da_3068.sourceCrs().authid(), 'EPSG:3068') da_wsg84.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:4326'), QgsProject.instance().transformContext()) if (da_wsg84.sourceCrs().isGeographic()): da_wsg84.setEllipsoid(da_wsg84.sourceCrs().ellipsoidAcronym()) self.assertEqual(da_wsg84.sourceCrs().authid(), 'EPSG:4326') print(("setting [{}] srid [{}] description [{}] isGeographic[{}]".format(u'Wsg84', da_wsg84.sourceCrs().authid(), da_wsg84.sourceCrs().description(), da_wsg84.sourceCrs().isGeographic()))) # print(("-- projectionAcronym[{}] ellipsoidAcronym[{}] toWkt[{}] mapUnits[{}] toProj4[{}]".format(da_wsg84.sourceCrs().projectionAcronym(),da_wsg84.sourceCrs().ellipsoidAcronym(), da_wsg84.sourceCrs().toWkt(),da_wsg84.sourceCrs().mapUnits(),da_wsg84.sourceCrs().toProj4()))) print(("Testing Position change for[{}] years[{}]".format(u'Ampelanlage - Potsdamer Platz, Verkehrsinsel', u'1924 and 1998'))) # 1924-10-24 SRID=3068;POINT(23099.49 20296.69) # 1924-10-24 SRID=4326;POINT(13.37650707988041 52.50952361017194) # 1998-10-02 SRID=3068;POINT(23082.30 20267.80) # 1998-10-02 SRID=4326;POINT(13.37625537334001 52.50926345498337) # values returned by SpatiaLite point_soldner_1924 = QgsPointXY(23099.49, 20296.69) point_soldner_1998 = QgsPointXY(23082.30, 20267.80) distance_soldner_meters = 33.617379 azimuth_soldner_1924 = 3.678339 # ST_Transform(point_soldner_1924,point_soldner_1998,4326) point_wsg84_1924 = QgsPointXY(13.37650707988041, 52.50952361017194) point_wsg84_1998 = QgsPointXY(13.37625537334001, 52.50926345498337) # ST_Distance(point_wsg84_1924,point_wsg84_1998,1) distance_wsg84_meters = 33.617302 # ST_Distance(point_wsg84_1924,point_wsg84_1998) # distance_wsg84_mapunits=0.000362 distance_wsg84_mapunits_format = QgsDistanceArea.formatDistance(0.000362, 7, QgsUnitTypes.DistanceDegrees, True) # ST_Azimuth(point_wsg84_1924,point_wsg84_1998) azimuth_wsg84_1924 = 3.674878 # ST_Azimuth(point_wsg84_1998,point_wsg84_1998) azimuth_wsg84_1998 = 0.533282 # ST_Project(point_wsg84_1924,33.617302,3.674878) # SRID=4326;POINT(13.37625537318728 52.50926345503591) point_soldner_1998_project = QgsPointXY(13.37625537318728, 52.50926345503591) # ST_Project(point_wsg84_1998,33.617302,0.533282) # SRID=4326;POINT(13.37650708009255 52.50952361009799) point_soldner_1924_project = QgsPointXY(13.37650708009255, 52.50952361009799) distance_qpoint = point_soldner_1924.distance(point_soldner_1998) azimuth_qpoint = point_soldner_1924.azimuth(point_soldner_1998) point_soldner_1998_result = point_soldner_1924.project(distance_qpoint, azimuth_qpoint) point_soldner_1924_result = QgsPointXY(0, 0) point_soldner_1998_result = QgsPointXY(0, 0) # Test meter based projected point from point_1924 to point_1998 length_1998_mapunits, point_soldner_1998_result = da_3068.measureLineProjected(point_soldner_1924, distance_soldner_meters, azimuth_qpoint) self.assertEqual(point_soldner_1998_result.toString(6), point_soldner_1998.toString(6)) # Test degree based projected point from point_1924 1 meter due East point_wsg84_meter_result = QgsPointXY(0, 0) point_wsg84_1927_meter = QgsPointXY(13.37652180838435, 52.50952361017102) length_meter_mapunits, point_wsg84_meter_result = da_wsg84.measureLineProjected(point_wsg84_1924, 1.0, (math.pi / 2)) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, QgsUnitTypes.DistanceDegrees, True), '0.0000147 deg') self.assertEqual(point_wsg84_meter_result.toString(7), point_wsg84_1927_meter.toString(7)) point_wsg84_1998_result = QgsPointXY(0, 0) length_1928_mapunits, point_wsg84_1998_result = da_wsg84.measureLineProjected(point_wsg84_1924, distance_wsg84_meters, azimuth_wsg84_1924) self.assertEqual(QgsDistanceArea.formatDistance(length_1928_mapunits, 7, QgsUnitTypes.DistanceDegrees, True), distance_wsg84_mapunits_format) self.assertEqual(point_wsg84_1998_result.toString(7), point_wsg84_1998.toString(7))
def processAlgorithm(self, feedback): layerPoints = dataobjects.getObjectFromUri( self.getParameterValue(self.POINTS)) layerHubs = dataobjects.getObjectFromUri( self.getParameterValue(self.HUBS)) fieldName = self.getParameterValue(self.FIELD) addLines = self.getParameterValue(self.GEOMETRY) units = self.UNITS[self.getParameterValue(self.UNIT)] if layerPoints.source() == layerHubs.source(): raise GeoAlgorithmExecutionException( self.tr('Same layer given for both hubs and spokes')) fields = layerPoints.fields() fields.append(QgsField('HubName', QVariant.String)) fields.append(QgsField('HubDist', QVariant.Double)) writer = self.getOutputFromName(self.OUTPUT).getVectorWriter( fields, QgsWkbTypes.Point, layerPoints.crs()) index = vector.spatialindex(layerHubs) distance = QgsDistanceArea() distance.setSourceCrs(layerPoints.crs().srsid()) distance.setEllipsoidalMode(True) # Scan source points, find nearest hub, and write to output file features = vector.features(layerPoints) total = 100.0 / len(features) for current, f in enumerate(features): src = f.geometry().boundingBox().center() neighbors = index.nearestNeighbor(src, 1) ft = next( layerHubs.getFeatures(QgsFeatureRequest().setFilterFid( neighbors[0]).setSubsetOfAttributes([fieldName], layerHubs.fields()))) closest = ft.geometry().boundingBox().center() hubDist = distance.measureLine(src, closest) attributes = f.attributes() attributes.append(ft[fieldName]) if units == 'Feet': attributes.append(hubDist * 3.2808399) elif units == 'Miles': attributes.append(hubDist * 0.000621371192) elif units == 'Kilometers': attributes.append(hubDist / 1000.0) elif units != 'Meters': attributes.append( sqrt( pow(src.x() - closest.x(), 2.0) + pow(src.y() - closest.y(), 2.0))) else: attributes.append(hubDist) feat = QgsFeature() feat.setAttributes(attributes) feat.setGeometry(QgsGeometry.fromPoint(src)) writer.addFeature(feat) feedback.setProgress(int(current * total)) del writer
def processAlgorithm(self, parameters, context, feedback): if parameters[self.INPUT] == parameters[self.HUBS]: raise QgsProcessingException( self.tr('Same layer given for both hubs and spokes')) point_source = self.parameterAsSource(parameters, self.INPUT, context) hub_source = self.parameterAsSource(parameters, self.HUBS, context) fieldName = self.parameterAsString(parameters, self.FIELD, context) units = self.UNITS[self.parameterAsEnum(parameters, self.UNIT, context)] fields = point_source.fields() fields.append(QgsField('HubName', QVariant.String)) fields.append(QgsField('HubDist', QVariant.Double)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, QgsWkbTypes.LineString, point_source.sourceCrs()) index = QgsSpatialIndex( hub_source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes( []).setDestinationCrs(point_source.sourceCrs()))) distance = QgsDistanceArea() distance.setSourceCrs(point_source.sourceCrs()) distance.setEllipsoid(context.project().ellipsoid()) # Scan source points, find nearest hub, and write to output file features = point_source.getFeatures() total = 100.0 / point_source.featureCount( ) if point_source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break if not f.hasGeometry(): sink.addFeature(f, QgsFeatureSink.FastInsert) continue src = f.geometry().boundingBox().center() neighbors = index.nearestNeighbor(src, 1) ft = next( hub_source.getFeatures(QgsFeatureRequest().setFilterFid( neighbors[0]).setSubsetOfAttributes( [fieldName], hub_source.fields()).setDestinationCrs( point_source.sourceCrs()))) closest = ft.geometry().boundingBox().center() hubDist = distance.measureLine(src, closest) if units != self.LAYER_UNITS: hub_dist_in_desired_units = distance.convertLengthMeasurement( hubDist, units) else: hub_dist_in_desired_units = hubDist attributes = f.attributes() attributes.append(ft[fieldName]) attributes.append(hub_dist_in_desired_units) feat = QgsFeature() feat.setAttributes(attributes) feat.setGeometry(QgsGeometry.fromPolylineXY([src, closest])) sink.addFeature(feat, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) group_field_name = self.parameterAsString(parameters, self.GROUP_FIELD, context) order_field_name = self.parameterAsString(parameters, self.ORDER_FIELD, context) date_format = self.parameterAsString(parameters, self.DATE_FORMAT, context) text_dir = self.parameterAsString(parameters, self.OUTPUT_TEXT_DIR, context) group_field_index = source.fields().lookupField(group_field_name) order_field_index = source.fields().lookupField(order_field_name) if group_field_index >= 0: group_field_def = source.fields().at(group_field_index) else: group_field_def = None order_field_def = source.fields().at(order_field_index) fields = QgsFields() if group_field_def is not None: fields.append(group_field_def) begin_field = QgsField(order_field_def) begin_field.setName('begin') fields.append(begin_field) end_field = QgsField(order_field_def) end_field.setName('end') fields.append(end_field) output_wkb = QgsWkbTypes.LineString if QgsWkbTypes.hasM(source.wkbType()): output_wkb = QgsWkbTypes.addM(output_wkb) if QgsWkbTypes.hasZ(source.wkbType()): output_wkb = QgsWkbTypes.addZ(output_wkb) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, output_wkb, source.sourceCrs()) points = dict() features = source.getFeatures( QgsFeatureRequest().setSubsetOfAttributes( [group_field_index, order_field_index])) total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break if not f.hasGeometry(): continue point = f.geometry().constGet().clone() if group_field_index >= 0: group = f.attributes()[group_field_index] else: group = 1 order = f.attributes()[order_field_index] if date_format != '': order = datetime.strptime(str(order), date_format) if group in points: points[group].append((order, point)) else: points[group] = [(order, point)] feedback.setProgress(int(current * total)) feedback.setProgress(0) da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) current = 0 total = 100.0 / len(points) if points else 1 for group, vertices in list(points.items()): if feedback.isCanceled(): break vertices.sort() f = QgsFeature() attributes = [] if group_field_index >= 0: attributes.append(group) attributes.extend([vertices[0][0], vertices[-1][0]]) f.setAttributes(attributes) line = [node[1] for node in vertices] if text_dir: fileName = os.path.join(text_dir, '%s.txt' % group) with open(fileName, 'w') as fl: fl.write('angle=Azimuth\n') fl.write('heading=Coordinate_System\n') fl.write('dist_units=Default\n') for i in range(len(line)): if i == 0: fl.write('startAt=%f;%f;90\n' % (line[i].x(), line[i].y())) fl.write('survey=Polygonal\n') fl.write('[data]\n') else: angle = line[i - 1].azimuth(line[i]) distance = da.measureLine(QgsPointXY(line[i - 1]), QgsPointXY(line[i])) fl.write('%f;%f;90\n' % (angle, distance)) f.setGeometry(QgsGeometry(QgsLineString(line))) sink.addFeature(f, QgsFeatureSink.FastInsert) current += 1 feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def linearMatrix(self, parameters, context, source, inField, target_source, targetField, matType, nPoints, feedback): inIdx = source.fields().lookupField(inField) outIdx = target_source.fields().lookupField(targetField) fields = QgsFields() input_id_field = source.fields()[inIdx] input_id_field.setName('InputID') fields.append(input_id_field) if matType == 0: target_id_field = target_source.fields()[outIdx] target_id_field.setName('TargetID') fields.append(target_id_field) fields.append(QgsField('Distance', QVariant.Double)) else: fields.append(QgsField('MEAN', QVariant.Double)) fields.append(QgsField('STDDEV', QVariant.Double)) fields.append(QgsField('MIN', QVariant.Double)) fields.append(QgsField('MAX', QVariant.Double)) out_wkb = QgsWkbTypes.multiType( source.wkbType()) if matType == 0 else source.wkbType() (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, out_wkb, source.sourceCrs()) index = QgsSpatialIndex( target_source.getFeatures( QgsFeatureRequest().setSubsetOfAttributes( []).setDestinationCrs(source.sourceCrs())), feedback) distArea = QgsDistanceArea() distArea.setSourceCrs(source.sourceCrs()) distArea.setEllipsoid(context.project().ellipsoid()) features = source.getFeatures( QgsFeatureRequest().setSubsetOfAttributes([inIdx])) total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, inFeat in enumerate(features): if feedback.isCanceled(): break inGeom = inFeat.geometry() inID = str(inFeat.attributes()[inIdx]) featList = index.nearestNeighbor(inGeom.asPoint(), nPoints) distList = [] vari = 0.0 request = QgsFeatureRequest().setFilterFids( featList).setSubsetOfAttributes([outIdx]).setDestinationCrs( source.sourceCrs()) for outFeat in target_source.getFeatures(request): if feedback.isCanceled(): break outID = outFeat.attributes()[outIdx] outGeom = outFeat.geometry() dist = distArea.measureLine(inGeom.asPoint(), outGeom.asPoint()) if matType == 0: out_feature = QgsFeature() out_geom = QgsGeometry.unaryUnion( [inFeat.geometry(), outFeat.geometry()]) out_feature.setGeometry(out_geom) out_feature.setAttributes([inID, outID, dist]) sink.addFeature(out_feature, QgsFeatureSink.FastInsert) else: distList.append(float(dist)) if matType != 0: mean = sum(distList) / len(distList) for i in distList: vari += (i - mean) * (i - mean) vari = math.sqrt(vari / len(distList)) out_feature = QgsFeature() out_feature.setGeometry(inFeat.geometry()) out_feature.setAttributes( [inID, mean, vari, min(distList), max(distList)]) sink.addFeature(out_feature, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException( self.invalidSourceError(parameters, self.INPUT)) strategy = self.parameterAsEnum(parameters, self.STRATEGY, context) minDistance = self.parameterAsDouble(parameters, self.MIN_DISTANCE, context) expression = QgsExpression( self.parameterAsString(parameters, self.EXPRESSION, context)) if expression.hasParserError(): raise QgsProcessingException(expression.parserErrorString()) expressionContext = self.createExpressionContext( parameters, context, source) expression.prepare(expressionContext) fields = QgsFields() fields.append(QgsField('id', QVariant.Int, '', 10, 0)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, QgsWkbTypes.Point, source.sourceCrs()) if sink is None: raise QgsProcessingException( self.invalidSinkError(parameters, self.OUTPUT)) da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) total = 100.0 / source.featureCount() if source.featureCount() else 0 current_progress = 0 for current, f in enumerate(source.getFeatures()): if feedback.isCanceled(): break if not f.hasGeometry(): continue current_progress = total * current feedback.setProgress(current_progress) expressionContext.setFeature(f) value = expression.evaluate(expressionContext) if expression.hasEvalError(): feedback.pushInfo( self.tr('Evaluation error for feature ID {}: {}').format( f.id(), expression.evalErrorString())) continue fGeom = f.geometry() engine = QgsGeometry.createGeometryEngine(fGeom.constGet()) engine.prepareGeometry() bbox = fGeom.boundingBox() if strategy == 0: pointCount = int(value) else: pointCount = int(round(value * da.measureArea(fGeom))) if pointCount == 0: feedback.pushInfo( "Skip feature {} as number of points for it is 0.".format( f.id())) continue index = QgsSpatialIndex() points = dict() nPoints = 0 nIterations = 0 maxIterations = pointCount * 200 feature_total = total / pointCount if pointCount else 1 random.seed() while nIterations < maxIterations and nPoints < pointCount: if feedback.isCanceled(): break rx = bbox.xMinimum() + bbox.width() * random.random() ry = bbox.yMinimum() + bbox.height() * random.random() p = QgsPointXY(rx, ry) geom = QgsGeometry.fromPointXY(p) if engine.contains(geom.constGet()) and \ vector.checkMinDistance(p, index, minDistance, points): f = QgsFeature(nPoints) f.initAttributes(1) f.setFields(fields) f.setAttribute('id', nPoints) f.setGeometry(geom) sink.addFeature(f, QgsFeatureSink.FastInsert) index.insertFeature(f) points[nPoints] = p nPoints += 1 feedback.setProgress(current_progress + int(nPoints * feature_total)) nIterations += 1 if nPoints < pointCount: feedback.pushInfo( self.tr('Could not generate requested number of random ' 'points. Maximum number of attempts exceeded.')) feedback.setProgress(100) return {self.OUTPUT: dest_id}
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException(self.invalidSourceError(parameters, self.INPUT)) strategy = self.parameterAsEnum(parameters, self.STRATEGY, context) minDistance = self.parameterAsDouble(parameters, self.MIN_DISTANCE, context) expression = QgsExpression(self.parameterAsString(parameters, self.EXPRESSION, context)) if expression.hasParserError(): raise QgsProcessingException(expression.parserErrorString()) expressionContext = self.createExpressionContext(parameters, context, source) expression.prepare(expressionContext) fields = QgsFields() fields.append(QgsField('id', QVariant.Int, '', 10, 0)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, QgsWkbTypes.Point, source.sourceCrs(), QgsFeatureSink.RegeneratePrimaryKey) if sink is None: raise QgsProcessingException(self.invalidSinkError(parameters, self.OUTPUT)) da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) total = 100.0 / source.featureCount() if source.featureCount() else 0 current_progress = 0 for current, f in enumerate(source.getFeatures()): if feedback.isCanceled(): break if not f.hasGeometry(): continue current_progress = total * current feedback.setProgress(current_progress) expressionContext.setFeature(f) value = expression.evaluate(expressionContext) if expression.hasEvalError(): feedback.pushInfo( self.tr('Evaluation error for feature ID {}: {}').format(f.id(), expression.evalErrorString())) continue fGeom = f.geometry() engine = QgsGeometry.createGeometryEngine(fGeom.constGet()) engine.prepareGeometry() bbox = fGeom.boundingBox() if strategy == 0: pointCount = int(value) else: pointCount = int(round(value * da.measureArea(fGeom))) if pointCount == 0: feedback.pushInfo("Skip feature {} as number of points for it is 0.".format(f.id())) continue index = QgsSpatialIndex() points = dict() nPoints = 0 nIterations = 0 maxIterations = pointCount * 200 feature_total = total / pointCount if pointCount else 1 random.seed() while nIterations < maxIterations and nPoints < pointCount: if feedback.isCanceled(): break rx = bbox.xMinimum() + bbox.width() * random.random() ry = bbox.yMinimum() + bbox.height() * random.random() p = QgsPointXY(rx, ry) geom = QgsGeometry.fromPointXY(p) if engine.contains(geom.constGet()) and \ vector.checkMinDistance(p, index, minDistance, points): f = QgsFeature(nPoints) f.initAttributes(1) f.setFields(fields) f.setAttribute('id', nPoints) f.setGeometry(geom) sink.addFeature(f, QgsFeatureSink.FastInsert) index.addFeature(f) points[nPoints] = p nPoints += 1 feedback.setProgress(current_progress + int(nPoints * feature_total)) nIterations += 1 if nPoints < pointCount: feedback.pushInfo(self.tr('Could not generate requested number of random ' 'points. Maximum number of attempts exceeded.')) feedback.setProgress(100) return {self.OUTPUT: dest_id}
def testMeasureLineProjectedWorldPoints(self): # +-+ # | | # +-+ + # checking returned length_mapunits/projected_points of diffferent world points with results from SpatiaLite ST_Project da_3068 = QgsDistanceArea() da_3068.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:3068'), QgsProject.instance().transformContext()) if (da_3068.sourceCrs().isGeographic()): da_3068.setEllipsoid(da_3068.sourceCrs().ellipsoidAcronym()) self.assertEqual(da_3068.sourceCrs().authid(), 'EPSG:3068') print(("setting [{}] srid [{}] description [{}] isGeographic[{}] lengthUnits[{}] projectionAcronym[{}] ellipsoidAcronym[{}]".format(u'EPSG:3068', da_3068.sourceCrs().authid(), da_3068.sourceCrs().description(), da_3068.sourceCrs().isGeographic(), QgsUnitTypes.toString(da_3068.lengthUnits()), da_3068.sourceCrs().projectionAcronym(), da_3068.sourceCrs().ellipsoidAcronym()))) da_wsg84 = QgsDistanceArea() da_wsg84.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:4326'), QgsProject.instance().transformContext()) if (da_wsg84.sourceCrs().isGeographic()): da_wsg84.setEllipsoid(da_wsg84.sourceCrs().ellipsoidAcronym()) self.assertEqual(da_wsg84.sourceCrs().authid(), 'EPSG:4326') print(("setting [{}] srid [{}] description [{}] isGeographic[{}] lengthUnits[{}] projectionAcronym[{}] ellipsoidAcronym[{}] ellipsoid[{}]".format(u'EPSG:4326', da_wsg84.sourceCrs().authid(), da_wsg84.sourceCrs().description(), da_wsg84.sourceCrs().isGeographic(), QgsUnitTypes.toString(da_wsg84.lengthUnits()), da_wsg84.sourceCrs().projectionAcronym(), da_wsg84.sourceCrs().ellipsoidAcronym(), da_wsg84.ellipsoid()))) da_4314 = QgsDistanceArea() da_4314.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:4314'), QgsProject.instance().transformContext()) if (da_4314.sourceCrs().isGeographic()): da_4314.setEllipsoid(da_4314.sourceCrs().ellipsoidAcronym()) self.assertEqual(da_4314.sourceCrs().authid(), 'EPSG:4314') print(("setting [{}] srid [{}] description [{}] isGeographic[{}] lengthUnits[{}] projectionAcronym[{}] ellipsoidAcronym[{}]".format(u'EPSG:4314', da_4314.sourceCrs().authid(), da_4314.sourceCrs().description(), da_4314.sourceCrs().isGeographic(), QgsUnitTypes.toString(da_4314.lengthUnits()), da_4314.sourceCrs().projectionAcronym(), da_4314.sourceCrs().ellipsoidAcronym()))) da_4805 = QgsDistanceArea() da_4805.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:4805'), QgsProject.instance().transformContext()) if (da_4805.sourceCrs().isGeographic()): da_4805.setEllipsoid(da_4805.sourceCrs().ellipsoidAcronym()) self.assertEqual(da_4805.sourceCrs().authid(), 'EPSG:4805') print(("setting [{}] srid [{}] description [{}] isGeographic[{}] lengthUnits[{}] projectionAcronym[{}] ellipsoidAcronym[{}]".format(u'EPSG:4805', da_4805.sourceCrs().authid(), da_4805.sourceCrs().description(), da_4805.sourceCrs().isGeographic(), QgsUnitTypes.toString(da_4805.lengthUnits()), da_4805.sourceCrs().projectionAcronym(), da_4805.sourceCrs().ellipsoidAcronym()))) # EPSG:5665 unknown, why? da_5665 = QgsDistanceArea() da_5665.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:5665'), QgsProject.instance().transformContext()) if (da_5665.sourceCrs().isGeographic()): da_5665.setEllipsoid(da_5665.sourceCrs().ellipsoidAcronym()) print(("setting [{}] srid [{}] description [{}] isGeographic[{}] lengthUnits[{}] projectionAcronym[{}] ellipsoidAcronym[{}]".format(u'EPSG:5665', da_5665.sourceCrs().authid(), da_5665.sourceCrs().description(), da_5665.sourceCrs().isGeographic(), QgsUnitTypes.toString(da_5665.lengthUnits()), da_5665.sourceCrs().projectionAcronym(), da_5665.sourceCrs().ellipsoidAcronym()))) #self.assertEqual(da_5665.sourceCrs().authid(), 'EPSG:5665') da_25833 = QgsDistanceArea() da_25833.setSourceCrs(QgsCoordinateReferenceSystem.fromOgcWmsCrs('EPSG:25833'), QgsProject.instance().transformContext()) if (da_25833.sourceCrs().isGeographic()): da_25833.setEllipsoid(da_25833.sourceCrs().ellipsoidAcronym()) print(("setting [{}] srid [{}] description [{}] isGeographic[{}] lengthUnits[{}] projectionAcronym[{}] ellipsoidAcronym[{}]".format(u'EPSG:25833', da_25833.sourceCrs().authid(), da_25833.sourceCrs().description(), da_25833.sourceCrs().isGeographic(), QgsUnitTypes.toString(da_25833.lengthUnits()), da_25833.sourceCrs().projectionAcronym(), da_25833.sourceCrs().ellipsoidAcronym()))) self.assertEqual(da_25833.sourceCrs().authid(), 'EPSG:25833') # Berlin - Brandenburg Gate - Quadriga point_berlin_3068 = QgsPointXY(23183.38449999984, 21047.3225000017) point_berlin_3068_project = point_berlin_3068.project(1, (math.pi / 2)) point_meter_result = QgsPointXY(0, 0) length_meter_mapunits, point_meter_result = da_3068.measureLineProjected(point_berlin_3068, 1.0, (math.pi / 2)) pprint(point_meter_result) print('-I-> Berlin 3068 length_meter_mapunits[{}] point_meter_result[{}]'.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_3068.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 1, da_3068.lengthUnits(), True), '1.0 m') self.assertEqual(point_meter_result.toString(7), point_berlin_3068_project.toString(7)) point_berlin_wsg84 = QgsPointXY(13.37770458660236, 52.51627178856762) point_berlin_wsg84_project = QgsPointXY(13.37771931736259, 52.51627178856669) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_berlin_wsg84, 1.0, (math.pi / 2)) print('-I-> Berlin Wsg84 length_meter_mapunits[{}] point_meter_result[{}] ellipsoid[{}]'.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 20, da_wsg84.lengthUnits(), True), point_meter_result.asWkt(), da_wsg84.ellipsoid())) # for unknown reasons, this is returning '0.00001473026 m' instead of '0.00001473026 deg' when using da_wsg84.lengthUnits() # self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits,11,da_wsg84.lengthUnits(),True), '0.00001473026 deg') self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 11, QgsUnitTypes.DistanceDegrees, True), '0.00001473026 deg') self.assertEqual(point_meter_result.toString(7), point_berlin_wsg84_project.toString(7)) point_berlin_4314 = QgsPointXY(13.37944343021465, 52.51767872437083) point_berlin_4314_project = QgsPointXY(13.37945816324759, 52.5176787243699) length_meter_mapunits, point_meter_result = da_4314.measureLineProjected(point_berlin_4314, 1.0, (math.pi / 2)) print('-I-> Berlin 4314 length_meter_mapunits[{}] point_meter_result[{}]'.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_4314.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 9, QgsUnitTypes.DistanceDegrees, True), '0.000014733 deg') self.assertEqual(point_meter_result.toString(7), point_berlin_4314_project.toString(7)) point_berlin_4805 = QgsPointXY(31.04960570069176, 52.5174657497405) point_berlin_4805_project = QgsPointXY(31.04962043365347, 52.51746574973957) length_meter_mapunits, point_meter_result = da_4805.measureLineProjected(point_berlin_4805, 1.0, (math.pi / 2)) print('-I-> Berlin 4805 length_meter_mapunits[{}] point_meter_result[{}]'.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_4805.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 9, QgsUnitTypes.DistanceDegrees, True), '0.000014733 deg') self.assertEqual(point_meter_result.toString(7), point_berlin_4805_project.toString(7)) point_berlin_25833 = QgsPointXY(389918.0748318382, 5819698.772194743) point_berlin_25833_project = point_berlin_25833.project(1, (math.pi / 2)) length_meter_mapunits, point_meter_result = da_25833.measureLineProjected(point_berlin_25833, 1.0, (math.pi / 2)) print('-I-> Berlin 25833 length_meter_mapunits[{}] point_meter_result[{}]'.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_25833.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_25833.lengthUnits(), True), '1.0000000 m') self.assertEqual(point_meter_result.toString(7), point_berlin_25833_project.toString(7)) if da_5665.sourceCrs().authid() != "": point_berlin_5665 = QgsPointXY(3389996.871728864, 5822169.719727578) point_berlin_5665_project = point_berlin_5665.project(1, (math.pi / 2)) length_meter_mapunits, point_meter_result = da_5665.measureLineProjected(point_berlin_5665, 1.0, (math.pi / 2)) print('-I-> Berlin 5665 length_meter_mapunits[{}] point_meter_result[{}]'.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_5665.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 1.0, da_5665.lengthUnits(), True), '1.0 m') self.assertEqual(point_meter_result.toString(7), point_berlin_5665_project.toString(7)) print('\n12 points ''above over'' and on the Equator') point_wsg84 = QgsPointXY(25.7844, 71.1725) point_wsg84_project = QgsPointXY(25.78442775215388, 71.17249999999795) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Nordkap, Norway - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, QgsUnitTypes.DistanceDegrees, True), '0.0000278 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(24.95995, 60.16841) point_wsg84_project = QgsPointXY(24.95996801277454, 60.16840999999877) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Helsinki, Finnland - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001801 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(12.599278, 55.692861) point_wsg84_project = QgsPointXY(12.59929390161872, 55.69286099999897) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Copenhagen, Denmark - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001590 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-0.001389, 51.477778) point_wsg84_project = QgsPointXY(-0.001374606184398, 51.4777779999991) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Royal Greenwich Observatory, United Kingdom - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001439 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(7.58769, 47.55814) point_wsg84_project = QgsPointXY(7.587703287209086, 47.55813999999922) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Basel, Switzerland - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001329 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(11.255278, 43.775278) point_wsg84_project = QgsPointXY(11.25529042107924, 43.77527799999933) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Florenz, Italy - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001242 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(14.514722, 35.899722) point_wsg84_project = QgsPointXY(14.51473307693308, 35.89972199999949) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Valletta, Malta - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001108 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-79.933333, 32.783333) point_wsg84_project = QgsPointXY(-79.93332232547254, 32.78333299999955) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Charlston, South Carolina - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001067 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-17.6666666, 27.733333) point_wsg84_project = QgsPointXY(-17.66665645831515, 27.73333299999962) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Ferro, Spain - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001014 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-99.133333, 19.433333) point_wsg84_project = QgsPointXY(-99.1333234776827, 19.43333299999975) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Mexico City, Mexico - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000952 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-79.894444, 9.341667) point_wsg84_project = QgsPointXY(-79.89443489691369, 9.341666999999882) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Colón, Panama - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000910 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-74.075833, 4.598056) point_wsg84_project = QgsPointXY(-74.07582398803629, 4.598055999999943) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Bogotá, Colombia - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000901 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(0, 0) point_wsg84_project = QgsPointXY(0.000008983152841, 0) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Equator, Atlantic Ocean - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000898 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) print('\n12 points ''down under'' and 1 point that should be considered invalid') point_wsg84 = QgsPointXY(-78.509722, -0.218611) point_wsg84_project = QgsPointXY(-78.50971301678221, -0.218610999999997) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Quito, Ecuador - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000898 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(106.816667, -6.2) point_wsg84_project = QgsPointXY(106.8166760356519, -6.199999999999922) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Jakarta, Indonesia - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000904 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-77.018611, -12.035) point_wsg84_project = QgsPointXY(-77.01860181630058, -12.03499999999985) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Lima, Peru - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000918 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(25.466667, -10.716667) point_wsg84_project = QgsPointXY(25.46667614155322, -10.71666699999986) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Kolwezi, Congo - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000914 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-70.333333, -18.483333) point_wsg84_project = QgsPointXY(-70.3333235314429, -18.48333299999976) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Arica, Chile - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00000947 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-70.666667, -33.45) point_wsg84_project = QgsPointXY(-70.66665624452817, -33.44999999999953) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Santiago, Chile - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001076 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(144.9604, -37.8191) point_wsg84_project = QgsPointXY(144.96041135746983741, -37.81909999999945171) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Melbourne, Australia - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001136 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(147.29, -42.88) point_wsg84_project = QgsPointXY(147.2900122399815, -42.87999999999934) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Hobart City,Tasmania, Australia - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001224 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(168.101667, -46.899722) point_wsg84_project = QgsPointXY(168.101680123673, -46.89972199999923) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Ryan''s Creek Aerodrome, New Zealand - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001312 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-69.216667, -51.633333) point_wsg84_project = QgsPointXY(-69.21665255700216, -51.6333329999991) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Río Gallegos, Argentina - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001444 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-68.3, -54.8) point_wsg84_project = QgsPointXY(-68.29998445081456, -54.79999999999899) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Ushuaia, Tierra del Fuego, Argentina - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00001555 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-63.494444, -64.825278) point_wsg84_project = QgsPointXY(-63.49442294002932, -64.82527799999851) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Port Lockroy, Antarctica - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00002106 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-180, -84.863272250) point_wsg84_project = QgsPointXY(-179.9999000000025, -84.8632722499922) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-I-> Someware, Antarctica - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00010000 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7)) point_wsg84 = QgsPointXY(-180, -85.0511300) point_wsg84_project = QgsPointXY(-179.9998962142197, -85.05112999999191) length_meter_mapunits, point_meter_result = da_wsg84.measureLineProjected(point_wsg84, 1.0, (math.pi / 2)) print('-W-> Mercator''s Last Stop, Antarctica - Wsg84 - length_meter_mapunits[{}] point_meter_result[{}] '.format(QgsDistanceArea.formatDistance(length_meter_mapunits, 7, da_wsg84.lengthUnits(), True), point_meter_result.asWkt())) self.assertEqual(QgsDistanceArea.formatDistance(length_meter_mapunits, 8, QgsUnitTypes.DistanceDegrees, True), '0.00010379 deg') self.assertEqual(point_meter_result.toString(7), point_wsg84_project.toString(7))
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException(self.invalidSourceError(parameters, self.INPUT)) group_field_name = self.parameterAsString(parameters, self.GROUP_FIELD, context) order_field_name = self.parameterAsString(parameters, self.ORDER_FIELD, context) date_format = self.parameterAsString(parameters, self.DATE_FORMAT, context) text_dir = self.parameterAsString(parameters, self.OUTPUT_TEXT_DIR, context) group_field_index = source.fields().lookupField(group_field_name) order_field_index = source.fields().lookupField(order_field_name) if group_field_index >= 0: group_field_def = source.fields().at(group_field_index) else: group_field_def = None order_field_def = source.fields().at(order_field_index) fields = QgsFields() if group_field_def is not None: fields.append(group_field_def) begin_field = QgsField(order_field_def) begin_field.setName('begin') fields.append(begin_field) end_field = QgsField(order_field_def) end_field.setName('end') fields.append(end_field) output_wkb = QgsWkbTypes.LineString if QgsWkbTypes.hasM(source.wkbType()): output_wkb = QgsWkbTypes.addM(output_wkb) if QgsWkbTypes.hasZ(source.wkbType()): output_wkb = QgsWkbTypes.addZ(output_wkb) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, output_wkb, source.sourceCrs()) if sink is None: raise QgsProcessingException(self.invalidSinkError(parameters, self.OUTPUT)) points = dict() features = source.getFeatures(QgsFeatureRequest().setSubsetOfAttributes([group_field_index, order_field_index]), QgsProcessingFeatureSource.FlagSkipGeometryValidityChecks) total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break if not f.hasGeometry(): continue point = f.geometry().constGet().clone() if group_field_index >= 0: group = f.attributes()[group_field_index] else: group = 1 order = f.attributes()[order_field_index] if date_format != '': order = datetime.strptime(str(order), date_format) if group in points: points[group].append((order, point)) else: points[group] = [(order, point)] feedback.setProgress(int(current * total)) feedback.setProgress(0) da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) current = 0 total = 100.0 / len(points) if points else 1 for group, vertices in list(points.items()): if feedback.isCanceled(): break vertices.sort(key=lambda x: (x[0] is None, x[0])) f = QgsFeature() attributes = [] if group_field_index >= 0: attributes.append(group) attributes.extend([vertices[0][0], vertices[-1][0]]) f.setAttributes(attributes) line = [node[1] for node in vertices] if text_dir: fileName = os.path.join(text_dir, '%s.txt' % group) with open(fileName, 'w') as fl: fl.write('angle=Azimuth\n') fl.write('heading=Coordinate_System\n') fl.write('dist_units=Default\n') for i in range(len(line)): if i == 0: fl.write('startAt=%f;%f;90\n' % (line[i].x(), line[i].y())) fl.write('survey=Polygonal\n') fl.write('[data]\n') else: angle = line[i - 1].azimuth(line[i]) distance = da.measureLine(QgsPointXY(line[i - 1]), QgsPointXY(line[i])) fl.write('%f;%f;90\n' % (angle, distance)) f.setGeometry(QgsGeometry(QgsLineString(line))) sink.addFeature(f, QgsFeatureSink.FastInsert) current += 1 feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def processAlgorithm(self, parameters, context, feedback): line_source = self.parameterAsSource(parameters, self.LINES, context) poly_source = self.parameterAsSource(parameters, self.POLYGONS, context) length_field_name = self.parameterAsString(parameters, self.LEN_FIELD, context) count_field_name = self.parameterAsString(parameters, self.COUNT_FIELD, context) fields = poly_source.fields() if fields.lookupField(length_field_name) < 0: fields.append(QgsField(length_field_name, QVariant.Double)) length_field_index = fields.lookupField(length_field_name) if fields.lookupField(count_field_name) < 0: fields.append(QgsField(count_field_name, QVariant.Int)) count_field_index = fields.lookupField(count_field_name) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, poly_source.wkbType(), poly_source.sourceCrs()) spatialIndex = QgsSpatialIndex(line_source.getFeatures( QgsFeatureRequest().setSubsetOfAttributes([]).setDestinationCrs(poly_source.sourceCrs(), context.transformContext())), feedback) distArea = QgsDistanceArea() distArea.setSourceCrs(poly_source.sourceCrs(), context.transformContext()) distArea.setEllipsoid(context.project().ellipsoid()) features = poly_source.getFeatures() total = 100.0 / poly_source.featureCount() if poly_source.featureCount() else 0 for current, poly_feature in enumerate(features): if feedback.isCanceled(): break output_feature = QgsFeature() count = 0 length = 0 if poly_feature.hasGeometry(): poly_geom = poly_feature.geometry() has_intersections = False lines = spatialIndex.intersects(poly_geom.boundingBox()) engine = None if len(lines) > 0: has_intersections = True # use prepared geometries for faster intersection tests engine = QgsGeometry.createGeometryEngine(poly_geom.constGet()) engine.prepareGeometry() if has_intersections: request = QgsFeatureRequest().setFilterFids(lines).setSubsetOfAttributes([]).setDestinationCrs(poly_source.sourceCrs(), context.transformContext()) for line_feature in line_source.getFeatures(request): if feedback.isCanceled(): break if engine.intersects(line_feature.geometry().constGet()): outGeom = poly_geom.intersection(line_feature.geometry()) length += distArea.measureLength(outGeom) count += 1 output_feature.setGeometry(poly_geom) attrs = poly_feature.attributes() if length_field_index == len(attrs): attrs.append(length) else: attrs[length_field_index] = length if count_field_index == len(attrs): attrs.append(count) else: attrs[count_field_index] = count output_feature.setAttributes(attrs) sink.addFeature(output_feature, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def processAlgorithm(self, context, feedback): layer = self.getParameterValue(self.INPUT_LAYER) mapping = self.getParameterValue(self.FIELDS_MAPPING) output = self.getOutputFromName(self.OUTPUT_LAYER) layer = QgsProcessingUtils.mapLayerFromString(layer, context) fields = QgsFields() expressions = [] da = QgsDistanceArea() da.setSourceCrs(layer.crs()) da.setEllipsoid(QgsProject.instance().ellipsoid()) exp_context = layer.createExpressionContext() for field_def in mapping: fields.append( QgsField(field_def['name'], field_def['type'], field_def['length'], field_def['precision'])) expression = QgsExpression(field_def['expression']) expression.setGeomCalculator(da) expression.setDistanceUnits(QgsProject.instance().distanceUnits()) expression.setAreaUnits(QgsProject.instance().areaUnits()) expression.prepare(exp_context) if expression.hasParserError(): raise GeoAlgorithmExecutionException( self.tr(u'Parser error in expression "{}": {}').format( str(expression.expression()), str(expression.parserErrorString()))) expressions.append(expression) writer = output.getVectorWriter(fields, layer.wkbType(), layer.crs(), context) # Create output vector layer with new attributes error_exp = None inFeat = QgsFeature() outFeat = QgsFeature() features = QgsProcessingUtils.getFeatures(layer, context) count = QgsProcessingUtils.featureCount(layer, context) if count > 0: total = 100.0 / count for current, inFeat in enumerate(features): rownum = current + 1 geometry = inFeat.geometry() outFeat.setGeometry(geometry) attrs = [] for i in range(0, len(mapping)): field_def = mapping[i] expression = expressions[i] exp_context.setFeature(inFeat) exp_context.lastScope().setVariable("row_number", rownum) value = expression.evaluate(exp_context) if expression.hasEvalError(): error_exp = expression break attrs.append(value) outFeat.setAttributes(attrs) writer.addFeature(outFeat) feedback.setProgress(int(current * total)) else: feedback.setProgress(100) del writer if error_exp is not None: raise GeoAlgorithmExecutionException( self.tr(u'Evaluation error in expression "{}": {}').format( str(error_exp.expression()), str(error_exp.parserErrorString())))
class MeasureAreaTool(QgsMapTool): finished = pyqtSignal() def __init__(self, canvas, msglog): super().__init__(canvas) self.canvas = canvas self.msglog = msglog self.start_point = self.middle_point = self.end_point = None self.rubber_band = QgsRubberBand(self.canvas, QgsWkbTypes.PolygonGeometry) self.rubber_band.setColor(QColor(255, 0, 0, 100)) self.rubber_band.setWidth(3) self.rubber_band_points = QgsRubberBand(self.canvas, QgsWkbTypes.PointGeometry) self.rubber_band_points.setIcon(QgsRubberBand.ICON_CIRCLE) self.rubber_band_points.setIconSize(10) self.rubber_band_points.setColor(QColor(255, 0, 0, 150)) crs = self.canvas.mapSettings().destinationCrs() self.area_calc = QgsDistanceArea() self.area_calc.setSourceCrs(crs, QgsProject.instance().transformContext()) self.area_calc.setEllipsoid(crs.ellipsoidAcronym()) self.reset() def reset(self): """ Reset log message and rubber band""" self.msglog.logMessage("") self.start_point = self.end_point = None self.rubber_band.reset(QgsWkbTypes.PolygonGeometry) self.rubber_band_points.reset(QgsWkbTypes.PointGeometry) def canvasPressEvent(self, event): pass def canvasReleaseEvent(self, event): transform = self.canvas.getCoordinateTransform() point = transform.toMapCoordinates(event.pos().x(), event.pos().y()) if self.start_point and event.button() == Qt.RightButton: multipoint = self.rubber_band.asGeometry() area = self.area_calc.measureArea(multipoint) anglemsg = QMessageBox(self.parent()) anglemsg.finished.connect(self.deactivate) anglemsg.setWindowTitle("Measure area tool") anglemsg.setText("Area: {} ".format( self.area_calc.formatArea(area, 3, QgsUnitTypes.AreaSquareMeters, True))) anglemsg.exec() self.finish() elif self.start_point: self.rubber_band.addPoint(point) self.rubber_band_points.addPoint(point) else: self.start_point = point self.rubber_band.addPoint(self.start_point) self.rubber_band_points.addPoint(self.start_point) def canvasMoveEvent(self, e): if self.start_point and not self.end_point: transform = self.canvas.getCoordinateTransform() point = transform.toMapCoordinates(e.pos().x(), e.pos().y()) self.rubber_band.movePoint(point) multipoint = self.rubber_band.asGeometry() area = self.area_calc.measureArea(multipoint) self.msglog.logMessage("") self.msglog.logMessage( "Current area: {} ".format( self.area_calc.formatArea(area, 3, QgsUnitTypes.AreaSquareMeters, True)), "Measure Area:", 0) def keyPressEvent(self, event): """ When escape key is pressed, line is restarted """ if event.key() == Qt.Key_Escape: self.reset() def finish(self): self.reset() self.finished.emit()
class ExportGeometryInfo(QgisAlgorithm): INPUT = 'INPUT' METHOD = 'CALC_METHOD' OUTPUT = 'OUTPUT' def icon(self): return QIcon( os.path.join(pluginPath, 'images', 'ftools', 'export_geometry.png')) def tags(self): return self.tr( 'export,add,information,measurements,areas,lengths,perimeters,latitudes,longitudes,x,y,z,extract,points,lines,polygons' ).split(',') def group(self): return self.tr('Vector geometry') def __init__(self): super().__init__() self.export_z = False self.export_m = False self.distance_area = None self.calc_methods = [ self.tr('Layer CRS'), self.tr('Project CRS'), self.tr('Ellipsoidal') ] def initAlgorithm(self, config=None): self.addParameter( QgsProcessingParameterFeatureSource(self.INPUT, self.tr('Input layer'))) self.addParameter( QgsProcessingParameterEnum(self.METHOD, self.tr('Calculate using'), options=self.calc_methods, defaultValue=0)) self.addParameter( QgsProcessingParameterFeatureSink(self.OUTPUT, self.tr('Added geom info'))) def name(self): return 'exportaddgeometrycolumns' def displayName(self): return self.tr('Export geometry columns') def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) method = self.parameterAsEnum(parameters, self.METHOD, context) wkb_type = source.wkbType() fields = source.fields() new_fields = QgsFields() if QgsWkbTypes.geometryType(wkb_type) == QgsWkbTypes.PolygonGeometry: new_fields.append(QgsField('area', QVariant.Double)) new_fields.append(QgsField('perimeter', QVariant.Double)) elif QgsWkbTypes.geometryType(wkb_type) == QgsWkbTypes.LineGeometry: new_fields.append(QgsField('length', QVariant.Double)) else: new_fields.append(QgsField('xcoord', QVariant.Double)) new_fields.append(QgsField('ycoord', QVariant.Double)) if QgsWkbTypes.hasZ(source.wkbType()): self.export_z = True new_fields.append(QgsField('zcoord', QVariant.Double)) if QgsWkbTypes.hasM(source.wkbType()): self.export_m = True new_fields.append(QgsField('mvalue', QVariant.Double)) fields = QgsProcessingUtils.combineFields(fields, new_fields) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, wkb_type, source.sourceCrs()) coordTransform = None # Calculate with: # 0 - layer CRS # 1 - project CRS # 2 - ellipsoidal self.distance_area = QgsDistanceArea() if method == 2: self.distance_area.setSourceCrs(source.sourceCrs()) self.distance_area.setEllipsoid(context.project().ellipsoid()) elif method == 1: coordTransform = QgsCoordinateTransform(source.sourceCrs(), context.project().crs()) features = source.getFeatures() total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break outFeat = f attrs = f.attributes() inGeom = f.geometry() if inGeom: if coordTransform is not None: inGeom.transform(coordTransform) if inGeom.type() == QgsWkbTypes.PointGeometry: attrs.extend(self.point_attributes(inGeom)) elif inGeom.type() == QgsWkbTypes.PolygonGeometry: attrs.extend(self.polygon_attributes(inGeom)) else: attrs.extend(self.line_attributes(inGeom)) outFeat.setAttributes(attrs) sink.addFeature(outFeat, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id} def point_attributes(self, geometry): pt = None if not geometry.isMultipart(): pt = geometry.geometry() else: if geometry.numGeometries() > 0: pt = geometry.geometryN(0) attrs = [] if pt: attrs.append(pt.x()) attrs.append(pt.y()) # add point z/m if self.export_z: attrs.append(pt.z()) if self.export_m: attrs.append(pt.m()) return attrs def line_attributes(self, geometry): return [self.distance_area.measureLength(geometry)] def polygon_attributes(self, geometry): area = self.distance_area.measureArea(geometry) perimeter = self.distance_area.measurePerimeter(geometry) return [area, perimeter]
def processAlgorithm(self, progress): layer = dataobjects.getObjectFromUri( self.getParameterValue(self.INPUT_LAYER)) fieldName = self.getParameterValue(self.FIELD_NAME) fieldType = self.TYPES[self.getParameterValue(self.FIELD_TYPE)] width = self.getParameterValue(self.FIELD_LENGTH) precision = self.getParameterValue(self.FIELD_PRECISION) newField = self.getParameterValue(self.NEW_FIELD) formula = self.getParameterValue(self.FORMULA) output = self.getOutputFromName(self.OUTPUT_LAYER) if output.value == '': ext = output.getDefaultFileExtension(self) output.value = system.getTempFilenameInTempFolder(output.name + '.' + ext) provider = layer.dataProvider() fields = layer.pendingFields() if newField: fields.append(QgsField(fieldName, fieldType, '', width, precision)) writer = output.getVectorWriter(fields, provider.geometryType(), layer.crs()) exp = QgsExpression(formula) da = QgsDistanceArea() da.setSourceCrs(layer.crs().srsid()) da.setEllipsoidalMode( iface.mapCanvas().mapSettings().hasCrsTransformEnabled()) da.setEllipsoid(QgsProject.instance().readEntry( 'Measure', '/Ellipsoid', GEO_NONE)[0]) exp.setGeomCalculator(da) if not exp.prepare(layer.pendingFields()): raise GeoAlgorithmExecutionException( self.tr('Evaluation error: %s' % exp.evalErrorString())) outFeature = QgsFeature() outFeature.initAttributes(len(fields)) outFeature.setFields(fields) error = '' calculationSuccess = True features = vector.features(layer) total = 100.0 / len(features) rownum = 1 for current, f in enumerate(features): rownum = current + 1 exp.setCurrentRowNumber(rownum) value = exp.evaluate(f) if exp.hasEvalError(): calculationSuccess = False error = exp.evalErrorString() break else: outFeature.setGeometry(f.geometry()) for fld in f.fields(): outFeature[fld.name()] = f[fld.name()] outFeature[fieldName] = value writer.addFeature(outFeature) progress.setPercentage(int(current * total)) del writer if not calculationSuccess: raise GeoAlgorithmExecutionException( self.tr('An error occurred while evaluating the calculation ' 'string:\n%s' % error))
def drawScaleBar(self, theComposerMap, theTopOffset): """Add a numeric scale to the bottom left of the map We draw the scale bar manually because QGIS does not yet support rendering a scalebar for a geographic map in km. .. seealso:: :meth:`drawNativeScaleBar` Args: * theComposerMap - QgsComposerMap instance used as the basis scale calculations. * theTopOffset - vertical offset at which the map should be drawn Returns: None Raises: Any exceptions raised by the InaSAFE library will be propagated. """ LOGGER.debug('InaSAFE Map drawScaleBar called') myCanvas = self.iface.mapCanvas() myRenderer = myCanvas.mapRenderer() # # Add a linear map scale # myDistanceArea = QgsDistanceArea() myDistanceArea.setSourceCrs(myRenderer.destinationCrs().srsid()) myDistanceArea.setProjectionsEnabled(True) # Determine how wide our map is in km/m # Starting point at BL corner myComposerExtent = theComposerMap.extent() myStartPoint = QgsPoint(myComposerExtent.xMinimum(), myComposerExtent.yMinimum()) # Ending point at BR corner myEndPoint = QgsPoint(myComposerExtent.xMaximum(), myComposerExtent.yMinimum()) myGroundDistance = myDistanceArea.measureLine(myStartPoint, myEndPoint) # Get the equivalent map distance per page mm myMapWidth = self.mapWidth # How far is 1mm on map on the ground in meters? myMMToGroundDistance = myGroundDistance / myMapWidth #print 'MM:', myMMDistance # How long we want the scale bar to be in relation to the map myScaleBarToMapRatio = 0.5 # How many divisions the scale bar should have myTickCount = 5 myScaleBarWidthMM = myMapWidth * myScaleBarToMapRatio myPrintSegmentWidthMM = myScaleBarWidthMM / myTickCount # Segment width in real world (m) # We apply some logic here so that segments are displayed in meters # if each segment is less that 1000m otherwise km. Also the segment # lengths are rounded down to human looking numbers e.g. 1km not 1.1km myUnits = '' myGroundSegmentWidth = myPrintSegmentWidthMM * myMMToGroundDistance if myGroundSegmentWidth < 1000: myUnits = 'm' myGroundSegmentWidth = round(myGroundSegmentWidth) # adjust the segment width now to account for rounding myPrintSegmentWidthMM = myGroundSegmentWidth / myMMToGroundDistance else: myUnits = 'km' # Segment with in real world (km) myGroundSegmentWidth = round(myGroundSegmentWidth / 1000) myPrintSegmentWidthMM = ((myGroundSegmentWidth * 1000) / myMMToGroundDistance) # Now adjust the scalebar width to account for rounding myScaleBarWidthMM = myTickCount * myPrintSegmentWidthMM #print "SBWMM:", myScaleBarWidthMM #print "SWMM:", myPrintSegmentWidthMM #print "SWM:", myGroundSegmentWidthM #print "SWKM:", myGroundSegmentWidthKM # start drawing in line segments myScaleBarHeight = 5 # mm myLineWidth = 0.3 # mm myInsetDistance = 7 # how much to inset the scalebar into the map by myScaleBarX = self.pageMargin + myInsetDistance myScaleBarY = (theTopOffset + self.mapHeight - myInsetDistance - myScaleBarHeight) # mm # Draw an outer background box - shamelessly hardcoded buffer myRect = QgsComposerShape( myScaleBarX - 4, # left edge myScaleBarY - 3, # top edge myScaleBarWidthMM + 13, # right edge myScaleBarHeight + 6, # bottom edge self.composition) myRect.setShapeType(QgsComposerShape.Rectangle) myRect.setLineWidth(myLineWidth) myRect.setFrame(False) myBrush = QtGui.QBrush(QtGui.QColor(255, 255, 255)) # workaround for missing setTransparentFill missing from python api myRect.setBrush(myBrush) self.composition.addItem(myRect) # Set up the tick label font myFontWeight = QtGui.QFont.Normal myFontSize = 6 myItalicsFlag = False myFont = QtGui.QFont('verdana', myFontSize, myFontWeight, myItalicsFlag) # Draw the bottom line myUpshift = 0.3 # shift the bottom line up for better rendering myRect = QgsComposerShape(myScaleBarX, myScaleBarY + myScaleBarHeight - myUpshift, myScaleBarWidthMM, 0.1, self.composition) myRect.setShapeType(QgsComposerShape.Rectangle) myRect.setLineWidth(myLineWidth) myRect.setFrame(False) self.composition.addItem(myRect) # Now draw the scalebar ticks for myTickCountIterator in range(0, myTickCount + 1): myDistanceSuffix = '' if myTickCountIterator == myTickCount: myDistanceSuffix = ' ' + myUnits myRealWorldDistance = ( '%.0f%s' % (myTickCountIterator * myGroundSegmentWidth, myDistanceSuffix)) #print 'RW:', myRealWorldDistance myMMOffset = myScaleBarX + (myTickCountIterator * myPrintSegmentWidthMM) #print 'MM:', myMMOffset myTickHeight = myScaleBarHeight / 2 # Lines are not exposed by the api yet so we # bodge drawing lines using rectangles with 1px height or width myTickWidth = 0.1 # width or rectangle to be drawn myUpTickLine = QgsComposerShape( myMMOffset, myScaleBarY + myScaleBarHeight - myTickHeight, myTickWidth, myTickHeight, self.composition) myUpTickLine.setShapeType(QgsComposerShape.Rectangle) myUpTickLine.setLineWidth(myLineWidth) myUpTickLine.setFrame(False) self.composition.addItem(myUpTickLine) # # Add a tick label # myLabel = QgsComposerLabel(self.composition) myLabel.setFont(myFont) myLabel.setText(myRealWorldDistance) myLabel.adjustSizeToText() myLabel.setItemPosition(myMMOffset - 3, myScaleBarY - myTickHeight) myLabel.setFrame(self.showFramesFlag) self.composition.addItem(myLabel)
class ExportGeometryInfo(QgisAlgorithm): INPUT = 'INPUT' METHOD = 'CALC_METHOD' OUTPUT = 'OUTPUT' def icon(self): return QgsApplication.getThemeIcon( "/algorithms/mAlgorithmAddGeometryAttributes.svg") def svgIconPath(self): return QgsApplication.iconPath( "/algorithms/mAlgorithmAddGeometryAttributes.svg") def tags(self): return self.tr( 'export,add,information,measurements,areas,lengths,perimeters,latitudes,longitudes,x,y,z,extract,points,lines,polygons,sinuosity,fields' ).split(',') def group(self): return self.tr('Vector geometry') def groupId(self): return 'vectorgeometry' def __init__(self): super().__init__() self.export_z = False self.export_m = False self.distance_area = None self.calc_methods = [ self.tr('Layer CRS'), self.tr('Project CRS'), self.tr('Ellipsoidal') ] def initAlgorithm(self, config=None): self.addParameter( QgsProcessingParameterFeatureSource(self.INPUT, self.tr('Input layer'))) self.addParameter( QgsProcessingParameterEnum(self.METHOD, self.tr('Calculate using'), options=self.calc_methods, defaultValue=0)) self.addParameter( QgsProcessingParameterFeatureSink(self.OUTPUT, self.tr('Added geom info'))) def name(self): return 'exportaddgeometrycolumns' def displayName(self): return self.tr('Add geometry attributes') def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException( self.invalidSourceError(parameters, self.INPUT)) method = self.parameterAsEnum(parameters, self.METHOD, context) wkb_type = source.wkbType() fields = source.fields() new_fields = QgsFields() if QgsWkbTypes.geometryType(wkb_type) == QgsWkbTypes.PolygonGeometry: new_fields.append(QgsField('area', QVariant.Double)) new_fields.append(QgsField('perimeter', QVariant.Double)) elif QgsWkbTypes.geometryType(wkb_type) == QgsWkbTypes.LineGeometry: new_fields.append(QgsField('length', QVariant.Double)) if not QgsWkbTypes.isMultiType(source.wkbType()): new_fields.append(QgsField('straightdis', QVariant.Double)) new_fields.append(QgsField('sinuosity', QVariant.Double)) else: new_fields.append(QgsField('xcoord', QVariant.Double)) new_fields.append(QgsField('ycoord', QVariant.Double)) if QgsWkbTypes.hasZ(source.wkbType()): self.export_z = True new_fields.append(QgsField('zcoord', QVariant.Double)) if QgsWkbTypes.hasM(source.wkbType()): self.export_m = True new_fields.append(QgsField('mvalue', QVariant.Double)) fields = QgsProcessingUtils.combineFields(fields, new_fields) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, wkb_type, source.sourceCrs()) if sink is None: raise QgsProcessingException( self.invalidSinkError(parameters, self.OUTPUT)) coordTransform = None # Calculate with: # 0 - layer CRS # 1 - project CRS # 2 - ellipsoidal self.distance_area = QgsDistanceArea() if method == 2: self.distance_area.setSourceCrs(source.sourceCrs(), context.transformContext()) self.distance_area.setEllipsoid(context.project().ellipsoid()) elif method == 1: coordTransform = QgsCoordinateTransform(source.sourceCrs(), context.project().crs(), context.project()) features = source.getFeatures() total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break outFeat = f attrs = f.attributes() inGeom = f.geometry() if inGeom: if coordTransform is not None: inGeom.transform(coordTransform) if inGeom.type() == QgsWkbTypes.PointGeometry: attrs.extend(self.point_attributes(inGeom)) elif inGeom.type() == QgsWkbTypes.PolygonGeometry: attrs.extend(self.polygon_attributes(inGeom)) else: attrs.extend(self.line_attributes(inGeom)) # ensure consistent count of attributes - otherwise null # geometry features will have incorrect attribute length # and provider may reject them if len(attrs) < len(fields): attrs += [NULL] * (len(fields) - len(attrs)) outFeat.setAttributes(attrs) sink.addFeature(outFeat, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id} def point_attributes(self, geometry): pt = None if not geometry.isMultipart(): pt = geometry.constGet() else: if geometry.numGeometries() > 0: pt = geometry.geometryN(0) attrs = [] if pt: attrs.append(pt.x()) attrs.append(pt.y()) # add point z/m if self.export_z: attrs.append(pt.z()) if self.export_m: attrs.append(pt.m()) return attrs def line_attributes(self, geometry): if geometry.isMultipart(): return [self.distance_area.measureLength(geometry)] else: curve = geometry.constGet() p1 = curve.startPoint() p2 = curve.endPoint() straight_distance = self.distance_area.measureLine( QgsPointXY(p1), QgsPointXY(p2)) sinuosity = curve.sinuosity() if math.isnan(sinuosity): sinuosity = NULL return [ self.distance_area.measureLength(geometry), straight_distance, sinuosity ] def polygon_attributes(self, geometry): area = self.distance_area.measureArea(geometry) perimeter = self.distance_area.measurePerimeter(geometry) return [area, perimeter]
class MeasureAngleTool(QgsMapTool): finished = pyqtSignal() def __init__(self, canvas, msglog): super().__init__(canvas) self.canvas = canvas self.msglog = msglog self.start_point = self.middle_point = self.end_point = None self.rubber_band = QgsRubberBand(self.canvas, QgsWkbTypes.LineGeometry) self.rubber_band.setColor(QColor(255, 0, 0, 100)) self.rubber_band.setWidth(3) self.rubber_band_points = QgsRubberBand(self.canvas, QgsWkbTypes.PointGeometry) self.rubber_band_points.setIcon(QgsRubberBand.ICON_CIRCLE) self.rubber_band_points.setIconSize(10) self.rubber_band_points.setColor(QColor(255, 0, 0, 150)) self.rubber_band_curve = QgsRubberBand(self.canvas) self.rubber_band_curve.setWidth(2) self.rubber_band_curve.setColor(QColor(255, 153, 0, 100)) crs = self.canvas.mapSettings().destinationCrs() self.distance_calc = QgsDistanceArea() self.distance_calc.setSourceCrs( crs, QgsProject.instance().transformContext()) self.distance_calc.setEllipsoid(crs.ellipsoidAcronym()) self.reset() def reset(self): self.msglog.logMessage("") self.start_point = self.middle_point = self.end_point = None self.rubber_band.reset(QgsWkbTypes.LineGeometry) self.rubber_band_points.reset(QgsWkbTypes.PointGeometry) self.rubber_band_curve.reset() def canvasPressEvent(self, event): pass def canvasReleaseEvent(self, event): transform = self.canvas.getCoordinateTransform() point = transform.toMapCoordinates(event.pos().x(), event.pos().y()) if self.start_point and self.middle_point: angle_start_to_middle = self.distance_calc.bearing( self.middle_point, self.start_point) angle_end_to_middle = self.distance_calc.bearing( self.middle_point, point) angle = degrees(angle_end_to_middle - angle_start_to_middle) if angle < -180: angle = 360 + angle elif angle > 180: angle = angle - 360 anglemsg = QMessageBox(self.parent()) anglemsg.finished.connect(self.deactivate) anglemsg.setWindowTitle("Measure angle tool") anglemsg.setText("Angle: {:.3F} º".format(abs(angle))) anglemsg.exec() self.finish() elif self.start_point: self.middle_point = point self.rubber_band.addPoint(self.middle_point) self.rubber_band_points.addPoint(self.middle_point) else: self.start_point = point self.rubber_band.addPoint(self.start_point) self.rubber_band_points.addPoint(self.start_point) def canvasMoveEvent(self, e): if self.start_point and not self.end_point: transform = self.canvas.getCoordinateTransform() point = transform.toMapCoordinates(e.pos().x(), e.pos().y()) self.rubber_band.movePoint(point) if self.start_point and self.middle_point and not self.end_point: angle_start_to_middle = self.distance_calc.bearing( self.middle_point, self.start_point) angle_end_to_middle = self.distance_calc.bearing( self.middle_point, point) angle = degrees(angle_end_to_middle - angle_start_to_middle) if angle < -180: angle = 360 + angle elif angle > 180: angle = angle - 360 self.msglog.logMessage("") self.msglog.logMessage( "Current angle: {:.3F} º".format(abs(angle)), "Measure angle:", 0) self.rubber_band_curve.reset() # get the distance from center to point dist_mid_to_p = sqrt((point.x() - self.middle_point.x()) * (point.x() - self.middle_point.x()) + (point.y() - self.middle_point.y()) * (point.y() - self.middle_point.y())) dist_mid_to_start = sqrt( (self.start_point.x() - self.middle_point.x()) * (self.start_point.x() - self.middle_point.x()) + (self.start_point.y() - self.middle_point.y()) * (self.start_point.y() - self.middle_point.y())) # get angle angle_start = atan2(self.start_point.y() - self.middle_point.y(), self.start_point.x() - self.middle_point.x()) angle_p = atan2(point.y() - self.middle_point.y(), point.x() - self.middle_point.x()) # smaller distance if dist_mid_to_p < dist_mid_to_start: dist = dist_mid_to_p else: dist = dist_mid_to_start y_p = dist * sin(angle_p) x_p = dist * cos(angle_p) y_start = dist * sin(angle_start) x_start = dist * cos(angle_start) circular_ring = QgsCircularString() circular_ring = circular_ring.fromTwoPointsAndCenter( QgsPoint(self.middle_point.x() + x_start / 2, self.middle_point.y() + y_start / 2), QgsPoint(self.middle_point.x() + x_p / 2, self.middle_point.y() + y_p / 2), QgsPoint(self.middle_point.x(), self.middle_point.y()), True) circular_geometry = QgsGeometry(circular_ring) self.rubber_band_curve.addGeometry( circular_geometry, QgsCoordinateReferenceSystem( 4326, QgsCoordinateReferenceSystem.EpsgCrsId)) def keyPressEvent(self, event): """ When escape key is pressed, line is restarted """ if event.key() == Qt.Key_Escape: self.reset() def finish(self): self.reset() self.finished.emit()
def regularMatrix(self, parameters, context, source, inField, target_source, targetField, nPoints, feedback): distArea = QgsDistanceArea() distArea.setSourceCrs(source.sourceCrs(), context.transformContext()) distArea.setEllipsoid(context.project().ellipsoid()) inIdx = source.fields().lookupField(inField) targetIdx = target_source.fields().lookupField(targetField) index = QgsSpatialIndex( target_source.getFeatures( QgsFeatureRequest().setSubsetOfAttributes( []).setDestinationCrs(source.sourceCrs(), context.transformContext())), feedback) first = True sink = None dest_id = None features = source.getFeatures( QgsFeatureRequest().setSubsetOfAttributes([inIdx])) total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, inFeat in enumerate(features): if feedback.isCanceled(): break inGeom = inFeat.geometry() if first: featList = index.nearestNeighbor(inGeom.asPoint(), nPoints) first = False fields = QgsFields() input_id_field = source.fields()[inIdx] input_id_field.setName('ID') fields.append(input_id_field) for f in target_source.getFeatures( QgsFeatureRequest().setFilterFids( featList).setSubsetOfAttributes([ targetIdx ]).setDestinationCrs(source.sourceCrs(), context.transformContext())): fields.append( QgsField(str(f[targetField]), QVariant.Double)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, source.wkbType(), source.sourceCrs()) if sink is None: raise QgsProcessingException( self.invalidSinkError(parameters, self.OUTPUT)) data = [inFeat[inField]] for target in target_source.getFeatures( QgsFeatureRequest().setSubsetOfAttributes( []).setFilterFids(featList).setDestinationCrs( source.sourceCrs(), context.transformContext())): if feedback.isCanceled(): break outGeom = target.geometry() dist = distArea.measureLine(inGeom.asPoint(), outGeom.asPoint()) data.append(dist) out_feature = QgsFeature() out_feature.setGeometry(inGeom) out_feature.setAttributes(data) sink.addFeature(out_feature, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
class SplitMapTool(QgsMapToolEdit): def __init__(self, canvas, layer, actionMoveVertices, actionAddVertices, actionRemoveVertices, actionMoveSegment, actionLineClose, actionLineOpen, actionMoveLine): super(SplitMapTool, self).__init__(canvas) self.canvas = canvas self.scene = canvas.scene() self.layer = layer self.actionMoveVertices = actionMoveVertices self.actionAddVertices = actionAddVertices self.actionRemoveVertices = actionRemoveVertices self.actionMoveSegment = actionMoveSegment self.actionLineClose = actionLineClose self.actionLineOpen = actionLineOpen self.actionMoveLine = actionMoveLine self.initialize() def initialize(self): try: self.canvas.renderStarting.disconnect(self.mapCanvasChanged) except: pass self.canvas.renderStarting.connect(self.mapCanvasChanged) try: self.layer.editingStopped.disconnect(self.stopCapturing) except: pass self.layer.editingStopped.connect(self.stopCapturing) self.selectedFeatures = self.layer.selectedFeatures() self.rubberBand = None self.tempRubberBand = None self.capturedPoints = [] self.capturing = False self.setCursor(Qt.CrossCursor) self.proj = QgsProject.instance() self.labels = [] self.vertices = [] self.calculator = QgsDistanceArea() self.calculator.setSourceCrs(self.layer.dataProvider().crs(), QgsProject.instance().transformContext()) self.calculator.setEllipsoid( self.layer.dataProvider().crs().ellipsoidAcronym()) self.drawingLine = False self.movingVertices = False self.addingVertices = False self.removingVertices = False self.movingSegment = False self.movingLine = False self.showingVertices = False self.movingVertex = -1 self.movingSegm = -1 self.movingLineInitialPoint = None self.lineClosed = False def restoreAction(self): self.addingVertices = False self.removingVertices = False self.movingVertices = False self.movingSegment = False self.movingLine = False self.showingVertices = False self.drawingLine = True self.movingVertex = -1 self.movingLineInitialPoint = None self.deleteVertices() self.redrawRubberBand() self.redrawTempRubberBand() self.canvas.scene().addItem(self.tempRubberBand) self.redrawActions() def mapCanvasChanged(self): self.redrawAreas() if self.showingVertices: self.redrawVertices() def canvasMoveEvent(self, event): if self.drawingLine and not self.lineClosed: if self.tempRubberBand != None and self.capturing: mapPoint = self.toMapCoordinates(event.pos()) self.tempRubberBand.movePoint(mapPoint) self.redrawAreas(event.pos()) if self.movingVertices and self.movingVertex >= 0: layerPoint = self.toLayerCoordinates(self.layer, event.pos()) self.capturedPoints[self.movingVertex] = layerPoint if self.lineClosed and self.movingVertex == 0: self.capturedPoints[len(self.capturedPoints) - 1] = layerPoint self.redrawRubberBand() self.redrawVertices() self.redrawAreas() if self.movingSegment and self.movingSegm >= 0: currentPoint = self.toLayerCoordinates(self.layer, event.pos()) distance = self.distancePoint(currentPoint, self.movingLineInitialPoint) bearing = self.movingLineInitialPoint.azimuth(currentPoint) self.capturedPoints[self.movingSegm] = self.projectPoint( self.capturedPoints[self.movingSegm], distance, bearing) self.capturedPoints[self.movingSegm + 1] = self.projectPoint( self.capturedPoints[self.movingSegm + 1], distance, bearing) if self.lineClosed: if self.movingSegm == 0: self.capturedPoints[ len(self.capturedPoints) - 1] = self.projectPoint( self.capturedPoints[len(self.capturedPoints) - 1], distance, bearing) elif self.movingSegm == len(self.capturedPoints) - 2: self.capturedPoints[0] = self.projectPoint( self.capturedPoints[0], distance, bearing) self.redrawRubberBand() self.redrawVertices() self.redrawAreas() self.movingLineInitialPoint = currentPoint if self.movingLine and self.movingLineInitialPoint != None: currentPoint = self.toLayerCoordinates(self.layer, event.pos()) distance = self.distancePoint(currentPoint, self.movingLineInitialPoint) bearing = self.movingLineInitialPoint.azimuth(currentPoint) for i in range(len(self.capturedPoints)): self.capturedPoints[i] = self.projectPoint( self.capturedPoints[i], distance, bearing) self.redrawRubberBand() self.redrawAreas() self.movingLineInitialPoint = currentPoint def projectPoint(self, point, distance, bearing): rads = bearing * pi / 180.0 dx = distance * sin(rads) dy = distance * cos(rads) return QgsPointXY(point.x() + dx, point.y() + dy) def redrawAreas(self, mousePos=None): self.deleteLabels() if self.capturing and len(self.capturedPoints) > 0: for i in range(len(self.selectedFeatures)): geometry = QgsGeometry(self.selectedFeatures[i].geometry()) movingPoints = list(self.capturedPoints) if mousePos != None: movingPoints.append( self.toLayerCoordinates(self.layer, mousePos)) result, newGeometries, topoTestPoints = geometry.splitGeometry( movingPoints, self.proj.topologicalEditing()) self.addLabel(geometry) if newGeometries != None and len(newGeometries) > 0: for i in range(len(newGeometries)): self.addLabel(newGeometries[i]) def addLabel(self, geometry): area = self.calculator.measureArea(geometry) labelPoint = geometry.pointOnSurface().vertexAt(0) label = QGraphicsTextItem("%.2f" % round(area, 2)) label.setHtml( "<div style=\"color:#ffffff;background:#111111;padding:5px\">" + "%.2f" % round(area, 2) + " " + areaUnits[self.calculator.areaUnits()] + "</div>") point = self.toMapCoordinatesV2(self.layer, labelPoint) label.setPos(self.toCanvasCoordinates(QgsPointXY(point.x(), point.y()))) self.scene.addItem(label) self.labels.append(label) def deleteLabels(self): for i in range(len(self.labels)): self.scene.removeItem(self.labels[i]) self.labels = [] def canvasPressEvent(self, event): if self.movingVertices: for i in range(len(self.capturedPoints)): point = self.toMapCoordinates(self.layer, self.capturedPoints[i]) currentVertex = self.toCanvasCoordinates( QgsPointXY(point.x(), point.y())) if self.distancePoint(event.pos(), currentVertex) <= maxDistanceHitTest: self.movingVertex = i break if self.movingSegment: for i in range(len(self.capturedPoints) - 1): vertex1 = self.toMapCoordinates(self.layer, self.capturedPoints[i]) currentVertex1 = self.toCanvasCoordinates( QgsPointXY(vertex1.x(), vertex1.y())) vertex2 = self.toMapCoordinates(self.layer, self.capturedPoints[i + 1]) currentVertex2 = self.toCanvasCoordinates( QgsPointXY(vertex2.x(), vertex2.y())) if self.distancePointLine( event.pos().x(), event.pos().y(), currentVertex1.x(), currentVertex1.y(), currentVertex2.x(), currentVertex2.y()) <= maxDistanceHitTest: self.movingSegm = i break self.movingLineInitialPoint = self.toLayerCoordinates( self.layer, event.pos()) def distancePoint(self, eventPos, vertexPos): return sqrt((eventPos.x() - vertexPos.x())**2 + (eventPos.y() - vertexPos.y())**2) def canvasReleaseEvent(self, event): if self.movingVertices or self.movingSegment or self.movingLine: if event.button() == Qt.RightButton: self.finishOperation() elif self.addingVertices: if event.button() == Qt.LeftButton: self.addVertex(event.pos()) elif event.button() == Qt.RightButton: self.finishOperation() elif self.removingVertices: if event.button() == Qt.LeftButton: self.removeVertex(event.pos()) elif event.button() == Qt.RightButton: self.finishOperation() else: if event.button() == Qt.LeftButton: if not self.lineClosed: if not self.capturing: self.startCapturing() self.addEndingVertex(event.pos()) elif event.button() == Qt.RightButton: self.finishOperation() self.movingVertex = -1 self.movingSegm = -1 self.movingLineInitialPoint = None self.redrawActions() def keyReleaseEvent(self, event): if event.key() == Qt.Key_Escape: self.stopCapturing() if event.key() == Qt.Key_Backspace or event.key() == Qt.Key_Delete: self.removeLastVertex() if event.key() == Qt.Key_Return or event.key() == Qt.Key_Enter: self.finishOperation() event.accept() self.redrawActions() def finishOperation(self): self.doSplit() self.stopCapturing() self.initialize() self.startCapturing() def doSplit(self): if self.capturedPoints != None: self.layer.splitFeatures(self.capturedPoints, self.proj.topologicalEditing()) def startCapturing(self): self.prepareRubberBand() self.prepareTempRubberBand() self.drawingLine = True self.capturing = True self.redrawActions() def prepareRubberBand(self): color = QColor("red") color.setAlphaF(0.78) self.rubberBand = QgsRubberBand(self.canvas, QgsWkbTypes.LineGeometry) self.rubberBand.setWidth(1) self.rubberBand.setColor(color) self.rubberBand.show() def prepareTempRubberBand(self): color = QColor("red") color.setAlphaF(0.78) self.tempRubberBand = QgsRubberBand(self.canvas, QgsWkbTypes.LineGeometry) self.tempRubberBand.setWidth(1) self.tempRubberBand.setColor(color) self.tempRubberBand.setLineStyle(Qt.DotLine) self.tempRubberBand.show() def redrawRubberBand(self): self.canvas.scene().removeItem(self.rubberBand) self.prepareRubberBand() for i in range(len(self.capturedPoints)): point = self.capturedPoints[i] if point.__class__ == QgsPoint: vertexCoord = self.toMapCoordinatesV2(self.layer, self.capturedPoints[i]) vertexCoord = QgsPointXY(vertexCoord.x(), vertexCoord.y()) else: vertexCoord = self.toMapCoordinates(self.layer, self.capturedPoints[i]) self.rubberBand.addPoint(vertexCoord) def redrawTempRubberBand(self): if self.tempRubberBand != None: self.tempRubberBand.reset(QgsWkbTypes.LineGeometry) self.tempRubberBand.addPoint( self.toMapCoordinates( self.layer, self.capturedPoints[len(self.capturedPoints) - 1])) def stopCapturing(self): self.deleteLabels() self.deleteVertices() if self.rubberBand: self.canvas.scene().removeItem(self.rubberBand) self.rubberBand = None if self.tempRubberBand: self.canvas.scene().removeItem(self.tempRubberBand) self.tempRubberBand = None self.drawingLine = False self.movingVertices = False self.showingVertices = False self.capturing = False self.capturedPoints = [] self.canvas.refresh() self.redrawActions() def addEndingVertex(self, canvasPoint): mapPoint = self.toMapCoordinates(canvasPoint) layerPoint = self.toLayerCoordinates(self.layer, canvasPoint) self.rubberBand.addPoint(mapPoint) self.capturedPoints.append(layerPoint) self.tempRubberBand.reset(QgsWkbTypes.LineGeometry) self.tempRubberBand.addPoint(mapPoint) def removeLastVertex(self): if not self.capturing: return rubberBandSize = self.rubberBand.numberOfVertices() tempRubberBandSize = self.tempRubberBand.numberOfVertices() numPoints = len(self.capturedPoints) if rubberBandSize < 1 or numPoints < 1: return self.rubberBand.removePoint(-1) if rubberBandSize > 1: if tempRubberBandSize > 1: point = self.rubberBand.getPoint(0, rubberBandSize - 2) self.tempRubberBand.movePoint(tempRubberBandSize - 2, point) else: self.tempRubberBand.reset(self.bandType()) del self.capturedPoints[-1] def addVertex(self, pos): newCapturedPoints = [] for i in range(len(self.capturedPoints) - 1): newCapturedPoints.append(self.capturedPoints[i]) vertex1 = self.toMapCoordinates(self.layer, self.capturedPoints[i]) currentVertex1 = self.toCanvasCoordinates( QgsPointXY(vertex1.x(), vertex1.y())) vertex2 = self.toMapCoordinates(self.layer, self.capturedPoints[i + 1]) currentVertex2 = self.toCanvasCoordinates( QgsPointXY(vertex2.x(), vertex2.y())) distance = self.distancePointLine(pos.x(), pos.y(), currentVertex1.x(), currentVertex1.y(), currentVertex2.x(), currentVertex2.y()) if distance <= maxDistanceHitTest: layerPoint = self.toLayerCoordinates(self.layer, pos) newCapturedPoints.append(layerPoint) newCapturedPoints.append(self.capturedPoints[len(self.capturedPoints) - 1]) self.capturedPoints = newCapturedPoints self.redrawRubberBand() self.redrawVertices() self.redrawAreas() self.redrawActions() def removeVertex(self, pos): deletedFirst = False deletedLast = False newCapturedPoints = [] for i in range(len(self.capturedPoints)): vertex = self.toMapCoordinates(self.layer, self.capturedPoints[i]) currentVertex = self.toCanvasCoordinates( QgsPointXY(vertex.x(), vertex.y())) if not self.distancePoint(pos, currentVertex) <= maxDistanceHitTest: newCapturedPoints.append(self.capturedPoints[i]) elif i == 0: deletedFirst = True elif i == len(self.capturedPoints) - 1: deletedLast = True self.capturedPoints = newCapturedPoints if deletedFirst and deletedLast: self.lineClosed = False self.redrawRubberBand() self.redrawVertices() self.redrawAreas() self.redrawActions() if len(self.capturedPoints) <= 2: self.stopRemovingVertices() def startMovingVertices(self): self.stopMovingLine() self.stopAddingVertices() self.stopRemovingVertices() self.stopMovingSegment() self.actionMoveVertices.setChecked(True) self.movingVertices = True self.showingVertices = True self.drawingLine = False self.canvas.scene().removeItem(self.tempRubberBand) self.redrawVertices() self.redrawAreas() self.redrawActions() def stopMovingVertices(self): self.movingVertices = False self.actionMoveVertices.setChecked(False) self.restoreAction() def startAddingVertices(self): self.stopMovingVertices() self.stopRemovingVertices() self.stopMovingLine() self.stopMovingSegment() self.actionAddVertices.setChecked(True) self.addingVertices = True self.showingVertices = True self.drawingLine = False self.canvas.scene().removeItem(self.tempRubberBand) self.redrawVertices() self.redrawAreas() self.redrawActions() def stopAddingVertices(self): self.addVertices = False self.actionAddVertices.setChecked(False) self.restoreAction() def startRemovingVertices(self): self.stopMovingVertices() self.stopAddingVertices() self.stopMovingLine() self.stopMovingSegment() self.actionRemoveVertices.setChecked(True) self.removingVertices = True self.showingVertices = True self.drawingLine = False self.canvas.scene().removeItem(self.tempRubberBand) self.redrawVertices() self.redrawAreas() self.redrawActions() def stopRemovingVertices(self): self.removingVertices = False self.actionRemoveVertices.setChecked(False) self.restoreAction() def startMovingSegment(self): self.stopMovingVertices() self.stopMovingLine() self.stopAddingVertices() self.stopRemovingVertices() self.actionMoveSegment.setChecked(True) self.movingSegment = True self.showingVertices = False self.drawingLine = False self.canvas.scene().removeItem(self.tempRubberBand) self.redrawVertices() self.redrawAreas() self.redrawActions() def stopMovingSegment(self): self.movingSegment = False self.actionMoveSegment.setChecked(False) self.restoreAction() def startMovingLine(self): self.stopMovingVertices() self.stopAddingVertices() self.stopRemovingVertices() self.stopMovingSegment() self.actionMoveLine.setChecked(True) self.movingLine = True self.showingVertices = False self.drawingLine = False self.canvas.scene().removeItem(self.tempRubberBand) self.redrawAreas() self.redrawActions() def stopMovingLine(self): self.actionMoveLine.setChecked(False) self.restoreAction() def lineClose(self): self.lineClosed = True self.capturedPoints.append(self.capturedPoints[0]) self.redrawRubberBand() self.redrawTempRubberBand() self.redrawAreas() self.redrawActions() def lineOpen(self): self.lineClosed = False del self.capturedPoints[-1] self.redrawRubberBand() self.redrawTempRubberBand() self.redrawAreas() self.redrawActions() def showVertices(self): for i in range(len(self.capturedPoints)): vertexc = self.toMapCoordinates(self.layer, self.capturedPoints[i]) vertexCoords = self.toCanvasCoordinates( QgsPointXY(vertexc.x(), vertexc.y())) if i == self.movingVertex: vertex = self.scene.addRect(vertexCoords.x() - 5, vertexCoords.y() - 5, 10, 10, QPen(QColor("green")), QBrush(QColor("green"))) self.vertices.append(vertex) elif i == len(self.capturedPoints ) - 1 and self.movingVertex == 0 and self.lineClosed: vertex = self.scene.addRect(vertexCoords.x() - 5, vertexCoords.y() - 5, 10, 10, QPen(QColor("green")), QBrush(QColor("green"))) self.vertices.append(vertex) else: vertex = self.scene.addRect(vertexCoords.x() - 4, vertexCoords.y() - 4, 8, 8, QPen(QColor("red")), QBrush(QColor("red"))) self.vertices.append(vertex) def deleteVertices(self): for i in range(len(self.vertices)): self.scene.removeItem(self.vertices[i]) self.vertices = [] def lineMagnitude(self, x1, y1, x2, y2): return sqrt(pow((x2 - x1), 2) + pow((y2 - y1), 2)) def distancePointLine(self, px, py, x1, y1, x2, y2): magnitude = self.lineMagnitude(x1, y1, x2, y2) if magnitude < 0.00000001: distance = 9999 return distance u1 = (((px - x1) * (x2 - x1)) + ((py - y1) * (y2 - y1))) u = u1 / (magnitude * magnitude) if (u < 0.00001) or (u > 1): ix = self.lineMagnitude(px, py, x1, y1) iy = self.lineMagnitude(px, py, x2, y2) if ix > iy: distance = iy else: distance = ix else: ix = x1 + u * (x2 - x1) iy = y1 + u * (y2 - y1) distance = self.lineMagnitude(px, py, ix, iy) return distance def redrawVertices(self): self.deleteVertices() self.showVertices() def redrawActions(self): self.redrawActionMoveVertices() self.redrawActionAddVertices() self.redrawActionRemoveVertices() self.redrawActionMoveSegment() self.redrawActionLineClose() self.redrawActionLineOpen() self.redrawActionMoveLine() def redrawActionMoveVertices(self): self.actionMoveVertices.setEnabled(False) if len(self.capturedPoints) > 0: self.actionMoveVertices.setEnabled(True) def redrawActionAddVertices(self): self.actionAddVertices.setEnabled(False) if len(self.capturedPoints) >= 2: self.actionAddVertices.setEnabled(True) def redrawActionRemoveVertices(self): self.actionRemoveVertices.setEnabled(False) if len(self.capturedPoints) > 2: self.actionRemoveVertices.setEnabled(True) def redrawActionMoveSegment(self): self.actionMoveSegment.setEnabled(False) if len(self.capturedPoints) > 2: self.actionMoveSegment.setEnabled(True) def redrawActionLineClose(self): self.actionLineClose.setEnabled(False) if not self.lineClosed and len(self.capturedPoints) >= 3: self.actionLineClose.setEnabled(True) def redrawActionLineOpen(self): self.actionLineOpen.setEnabled(False) if self.lineClosed: self.actionLineOpen.setEnabled(True) def redrawActionMoveLine(self): self.actionMoveLine.setEnabled(False) if len(self.capturedPoints) > 0: self.actionMoveLine.setEnabled(True)
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException( self.invalidSourceError(parameters, self.INPUT)) output_file = self.parameterAsFileOutput(parameters, self.OUTPUT_HTML_FILE, context) spatialIndex = QgsSpatialIndex(source, feedback) distance = QgsDistanceArea() distance.setSourceCrs(source.sourceCrs(), context.transformContext()) distance.setEllipsoid(context.project().ellipsoid()) sumDist = 0.00 A = source.sourceExtent() A = float(A.width() * A.height()) features = source.getFeatures() count = source.featureCount() total = 100.0 / count if count else 1 for current, feat in enumerate(features): if feedback.isCanceled(): break neighbourID = spatialIndex.nearestNeighbor( feat.geometry().asPoint(), 2)[1] request = QgsFeatureRequest().setFilterFid( neighbourID).setSubsetOfAttributes([]) neighbour = next(source.getFeatures(request)) sumDist += distance.measureLine(neighbour.geometry().asPoint(), feat.geometry().asPoint()) feedback.setProgress(int(current * total)) do = float(sumDist) / count de = float(0.5 / math.sqrt(count / A)) d = float(do / de) SE = float(0.26136 / math.sqrt(count**2 / A)) zscore = float((do - de) / SE) results = {} results[self.OBSERVED_MD] = do results[self.EXPECTED_MD] = de results[self.NN_INDEX] = d results[self.POINT_COUNT] = count results[self.Z_SCORE] = zscore if output_file: data = [] data.append('Observed mean distance: ' + str(do)) data.append('Expected mean distance: ' + str(de)) data.append('Nearest neighbour index: ' + str(d)) data.append('Number of points: ' + str(count)) data.append('Z-Score: ' + str(zscore)) self.createHTML(output_file, data) results[self.OUTPUT_HTML_FILE] = output_file return results
class ExportGeometryInfo(QgisAlgorithm): INPUT = 'INPUT' METHOD = 'CALC_METHOD' OUTPUT = 'OUTPUT' def icon(self): return QgsApplication.getThemeIcon("/algorithms/mAlgorithmAddGeometryAttributes.svg") def svgIconPath(self): return QgsApplication.iconPath("/algorithms/mAlgorithmAddGeometryAttributes.svg") def tags(self): return self.tr('export,add,information,measurements,areas,lengths,perimeters,latitudes,longitudes,x,y,z,extract,points,lines,polygons,sinuosity,fields').split(',') def group(self): return self.tr('Vector geometry') def groupId(self): return 'vectorgeometry' def __init__(self): super().__init__() self.export_z = False self.export_m = False self.distance_area = None self.calc_methods = [self.tr('Layer CRS'), self.tr('Project CRS'), self.tr('Ellipsoidal')] def initAlgorithm(self, config=None): self.addParameter(QgsProcessingParameterFeatureSource(self.INPUT, self.tr('Input layer'))) self.addParameter(QgsProcessingParameterEnum(self.METHOD, self.tr('Calculate using'), options=self.calc_methods, defaultValue=0)) self.addParameter(QgsProcessingParameterFeatureSink(self.OUTPUT, self.tr('Added geom info'))) def name(self): return 'exportaddgeometrycolumns' def displayName(self): return self.tr('Add geometry attributes') def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException(self.invalidSourceError(parameters, self.INPUT)) method = self.parameterAsEnum(parameters, self.METHOD, context) wkb_type = source.wkbType() fields = source.fields() new_fields = QgsFields() if QgsWkbTypes.geometryType(wkb_type) == QgsWkbTypes.PolygonGeometry: new_fields.append(QgsField('area', QVariant.Double)) new_fields.append(QgsField('perimeter', QVariant.Double)) elif QgsWkbTypes.geometryType(wkb_type) == QgsWkbTypes.LineGeometry: new_fields.append(QgsField('length', QVariant.Double)) if not QgsWkbTypes.isMultiType(source.wkbType()): new_fields.append(QgsField('straightdis', QVariant.Double)) new_fields.append(QgsField('sinuosity', QVariant.Double)) else: new_fields.append(QgsField('xcoord', QVariant.Double)) new_fields.append(QgsField('ycoord', QVariant.Double)) if QgsWkbTypes.hasZ(source.wkbType()): self.export_z = True new_fields.append(QgsField('zcoord', QVariant.Double)) if QgsWkbTypes.hasM(source.wkbType()): self.export_m = True new_fields.append(QgsField('mvalue', QVariant.Double)) fields = QgsProcessingUtils.combineFields(fields, new_fields) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, wkb_type, source.sourceCrs()) if sink is None: raise QgsProcessingException(self.invalidSinkError(parameters, self.OUTPUT)) coordTransform = None # Calculate with: # 0 - layer CRS # 1 - project CRS # 2 - ellipsoidal self.distance_area = QgsDistanceArea() if method == 2: self.distance_area.setSourceCrs(source.sourceCrs(), context.transformContext()) self.distance_area.setEllipsoid(context.project().ellipsoid()) elif method == 1: coordTransform = QgsCoordinateTransform(source.sourceCrs(), context.project().crs(), context.project()) features = source.getFeatures() total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break outFeat = f attrs = f.attributes() inGeom = f.geometry() if inGeom: if coordTransform is not None: inGeom.transform(coordTransform) if inGeom.type() == QgsWkbTypes.PointGeometry: attrs.extend(self.point_attributes(inGeom)) elif inGeom.type() == QgsWkbTypes.PolygonGeometry: attrs.extend(self.polygon_attributes(inGeom)) else: attrs.extend(self.line_attributes(inGeom)) # ensure consistent count of attributes - otherwise null # geometry features will have incorrect attribute length # and provider may reject them if len(attrs) < len(fields): attrs += [NULL] * (len(fields) - len(attrs)) outFeat.setAttributes(attrs) sink.addFeature(outFeat, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id} def point_attributes(self, geometry): pt = None if not geometry.isMultipart(): pt = geometry.constGet() else: if geometry.numGeometries() > 0: pt = geometry.geometryN(0) attrs = [] if pt: attrs.append(pt.x()) attrs.append(pt.y()) # add point z/m if self.export_z: attrs.append(pt.z()) if self.export_m: attrs.append(pt.m()) return attrs def line_attributes(self, geometry): if geometry.isMultipart(): return [self.distance_area.measureLength(geometry)] else: curve = geometry.constGet() p1 = curve.startPoint() p2 = curve.endPoint() straight_distance = self.distance_area.measureLine(QgsPointXY(p1), QgsPointXY(p2)) sinuosity = curve.sinuosity() if math.isnan(sinuosity): sinuosity = NULL return [self.distance_area.measureLength(geometry), straight_distance, sinuosity] def polygon_attributes(self, geometry): area = self.distance_area.measureArea(geometry) perimeter = self.distance_area.measurePerimeter(geometry) return [area, perimeter]
class SizeCalculator(object): """Special object to handle size calculation with an output unit.""" def __init__(self, coordinate_reference_system, geometry_type, exposure_key): """Constructor for the size calculator. :param coordinate_reference_system: The Coordinate Reference System of the layer. :type coordinate_reference_system: QgsCoordinateReferenceSystem :param exposure_key: The geometry type of the layer. :type exposure_key: qgis.core.QgsWkbTypes.GeometryType """ self.calculator = QgsDistanceArea() self.calculator.setSourceCrs(coordinate_reference_system) self.calculator.setEllipsoid('WGS84') self.calculator.setEllipsoidalMode(True) if geometry_type == QgsWKBTypes.LineGeometry: self.default_unit = unit_metres LOGGER.info('The size calculator is set to use {unit}'.format( unit=distance_unit[self.calculator.lengthUnits()])) else: self.default_unit = unit_square_metres LOGGER.info('The size calculator is set to use {unit}'.format( unit=distance_unit[self.calculator.areaUnits()])) self.geometry_type = geometry_type self.output_unit = None if exposure_key: exposure_definition = definition(exposure_key) self.output_unit = exposure_definition['size_unit'] def measure(self, geometry): """Measure the length or the area of a geometry. :param geometry: The geometry. :type geometry: QgsGeometry :return: The geometric size in the expected exposure unit. :rtype: float """ message = 'Size with NaN value : geometry valid={valid}, WKT={wkt}' feature_size = 0 if geometry.isMultipart(): # Be careful, the size calculator is not working well on a # multipart. # So we compute the size part per part. See ticket #3812 for single in geometry.asGeometryCollection(): if self.geometry_type == QgsWKBTypes.LineGeometry: geometry_size = self.calculator.measureLength(single) else: geometry_size = self.calculator.measureArea(single) if not isnan(geometry_size): feature_size += geometry_size else: LOGGER.debug( message.format(valid=single.isGeosValid(), wkt=single.exportToWkt())) else: if self.geometry_type == QgsWKBTypes.LineGeometry: geometry_size = self.calculator.measureLength(geometry) else: geometry_size = self.calculator.measureArea(geometry) if not isnan(geometry_size): feature_size = geometry_size else: LOGGER.debug( message.format(valid=geometry.isGeosValid(), wkt=geometry.exportToWkt())) feature_size = round(feature_size) if self.output_unit: if self.output_unit != self.default_unit: feature_size = convert_unit(feature_size, self.default_unit, self.output_unit) return feature_size
def draw_scalebar(self, composer_map, top_offset): """Add a numeric scale to the bottom left of the map. We draw the scale bar manually because QGIS does not yet support rendering a scale bar for a geographic map in km. .. seealso:: :meth:`drawNativeScaleBar` :param composer_map: Composer map on which to draw the scalebar. :type composer_map: QgsComposerMap :param top_offset: Vertical offset at which the logo should be drawn. :type top_offset: int """ LOGGER.debug('InaSAFE Map drawScaleBar called') myCanvas = self.iface.mapCanvas() myRenderer = myCanvas.mapRenderer() # # Add a linear map scale # myDistanceArea = QgsDistanceArea() myDistanceArea.setSourceCrs(myRenderer.destinationCrs().srsid()) myDistanceArea.setEllipsoidalMode(True) # Determine how wide our map is in km/m # Starting point at BL corner myComposerExtent = composer_map.extent() myStartPoint = QgsPoint(myComposerExtent.xMinimum(), myComposerExtent.yMinimum()) # Ending point at BR corner myEndPoint = QgsPoint(myComposerExtent.xMaximum(), myComposerExtent.yMinimum()) myGroundDistance = myDistanceArea.measureLine(myStartPoint, myEndPoint) # Get the equivalent map distance per page mm myMapWidth = self.mapWidth # How far is 1mm on map on the ground in meters? myMMToGroundDistance = myGroundDistance / myMapWidth #print 'MM:', myMMDistance # How long we want the scale bar to be in relation to the map myScaleBarToMapRatio = 0.5 # How many divisions the scale bar should have myTickCount = 5 myScaleBarWidthMM = myMapWidth * myScaleBarToMapRatio myPrintSegmentWidthMM = myScaleBarWidthMM / myTickCount # Segment width in real world (m) # We apply some logic here so that segments are displayed in meters # if each segment is less that 1000m otherwise km. Also the segment # lengths are rounded down to human looking numbers e.g. 1km not 1.1km myUnits = '' myGroundSegmentWidth = myPrintSegmentWidthMM * myMMToGroundDistance if myGroundSegmentWidth < 1000: myUnits = 'm' myGroundSegmentWidth = round(myGroundSegmentWidth) # adjust the segment width now to account for rounding myPrintSegmentWidthMM = myGroundSegmentWidth / myMMToGroundDistance else: myUnits = 'km' # Segment with in real world (km) myGroundSegmentWidth = round(myGroundSegmentWidth / 1000) myPrintSegmentWidthMM = ((myGroundSegmentWidth * 1000) / myMMToGroundDistance) # Now adjust the scalebar width to account for rounding myScaleBarWidthMM = myTickCount * myPrintSegmentWidthMM #print "SBWMM:", myScaleBarWidthMM #print "SWMM:", myPrintSegmentWidthMM #print "SWM:", myGroundSegmentWidthM #print "SWKM:", myGroundSegmentWidthKM # start drawing in line segments myScaleBarHeight = 5 # mm myLineWidth = 0.3 # mm myInsetDistance = 7 # how much to inset the scalebar into the map by myScaleBarX = self.pageMargin + myInsetDistance myScaleBarY = ( top_offset + self.mapHeight - myInsetDistance - myScaleBarHeight) # mm # Draw an outer background box - shamelessly hardcoded buffer myRect = QgsComposerShape(myScaleBarX - 4, # left edge myScaleBarY - 3, # top edge myScaleBarWidthMM + 13, # right edge myScaleBarHeight + 6, # bottom edge self.composition) myRect.setShapeType(QgsComposerShape.Rectangle) myPen = QtGui.QPen() myPen.setColor(QtGui.QColor(255, 255, 255)) myPen.setWidthF(myLineWidth) myRect.setPen(myPen) #myRect.setLineWidth(myLineWidth) myRect.setFrameEnabled(False) myBrush = QtGui.QBrush(QtGui.QColor(255, 255, 255)) # workaround for missing setTransparentFill missing from python api myRect.setBrush(myBrush) self.composition.addItem(myRect) # Set up the tick label font myFontWeight = QtGui.QFont.Normal myFontSize = 6 myItalicsFlag = False myFont = QtGui.QFont('verdana', myFontSize, myFontWeight, myItalicsFlag) # Draw the bottom line myUpshift = 0.3 # shift the bottom line up for better rendering myRect = QgsComposerShape(myScaleBarX, myScaleBarY + myScaleBarHeight - myUpshift, myScaleBarWidthMM, 0.1, self.composition) myRect.setShapeType(QgsComposerShape.Rectangle) myPen = QtGui.QPen() myPen.setColor(QtGui.QColor(255, 255, 255)) myPen.setWidthF(myLineWidth) myRect.setPen(myPen) #myRect.setLineWidth(myLineWidth) myRect.setFrameEnabled(False) self.composition.addItem(myRect) # Now draw the scalebar ticks for myTickCountIterator in range(0, myTickCount + 1): myDistanceSuffix = '' if myTickCountIterator == myTickCount: myDistanceSuffix = ' ' + myUnits myRealWorldDistance = ('%.0f%s' % (myTickCountIterator * myGroundSegmentWidth, myDistanceSuffix)) #print 'RW:', myRealWorldDistance myMMOffset = myScaleBarX + (myTickCountIterator * myPrintSegmentWidthMM) #print 'MM:', myMMOffset myTickHeight = myScaleBarHeight / 2 # Lines are not exposed by the api yet so we # bodge drawing lines using rectangles with 1px height or width myTickWidth = 0.1 # width or rectangle to be drawn myUpTickLine = QgsComposerShape( myMMOffset, myScaleBarY + myScaleBarHeight - myTickHeight, myTickWidth, myTickHeight, self.composition) myUpTickLine.setShapeType(QgsComposerShape.Rectangle) myPen = QtGui.QPen() myPen.setWidthF(myLineWidth) myUpTickLine.setPen(myPen) #myUpTickLine.setLineWidth(myLineWidth) myUpTickLine.setFrameEnabled(False) self.composition.addItem(myUpTickLine) # # Add a tick label # myLabel = QgsComposerLabel(self.composition) myLabel.setFont(myFont) myLabel.setText(myRealWorldDistance) myLabel.adjustSizeToText() myLabel.setItemPosition( myMMOffset - 3, myScaleBarY - myTickHeight) myLabel.setFrameEnabled(self.showFramesFlag) self.composition.addItem(myLabel)
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) pointCount = self.parameterAsDouble(parameters, self.POINTS_NUMBER, context) minDistance = self.parameterAsDouble(parameters, self.MIN_DISTANCE, context) fields = QgsFields() fields.append(QgsField('id', QVariant.Int, '', 10, 0)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, QgsWkbTypes.Point, source.sourceCrs()) nPoints = 0 nIterations = 0 maxIterations = pointCount * 200 featureCount = source.featureCount() total = 100.0 / pointCount if pointCount else 1 index = QgsSpatialIndex() points = dict() da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) request = QgsFeatureRequest() random.seed() while nIterations < maxIterations and nPoints < pointCount: if feedback.isCanceled(): break # pick random feature fid = random.randint(0, featureCount - 1) f = next(source.getFeatures(request.setFilterFid(fid).setSubsetOfAttributes([]))) fGeom = f.geometry() if fGeom.isMultipart(): lines = fGeom.asMultiPolyline() # pick random line lineId = random.randint(0, len(lines) - 1) vertices = lines[lineId] else: vertices = fGeom.asPolyline() # pick random segment if len(vertices) == 2: vid = 0 else: vid = random.randint(0, len(vertices) - 2) startPoint = vertices[vid] endPoint = vertices[vid + 1] length = da.measureLine(startPoint, endPoint) dist = length * random.random() if dist > minDistance: d = dist / (length - dist) rx = (startPoint.x() + d * endPoint.x()) / (1 + d) ry = (startPoint.y() + d * endPoint.y()) / (1 + d) # generate random point p = QgsPointXY(rx, ry) geom = QgsGeometry.fromPointXY(p) if vector.checkMinDistance(p, index, minDistance, points): f = QgsFeature(nPoints) f.initAttributes(1) f.setFields(fields) f.setAttribute('id', nPoints) f.setGeometry(geom) sink.addFeature(f, QgsFeatureSink.FastInsert) index.insertFeature(f) points[nPoints] = p nPoints += 1 feedback.setProgress(int(nPoints * total)) nIterations += 1 if nPoints < pointCount: feedback.pushInfo(self.tr('Could not generate requested number of random points. ' 'Maximum number of attempts exceeded.')) return {self.OUTPUT: dest_id}
def processAlgorithm(self, parameters, context, feedback): layer = QgsProcessingUtils.mapLayerFromString( self.getParameterValue(self.VECTOR), context) groupField = self.getParameterValue(self.GROUP_FIELD) orderField = self.getParameterValue(self.ORDER_FIELD) dateFormat = str(self.getParameterValue(self.DATE_FORMAT)) #gap = int(self.getParameterValue(self.GAP_PERIOD)) dirName = self.getOutputValue(self.OUTPUT_TEXT) fields = QgsFields() fields.append(QgsField('group', QVariant.String, '', 254, 0)) fields.append(QgsField('begin', QVariant.String, '', 254, 0)) fields.append(QgsField('end', QVariant.String, '', 254, 0)) writer = self.getOutputFromName(self.OUTPUT_LINES).getVectorWriter( fields, QgsWkbTypes.LineString, layer.crs(), context) points = dict() features = QgsProcessingUtils.getFeatures(layer, context) total = 100.0 / layer.featureCount() if layer.featureCount() else 0 for current, f in enumerate(features): point = f.geometry().asPoint() group = f[groupField] order = f[orderField] if dateFormat != '': order = datetime.strptime(str(order), dateFormat) if group in points: points[group].append((order, point)) else: points[group] = [(order, point)] feedback.setProgress(int(current * total)) feedback.setProgress(0) da = QgsDistanceArea() da.setSourceCrs(layer.sourceCrs()) da.setEllipsoid(QgsProject.instance().ellipsoid()) current = 0 total = 100.0 / len(points) if points else 1 for group, vertices in list(points.items()): vertices.sort() f = QgsFeature() f.initAttributes(len(fields)) f.setFields(fields) f['group'] = group f['begin'] = vertices[0][0] f['end'] = vertices[-1][0] fileName = os.path.join(dirName, '%s.txt' % group) with open(fileName, 'w') as fl: fl.write('angle=Azimuth\n') fl.write('heading=Coordinate_System\n') fl.write('dist_units=Default\n') line = [] i = 0 for node in vertices: line.append(node[1]) if i == 0: fl.write('startAt=%f;%f;90\n' % (node[1].x(), node[1].y())) fl.write('survey=Polygonal\n') fl.write('[data]\n') else: angle = line[i - 1].azimuth(line[i]) distance = da.measureLine(line[i - 1], line[i]) fl.write('%f;%f;90\n' % (angle, distance)) i += 1 f.setGeometry(QgsGeometry.fromPolyline(line)) writer.addFeature(f, QgsFeatureSink.FastInsert) current += 1 feedback.setProgress(int(current * total)) del writer
def testLengthMeasureAndUnits(self): """Test a variety of length measurements in different CRS and ellipsoid modes, to check that the calculated lengths and units are always consistent """ da = QgsDistanceArea() da.setSourceCrs(3452) da.setEllipsoidalMode(False) da.setEllipsoid("NONE") # We check both the measured length AND the units, in case the logic regarding # ellipsoids and units changes in future distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) assert ((abs(distance - 2.23606797) < 0.00000001 and units == QgsUnitTypes.DistanceDegrees) or (abs(distance - 248.52) < 0.01 and units == QgsUnitTypes.DistanceMeters)) da.setEllipsoid("WGS84") distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) assert ((abs(distance - 2.23606797) < 0.00000001 and units == QgsUnitTypes.DistanceDegrees) or (abs(distance - 248.52) < 0.01 and units == QgsUnitTypes.DistanceMeters)) da.setEllipsoidalMode(True) distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) # should always be in Meters self.assertAlmostEqual(distance, 247555.57, delta=0.01) self.assertEqual(units, QgsUnitTypes.DistanceMeters) # test converting the resultant length distance = da.convertLengthMeasurement(distance, QgsUnitTypes.DistanceNauticalMiles) self.assertAlmostEqual(distance, 133.669, delta=0.01) # now try with a source CRS which is in feet da.setSourceCrs(27469) da.setEllipsoidalMode(False) # measurement should be in feet distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) self.assertAlmostEqual(distance, 2.23606797, delta=0.000001) self.assertEqual(units, QgsUnitTypes.DistanceFeet) # test converting the resultant length distance = da.convertLengthMeasurement(distance, QgsUnitTypes.DistanceMeters) self.assertAlmostEqual(distance, 0.6815, delta=0.001) da.setEllipsoidalMode(True) # now should be in Meters again distance = da.measureLine(QgsPoint(1, 1), QgsPoint(2, 3)) units = da.lengthUnits() print(("measured {} in {}".format(distance, QgsUnitTypes.toString(units)))) self.assertAlmostEqual(distance, 0.67953772, delta=0.000001) self.assertEqual(units, QgsUnitTypes.DistanceMeters) # test converting the resultant length distance = da.convertLengthMeasurement(distance, QgsUnitTypes.DistanceFeet) self.assertAlmostEqual(distance, 2.2294, delta=0.001)
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException(self.invalidSourceError(parameters, self.INPUT)) pointCount = self.parameterAsDouble(parameters, self.POINTS_NUMBER, context) minDistance = self.parameterAsDouble(parameters, self.MIN_DISTANCE, context) fields = QgsFields() fields.append(QgsField('id', QVariant.Int, '', 10, 0)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, QgsWkbTypes.Point, source.sourceCrs()) if sink is None: raise QgsProcessingException(self.invalidSinkError(parameters, self.OUTPUT)) nPoints = 0 nIterations = 0 maxIterations = pointCount * 200 featureCount = source.featureCount() total = 100.0 / pointCount if pointCount else 1 index = QgsSpatialIndex() points = dict() da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) request = QgsFeatureRequest() random.seed() while nIterations < maxIterations and nPoints < pointCount: if feedback.isCanceled(): break # pick random feature fid = random.randint(0, featureCount - 1) f = next(source.getFeatures(request.setFilterFid(fid).setSubsetOfAttributes([]))) fGeom = f.geometry() if fGeom.isMultipart(): lines = fGeom.asMultiPolyline() # pick random line lineId = random.randint(0, len(lines) - 1) vertices = lines[lineId] else: vertices = fGeom.asPolyline() # pick random segment if len(vertices) == 2: vid = 0 else: vid = random.randint(0, len(vertices) - 2) startPoint = vertices[vid] endPoint = vertices[vid + 1] length = da.measureLine(startPoint, endPoint) dist = length * random.random() if dist > minDistance: d = dist / (length - dist) rx = (startPoint.x() + d * endPoint.x()) / (1 + d) ry = (startPoint.y() + d * endPoint.y()) / (1 + d) # generate random point p = QgsPointXY(rx, ry) geom = QgsGeometry.fromPointXY(p) if vector.checkMinDistance(p, index, minDistance, points): f = QgsFeature(nPoints) f.initAttributes(1) f.setFields(fields) f.setAttribute('id', nPoints) f.setGeometry(geom) sink.addFeature(f, QgsFeatureSink.FastInsert) index.addFeature(f) points[nPoints] = p nPoints += 1 feedback.setProgress(int(nPoints * total)) nIterations += 1 if nPoints < pointCount: feedback.pushInfo(self.tr('Could not generate requested number of random points. ' 'Maximum number of attempts exceeded.')) return {self.OUTPUT: dest_id}
def processAlgorithm(self, progress): layer = self.getParameterValue(self.INPUT_LAYER) mapping = self.getParameterValue(self.FIELDS_MAPPING) output = self.getOutputFromName(self.OUTPUT_LAYER) layer = dataobjects.getObjectFromUri(layer) fields = [] expressions = [] da = QgsDistanceArea() da.setSourceCrs(layer.crs().srsid()) da.setEllipsoidalMode( iface.mapCanvas().mapSettings().hasCrsTransformEnabled()) da.setEllipsoid(QgsProject.instance().readEntry( 'Measure', '/Ellipsoid', GEO_NONE)[0]) exp_context = QgsExpressionContext() exp_context.appendScope(QgsExpressionContextUtils.globalScope()) exp_context.appendScope(QgsExpressionContextUtils.projectScope()) exp_context.appendScope(QgsExpressionContextUtils.layerScope(layer)) for field_def in mapping: fields.append( QgsField(name=field_def['name'], type=field_def['type'], len=field_def['length'], prec=field_def['precision'])) expression = QgsExpression(field_def['expression']) expression.setGeomCalculator(da) expression.setDistanceUnits(QgsProject.instance().distanceUnits()) expression.setAreaUnits(QgsProject.instance().areaUnits()) if expression.hasParserError(): raise GeoAlgorithmExecutionException( self.tr(u'Parser error in expression "{}": {}').format( str(field_def['expression']), str(expression.parserErrorString()))) expression.prepare(exp_context) if expression.hasEvalError(): raise GeoAlgorithmExecutionException( self.tr(u'Evaluation error in expression "{}": {}').format( str(field_def['expression']), str(expression.evalErrorString()))) expressions.append(expression) writer = output.getVectorWriter(fields, layer.wkbType(), layer.crs()) # Create output vector layer with new attributes error = '' calculationSuccess = True inFeat = QgsFeature() outFeat = QgsFeature() features = vector.features(layer) total = 100.0 / len(features) for current, inFeat in enumerate(features): rownum = current + 1 geometry = inFeat.geometry() outFeat.setGeometry(geometry) attrs = [] for i in range(0, len(mapping)): field_def = mapping[i] expression = expressions[i] exp_context.setFeature(inFeat) exp_context.lastScope().setVariable("row_number", rownum) value = expression.evaluate(exp_context) if expression.hasEvalError(): calculationSuccess = False error = expression.evalErrorString() break attrs.append(value) outFeat.setAttributes(attrs) writer.addFeature(outFeat) progress.setPercentage(int(current * total)) del writer if not calculationSuccess: raise GeoAlgorithmExecutionException( self.tr('An error occurred while evaluating the calculation' ' string:\n') + error)
def processAlgorithm(self, parameters, context, feedback): source = self.parameterAsSource(parameters, self.INPUT, context) if source is None: raise QgsProcessingException(self.invalidSourceError(parameters, self.INPUT)) layer = self.parameterAsVectorLayer(parameters, self.INPUT, context) field_name = self.parameterAsString(parameters, self.FIELD_NAME, context) field_type = self.TYPES[self.parameterAsEnum(parameters, self.FIELD_TYPE, context)] width = self.parameterAsInt(parameters, self.FIELD_LENGTH, context) precision = self.parameterAsInt(parameters, self.FIELD_PRECISION, context) new_field = self.parameterAsBool(parameters, self.NEW_FIELD, context) formula = self.parameterAsString(parameters, self.FORMULA, context) expression = QgsExpression(formula) da = QgsDistanceArea() da.setSourceCrs(source.sourceCrs(), context.transformContext()) da.setEllipsoid(context.project().ellipsoid()) expression.setGeomCalculator(da) expression.setDistanceUnits(context.project().distanceUnits()) expression.setAreaUnits(context.project().areaUnits()) fields = source.fields() field_index = fields.lookupField(field_name) if new_field or field_index < 0: fields.append(QgsField(field_name, field_type, '', width, precision)) (sink, dest_id) = self.parameterAsSink(parameters, self.OUTPUT, context, fields, source.wkbType(), source.sourceCrs()) if sink is None: raise QgsProcessingException(self.invalidSinkError(parameters, self.OUTPUT)) exp_context = self.createExpressionContext(parameters, context) if layer is not None: exp_context.appendScope(QgsExpressionContextUtils.layerScope(layer)) expression.prepare(exp_context) features = source.getFeatures() total = 100.0 / source.featureCount() if source.featureCount() else 0 for current, f in enumerate(features): if feedback.isCanceled(): break rownum = current + 1 exp_context.setFeature(f) exp_context.lastScope().setVariable("row_number", rownum) value = expression.evaluate(exp_context) if expression.hasEvalError(): feedback.reportError(expression.evalErrorString()) else: attrs = f.attributes() if new_field or field_index < 0: attrs.append(value) else: attrs[field_index] = value f.setAttributes(attrs) sink.addFeature(f, QgsFeatureSink.FastInsert) feedback.setProgress(int(current * total)) return {self.OUTPUT: dest_id}
def testAreaMeasureAndUnits(self): """Test a variety of area measurements in different CRS and ellipsoid modes, to check that the calculated areas and units are always consistent """ da = QgsDistanceArea() da.setSourceCrs(QgsCoordinateReferenceSystem.fromSrsId(3452), QgsProject.instance().transformContext()) da.setEllipsoid("NONE") polygon = QgsGeometry.fromPolygonXY( [[ QgsPointXY(0, 0), QgsPointXY(1, 0), QgsPointXY(1, 1), QgsPointXY(2, 1), QgsPointXY(2, 2), QgsPointXY(0, 2), QgsPointXY(0, 0), ]] ) # We check both the measured area AND the units, in case the logic regarding # ellipsoids and units changes in future area = da.measureArea(polygon) units = da.areaUnits() print(("measured {} in {}".format(area, QgsUnitTypes.toString(units)))) assert ((abs(area - 3.0) < 0.00000001 and units == QgsUnitTypes.AreaSquareDegrees) or (abs(area - 37176087091.5) < 0.1 and units == QgsUnitTypes.AreaSquareMeters)) da.setEllipsoid("WGS84") area = da.measureArea(polygon) units = da.areaUnits() print(("measured {} in {}".format(area, QgsUnitTypes.toString(units)))) # should always be in Meters Squared self.assertAlmostEqual(area, 37416879192.9, delta=0.1) self.assertEqual(units, QgsUnitTypes.AreaSquareMeters) # test converting the resultant area area = da.convertAreaMeasurement(area, QgsUnitTypes.AreaSquareMiles) self.assertAlmostEqual(area, 14446.7378, delta=0.001) # now try with a source CRS which is in feet polygon = QgsGeometry.fromPolygonXY( [[ QgsPointXY(1850000, 4423000), QgsPointXY(1851000, 4423000), QgsPointXY(1851000, 4424000), QgsPointXY(1852000, 4424000), QgsPointXY(1852000, 4425000), QgsPointXY(1851000, 4425000), QgsPointXY(1850000, 4423000) ]] ) da.setSourceCrs(QgsCoordinateReferenceSystem.fromSrsId(27469), QgsProject.instance().transformContext()) da.setEllipsoid("NONE") # measurement should be in square feet area = da.measureArea(polygon) units = da.areaUnits() print(("measured {} in {}".format(area, QgsUnitTypes.toString(units)))) self.assertAlmostEqual(area, 2000000, delta=0.001) self.assertEqual(units, QgsUnitTypes.AreaSquareFeet) # test converting the resultant area area = da.convertAreaMeasurement(area, QgsUnitTypes.AreaSquareYards) self.assertAlmostEqual(area, 222222.2222, delta=0.001) da.setEllipsoid("WGS84") # now should be in Square Meters again area = da.measureArea(polygon) units = da.areaUnits() print(("measured {} in {}".format(area, QgsUnitTypes.toString(units)))) self.assertAlmostEqual(area, 184149.37, delta=1.0) self.assertEqual(units, QgsUnitTypes.AreaSquareMeters) # test converting the resultant area area = da.convertAreaMeasurement(area, QgsUnitTypes.AreaSquareYards) self.assertAlmostEqual(area, 220240.8172549, delta=1.0)