def getClickBbox(self, thePoint):
"""
Get a tiny bbox around a mouse click.
Args:
Point object.
Returns:
Tiny QgsRectangle bbox around point.
Raises:
CoordinateProcessingException if bbox creation encounters error.
"""
# get the xy coords
#QMessageBox.information(None, 'VF', str(thePoint))
myX = thePoint.x()
myY = thePoint.y()
myUnitsPerPixel = self.canvas.mapUnitsPerPixel()
# create a little bbox from clicked coords
try:
myBbox = QgsRectangle()
myBbox.setXMinimum(myX - myUnitsPerPixel)
myBbox.setYMinimum(myY - myUnitsPerPixel)
myBbox.setXMaximum(myX + myUnitsPerPixel)
myBbox.setYMaximum(myY + myUnitsPerPixel)
#QMessageBox.information(None, 'VF', myBbox.toString())
return myBbox
except:
msg = 'Click coordinates could not be processed.'
raise ex.CoordinateProcessingException(msg)
def canvasReleaseEvent(self, e):
super(MapToolInteractive, self).canvasReleaseEvent(e)
e.ignore()
if (e.button() == Qt.LeftButton):
if self._dragging:
# Pan map mode
self.canvas().panActionEnd(e.pos())
self.setCursor(CapturePointCursor)
self._dragging = False
e.accept()
elif (e.button() == Qt.RightButton):
if self._dragging:
# Zoom mode
self._zoomRect.setBottomRight(e.pos())
if (self._zoomRect.topLeft() != self._zoomRect.bottomRight()):
coordinateTransform = self.canvas().getCoordinateTransform(
)
ll = coordinateTransform.toMapCoordinates(
self._zoomRect.left(), self._zoomRect.bottom())
ur = coordinateTransform.toMapCoordinates(
self._zoomRect.right(), self._zoomRect.top())
r = QgsRectangle()
r.setXMinimum(ll.x())
r.setYMinimum(ll.y())
r.setXMaximum(ur.x())
r.setYMaximum(ur.y())
r.normalize()
if (r.width() != 0 and r.height() != 0):
self.canvas().setExtent(r)
self.canvas().refresh()
self._dragging = False
if (self._zoomRubberBand is not None):
self.canvas().scene().removeItem(self._zoomRubberBand)
self._zoomRubberBand = None
e.accept()
def _getFeatures(self):
"""Identify objects under the mouse, having actions"""
searchRadius = self.searchRadiusMU(self.canvas)
point = self.toMapCoordinates(self.__pos)
features = []
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
for layer in self.canvas.layers():
# treat only vector layers having actions
if (layer.type() == QgsMapLayer.VectorLayer
and len(layer.actions().actions()) > 0):
layerRect = self.toLayerCoordinates(layer, rect)
self.request.setFilterRect(layerRect)
for feature in layer.getFeatures(layerRect if (
layer.dataProvider().name() == "WFS"
) else self.request):
features.append({"layer": layer, "feature": feature})
return features
def getClickBbox(self, thePoint):
"""
Get a tiny bbox around a mouse click.
Args:
Point object.
Returns:
Tiny QgsRectangle bbox around point.
Raises:
CoordinateProcessingException if bbox creation encounters error.
"""
# get the xy coords
#QMessageBox.information(None, 'VF', str(thePoint))
myX = thePoint.x()
myY = thePoint.y()
myUnitsPerPixel = self.canvas.mapUnitsPerPixel()
# create a little bbox from clicked coords
try:
myBbox = QgsRectangle()
myBbox.setXMinimum(myX - myUnitsPerPixel)
myBbox.setYMinimum(myY - myUnitsPerPixel)
myBbox.setXMaximum(myX + myUnitsPerPixel)
myBbox.setYMaximum(myY + myUnitsPerPixel)
#QMessageBox.information(None, 'VF', myBbox.toString())
return myBbox
except:
msg = 'Click coordinates could not be processed.'
raise ex.CoordinateProcessingException(msg)
def withinBoundary(layer, point, featureId, closestFeature):
# find the furthest bounding box borders
closestFeature = layer.getFeatures(QgsFeatureRequest(featureId)).next()
rect = closestFeature.geometry().boundingBox()
dist_pX_rXmax = abs(point.x() - rect.xMaximum())
dist_pX_rXmin = abs(point.x() - rect.xMinimum())
if dist_pX_rXmax > dist_pX_rXmin:
width = dist_pX_rXmax
else:
width = dist_pX_rXmin
dist_pY_rYmax = abs(point.y() - rect.yMaximum())
dist_pY_rYmin = abs(point.y() - rect.yMinimum())
if dist_pY_rYmax > dist_pY_rYmin:
height = dist_pY_rYmax
else:
height = dist_pY_rYmin
# create the search rectangle
rect = QgsRectangle()
rect.setXMinimum(point.x() - width)
rect.setXMaximum(point.x() + width)
rect.setYMinimum(point.y() - height)
rect.setYMaximum(point.y() + height)
# retrieve all geometries into the search rectangle
iter2 = layer.getFeatures(QgsFeatureRequest(rect))
# find the nearest feature
minDist = -1
featureId = None
point = QgsGeometry.fromPointXY(point)
f = QgsFeature()
while iter2.nextFeature(f):
geom = f.geometry()
distance = geom.distance(point)
if minDist < 0 or distance < minDist:
minDist = distance
featureId = f.id()
# get the closest feature
try:
closestFeature = layer.getFeatures(QgsFeatureRequest(featureId)).next()
if featureId is None or layer.getFeatures(
QgsFeatureRequest(featureId)).next(f) is False:
closestFeature = None
except:
f = QgsFeature()
closestFeature = layer.getFeatures(
QgsFeatureRequest(featureId)).nextFeature(f)
closestFeature = f
if featureId is None or layer.getFeatures(
QgsFeatureRequest(featureId)).nextFeature(f) is False:
closestFeature = None
return closestFeature
def toSearchRect(self, point):
searchRadius = self.canvas.extent().width() * (self.radius / 100.0)
point = self.toMapCoordinates(point)
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
return rect
def toSearchRect(self, point):
searchRadius = self.canvas.extent().width() * ( self.radius / 100.0 )
point = self.toMapCoordinates(point)
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
return rect
def canvasReleaseEvent(self, event):
searchRadius = (QgsTolerance.toleranceInMapUnits(
5, self.layerfrom,
self.canvas().mapRenderer(), QgsTolerance.Pixels))
point = self.toMapCoordinates(event.pos())
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
rq = QgsFeatureRequest().setFilterRect(rect)
try:
# Only supports the first feature
# TODO build picker to select which feature to inspect
feature = self.layerfrom.getFeatures(rq).next()
self.band.setToGeometry(feature.geometry(), self.layerfrom)
fields = self.layerto.pendingFields()
newfeature = QgsFeature(fields)
if self.layerto.geometryType() == QGis.Point:
newfeature.setGeometry(QgsGeometry.fromPoint(point))
else:
newfeature.setGeometry(QgsGeometry(feature.geometry()))
#Set the default values
for indx in xrange(fields.count()):
newfeature[indx] = self.layerto.dataProvider().defaultValue(
indx)
# Assign the old values to the new feature
for fieldfrom, fieldto in self.fields.iteritems():
newfeature[fieldto] = feature[fieldfrom]
passed, message = self.validation_method(feature=newfeature,
layerto=self.layerto)
if passed:
self.finished.emit(self.layerto, newfeature)
else:
self.band.reset()
self.error.emit(message)
except StopIteration:
pass
def canvasReleaseEvent(self, event):
searchRadius = (QgsTolerance.toleranceInMapUnits( 5, self.layerfrom,
self.canvas().mapRenderer(), QgsTolerance.Pixels))
point = self.toMapCoordinates(event.pos())
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
rq = QgsFeatureRequest().setFilterRect(rect)
# Look for an existing feature first. If there is one
# then we emit that back to qmap.
try:
feature = self.layerto.getFeatures(rq).next()
self.band.setToGeometry(feature.geometry(), self.layerto)
self.finished.emit(self.layerto, feature)
return
except StopIteration:
pass
try:
# Only supports the first feature
# TODO build picker to select which feature to inspect
feature = self.layerfrom.getFeatures(rq).next()
self.band.setToGeometry(feature.geometry(), self.layerfrom)
fields = self.layerto.pendingFields()
newfeature = QgsFeature(fields)
newfeature.setGeometry(QgsGeometry(feature.geometry()))
#Set the default values
for indx in xrange(fields.count()):
newfeature[indx] = self.layerto.dataProvider().defaultValue( indx )
# Assign the old values to the new feature
for fieldfrom, fieldto in self.fields.iteritems():
newfeature[fieldto] = feature[fieldfrom]
self.finished.emit(self.layerto, newfeature)
except StopIteration:
pass
def canvasReleaseEvent(self, event):
searchRadius = (QgsTolerance.toleranceInMapUnits(
5, self.layerfrom,
self.canvas().mapRenderer(), QgsTolerance.Pixels))
point = self.toMapCoordinates(event.pos())
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
rq = QgsFeatureRequest().setFilterRect(rect)
# Look for an existing feature first. If there is one
# then we emit that back to qmap.
try:
feature = self.layerto.getFeatures(rq).next()
self.band.setToGeometry(feature.geometry(), self.layerto)
self.finished.emit(self.layerto, feature)
return
except StopIteration:
pass
try:
# Only supports the first feature
# TODO build picker to select which feature to inspect
feature = self.layerfrom.getFeatures(rq).next()
self.band.setToGeometry(feature.geometry(), self.layerfrom)
fields = self.layerto.pendingFields()
newfeature = QgsFeature(fields)
newfeature.setGeometry(QgsGeometry(feature.geometry()))
#Set the default values
for indx in xrange(fields.count()):
newfeature[indx] = self.layerto.dataProvider().defaultValue(
indx)
# Assign the old values to the new feature
for fieldfrom, fieldto in self.fields.iteritems():
newfeature[fieldto] = feature[fieldfrom]
self.finished.emit(self.layerto, newfeature)
except StopIteration:
pass
def canvasReleaseEvent(self, event):
searchRadius = (QgsTolerance.toleranceInMapUnits( 5, self.layerfrom,
self.canvas().mapRenderer(), QgsTolerance.Pixels))
point = self.toMapCoordinates(event.pos())
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
rq = QgsFeatureRequest().setFilterRect(rect)
try:
# Only supports the first feature
# TODO build picker to select which feature to inspect
feature = self.layerfrom.getFeatures(rq).next()
self.band.setToGeometry(feature.geometry(), self.layerfrom)
fields = self.layerto.pendingFields()
newfeature = QgsFeature(fields)
if self.layerto.geometryType() == QGis.Point:
newfeature.setGeometry(QgsGeometry.fromPoint(point))
else:
newfeature.setGeometry(QgsGeometry(feature.geometry()))
#Set the default values
for indx in xrange(fields.count()):
newfeature[indx] = self.layerto.dataProvider().defaultValue( indx )
# Assign the old values to the new feature
for fieldfrom, fieldto in self.fields.iteritems():
newfeature[fieldto] = feature[fieldfrom]
passed, message = self.validation_method(feature=newfeature,
layerto=self.layerto)
if passed:
self.finished.emit(self.layerto, newfeature)
else:
self.band.reset()
self.error.emit(message)
except StopIteration:
pass
def canvasPressEvent(self, e):
layer = config.iface.activeLayer()
if layer is None or not isinstance(layer, QgsVectorLayer):
config.iface.messageBar().pushMessage("No layer selected or the current active layer is not a valid vector layer",
level = QgsMessageBar.WARNING, duration = 5)
return
if not layertracking.isRepoLayer(layer):
config.iface.messageBar().pushMessage("The current active layer is not being tracked as part of a GeoGig repo",
level = QgsMessageBar.WARNING, duration = 5)
return
trackedlayer = layertracking.getTrackingInfo(layer)
point = self.toMapCoordinates(e.pos())
searchRadius = self.canvas().extent().width() * .01;
r = QgsRectangle()
r.setXMinimum(point.x() - searchRadius);
r.setXMaximum(point.x() + searchRadius);
r.setYMinimum(point.y() - searchRadius);
r.setYMaximum(point.y() + searchRadius);
r = self.toLayerCoordinates(layer, r);
fit = layer.getFeatures(QgsFeatureRequest().setFilterRect(r).setFlags(QgsFeatureRequest.ExactIntersect));
fid = None
try:
feature = next(fit)
fid = feature.id()
fid = geogigFidFromGpkgFid(trackedlayer, fid)
if fid is None:
return
except StopIteration as e:
return
repo = Repository(trackedlayer.repoUrl)
menu = QMenu()
versionsAction = QAction("Show all versions of this feature...", None)
versionsAction.triggered.connect(lambda: self.versions(repo, trackedlayer.layername, fid))
menu.addAction(versionsAction)
blameAction = QAction("Show authorship...", None)
blameAction.triggered.connect(lambda: self.blame(repo, trackedlayer.layername, fid))
menu.addAction(blameAction)
point = config.iface.mapCanvas().mapToGlobal(e.pos())
menu.exec_(point)
def getFeatures(self, point):
searchRadius = (QgsTolerance.toleranceInMapUnits( self.radius, self.layers[0],
self.canvas.mapRenderer(),
QgsTolerance.Pixels))
point = self.toMapCoordinates(point)
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
rq = QgsFeatureRequest().setFilterRect(rect)
self.band.reset()
for layer in self.layers:
rq = QgsFeatureRequest().setFilterRect(rect)
for feature in layer.getFeatures(rq):
if feature.isValid():
yield feature, layer
def getFeatures(self, point):
searchRadius = (QgsTolerance.toleranceInMapUnits(
self.radius, self.layers[0], self.canvas.mapRenderer(),
QgsTolerance.Pixels))
point = self.toMapCoordinates(point)
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
rq = QgsFeatureRequest().setFilterRect(rect)
self.band.reset()
for layer in self.layers:
rq = QgsFeatureRequest().setFilterRect(rect)
for feature in layer.getFeatures(rq):
if feature.isValid():
yield feature, layer
def canvasPressEvent(self, event):
"""
Override of QgsMapTool mouse press event
"""
if event.button() == Qt.LeftButton and not self.mCtrl:
if self.band:
self.band.hide()
self.band = None
self.feature = None
logger.info("layer feature count {}".format(self.layer.featureCount()))
if not self.layer:
return
logger.info("Trying to find feature in layer")
point = self.toLayerCoordinates(self.layer, event.pos())
search_radius = (QgsTolerance.toleranceInMapUnits(10, self.layer,
self.canvas().mapSettings(), QgsTolerance.Pixels))
rect = QgsRectangle()
rect.setXMinimum(point.x() - search_radius)
rect.setXMaximum(point.x() + search_radius)
rect.setYMinimum(point.y() - search_radius)
rect.setYMaximum(point.y() + search_radius)
rq = QgsFeatureRequest().setFilterRect(rect)
f = QgsFeature()
self.layer.getFeatures(rq).nextFeature(f)
if f.geometry():
self.band = self.create_rubber_band()
self.band.setToGeometry(f.geometry(), self.layer)
self.band.show()
self.startcoord = self.toMapCoordinates(event.pos())
self.feature = f
self.clicked_outside_layer = False
return
else:
self.clicked_outside_layer = True
def _getFeatures(self):
"""Identify objects under the mouse, having actions
"""
searchRadius = self.searchRadiusMU(self.canvas)
point = self.toMapCoordinates(self.__pos)
features = []
rect = QgsRectangle()
rect.setXMinimum(point.x() - searchRadius)
rect.setXMaximum(point.x() + searchRadius)
rect.setYMinimum(point.y() - searchRadius)
rect.setYMaximum(point.y() + searchRadius)
for layer in self.canvas.layers():
# treat only vector layers having actions
if layer.type() == QgsMapLayer.VectorLayer and len(layer.actions().actions()) > 0:
self.request.setFilterRect(self.toLayerCoordinates(layer, rect))
for feature in layer.getFeatures(self.request):
features.append({"layer":layer, "feature":feature})
return features
def canvasPressEvent(self, e):
layer = iface.activeLayer()
if layer is None or not isinstance(layer, QgsVectorLayer):
iface.messageBar().pushMessage(
"No layer selected or the current active layer is not a valid vector layer",
level=Qgis.Warning,
duration=5)
return
geogiglayer = getWrappingGeogigLayer(layer)
if geogiglayer is None:
iface.messageBar().pushMessage(
"The current active layer is not being tracked as part of a GeoGig repo",
level=Qgis.Warning,
duration=5)
return
point = self.toMapCoordinates(e.pos())
searchRadius = self.canvas().extent().width() * .01
r = QgsRectangle()
r.setXMinimum(point.x() - searchRadius)
r.setXMaximum(point.x() + searchRadius)
r.setYMinimum(point.y() - searchRadius)
r.setYMaximum(point.y() + searchRadius)
r = self.toLayerCoordinates(layer, r)
fit = layer.getFeatures(QgsFeatureRequest().setFilterRect(r).setFlags(
QgsFeatureRequest.ExactIntersect))
fid = None
try:
feature = next(fit)
fid = feature[GEOGIGID_FIELD]
if fid is None:
return
except StopIteration as e:
return
self.versions(geogiglayer, fid)
def show_tip(self, point):
rectangle = QgsRectangle()
radius = self.canvas.extent().width() / 100 * 5 # 5% of the map width
rectangle.setXMinimum(point.x() - radius)
rectangle.setYMinimum(point.y() - radius)
rectangle.setXMaximum(point.x() + radius)
rectangle.setYMaximum(point.y() + radius)
layer_rectangle = self.canvas.mapRenderer().mapToLayerCoordinates(
self.catalogue_layer, rectangle)
features = self.catalogue_layer.getFeatures(
QgsFeatureRequest().setFilterRect(layer_rectangle))
# assume the first one is the closest
try:
feat = features.next()
msg_lines = ["Event Found"]
for k in self.catalogue_model.catalogue_keys():
msg_lines.append("%s=%s" % (k, feat[k]))
except StopIteration:
msg_lines = ["No Event found"]
if self.raster_layer is not None:
src = self.basemap_layer.crs()
dst = QgsCoordinateReferenceSystem(4326)
trans = QgsCoordinateTransform(src, dst)
point = trans.transform(point)
raster_data = self.raster_layer.dataProvider().identify(
point, QgsRaster.IdentifyFormatValue)
for k, v in raster_data.results().items():
msg_lines.append("Smoothed=%s" % str(v))
utils.alert('\n'.join(msg_lines))
def run(bar, layer1_path, layer2_path, obstacles_path, research_ray):
output = {}
#layer1 receiver
layer1 = QgsVectorLayer(layer1_path, "layer1", "ogr")
#layer 2 source
layer2 = QgsVectorLayer(layer2_path, "layer2", "ogr")
layer2_feat_all_dict = {}
layer2_feat_all = layer2.dataProvider().getFeatures()
layer2_spIndex = QgsSpatialIndex()
for layer2_feat in layer2_feat_all:
layer2_spIndex.insertFeature(layer2_feat)
layer2_feat_all_dict[layer2_feat.id()] = layer2_feat
if obstacles_path is not None:
obstacles_layer = QgsVectorLayer(obstacles_path, "obstacles", "ogr")
obstacles_feat_all = obstacles_layer.dataProvider().getFeatures()
obstacles_spIndex = QgsSpatialIndex()
obstacles_feat_all_dict = {}
for obstacles_feat in obstacles_feat_all:
obstacles_spIndex.insertFeature(obstacles_feat)
obstacles_feat_all_dict[obstacles_feat.id()] = obstacles_feat
layer1_feat_all = layer1.dataProvider().getFeatures()
layer1_feat_total = layer1.dataProvider().featureCount()
layer1_feat_number = 0
for layer1_feat in layer1_feat_all:
layer1_feat_number = layer1_feat_number + 1
barValue = layer1_feat_number / float(layer1_feat_total) * 100
bar.setValue(barValue)
# researches the layer2 points in a rectangle created by the research_ray
# creates the search rectangle
rect = QgsRectangle()
rect.setXMinimum(layer1_feat.geometry().asPoint().x() - research_ray)
rect.setXMaximum(layer1_feat.geometry().asPoint().x() + research_ray)
rect.setYMinimum(layer1_feat.geometry().asPoint().y() - research_ray)
rect.setYMaximum(layer1_feat.geometry().asPoint().y() + research_ray)
layer2_request = layer2_spIndex.intersects(rect)
layer2_points = []
for layer2_id in layer2_request:
layer2_feat = layer2_feat_all_dict[layer2_id]
ray_to_test_length = compute_distance(
layer1_feat.geometry().asPoint(),
layer2_feat.geometry().asPoint())
if ray_to_test_length <= research_ray:
ray_to_test = QgsGeometry.fromPolylineXY([
layer1_feat.geometry().asPoint(),
layer2_feat.geometry().asPoint()
])
intersect = 0
if obstacles_path is not None:
obstacles_request = obstacles_spIndex.intersects(
ray_to_test.boundingBox())
for obstacles_id in obstacles_request:
if obstacles_feat_all_dict[obstacles_id].geometry(
).crosses(ray_to_test) == 1:
intersect = 1
break
if intersect == 0:
layer2_points.append(layer2_feat.id())
output[layer1_feat.id()] = layer2_points
return output
def run_selection_distance(bar, layer1_path, layer2_path, obstacles_path,
research_ray, dict_selection_layer2TOlayer3,
layer3_path):
'''runs only in the selection dict and check the distance also with the selection dict rays'''
output = {}
layer1 = QgsVectorLayer(layer1_path, "layer1", "ogr")
layer2 = QgsVectorLayer(layer2_path, "layer2", "ogr")
layer2_feat_all_dict = {}
layer2_feat_all = layer2.dataProvider().getFeatures()
layer2_spIndex = QgsSpatialIndex()
for layer2_feat in layer2_feat_all:
layer2_spIndex.insertFeature(layer2_feat)
layer2_feat_all_dict[layer2_feat.id()] = layer2_feat
if obstacles_path is not None:
obstacles_layer = QgsVectorLayer(obstacles_path, "obstacles", "ogr")
obstacles_feat_all = obstacles_layer.dataProvider().getFeatures()
obstacles_spIndex = QgsSpatialIndex()
obstacles_feat_all_dict = {}
for obstacles_feat in obstacles_feat_all:
obstacles_spIndex.insertFeature(obstacles_feat)
obstacles_feat_all_dict[obstacles_feat.id()] = obstacles_feat
layer3 = QgsVectorLayer(layer3_path, "layer3", "ogr")
layer3_feat_all = layer3.dataProvider().getFeatures()
layer3_feat_all_dict = {}
for layer3_feat in layer3_feat_all:
layer3_feat_all_dict[layer3_feat.id()] = layer3_feat
layer1_feat_all = layer1.dataProvider().getFeatures()
layer1_feat_total = layer1.dataProvider().featureCount()
layer1_feat_number = 0
for layer1_feat in layer1_feat_all:
layer1_feat_number = layer1_feat_number + 1
barValue = layer1_feat_number / float(layer1_feat_total) * 100
bar.setValue(barValue)
# researches the layer2 points in a rectangle created by the research_ray
# creates the search rectangle
rect = QgsRectangle()
rect.setXMinimum(layer1_feat.geometry().asPoint().x() - research_ray)
rect.setXMaximum(layer1_feat.geometry().asPoint().x() + research_ray)
rect.setYMinimum(layer1_feat.geometry().asPoint().y() - research_ray)
rect.setYMaximum(layer1_feat.geometry().asPoint().y() + research_ray)
layer2_request = layer2_spIndex.intersects(rect)
layer2_points = []
for layer2_id in layer2_request:
if layer2_id in dict_selection_layer2TOlayer3:
layer2_feat = layer2_feat_all_dict[layer2_id]
ray_to_test_length = compute_distance(
layer1_feat.geometry().asPoint(),
layer2_feat.geometry().asPoint())
distance_layer2_layer3 = []
min_distance_layer2_layer3 = research_ray
for layer3_id in dict_selection_layer2TOlayer3[layer2_id]:
layer3_feat = layer3_feat_all_dict[layer3_id]
ray_layer2_layer3 = compute_distance(
layer2_feat.geometry().asPoint(),
layer3_feat.geometry().asPoint())
if ray_layer2_layer3 < min_distance_layer2_layer3:
min_distance_layer2_layer3 = ray_layer2_layer3
if min_distance_layer2_layer3 + ray_to_test_length <= research_ray:
ray_to_test = QgsGeometry.fromPolyline([
layer1_feat.geometry().asPoint(),
layer2_feat.geometry().asPoint()
])
intersect = 0
if obstacles_path is not None:
obstacles_request = obstacles_spIndex.intersects(
ray_to_test.boundingBox())
for obstacles_id in obstacles_request:
if obstacles_feat_all_dict[obstacles_id].geometry(
).crosses(ray_to_test) == 1:
intersect = 1
break
if intersect == 0:
layer2_points.append(layer2_feat.id())
output[layer1_feat.id()] = layer2_points
return output
def findAtPoint(self, layer, point, canvas, onlyTheClosestOne=True, onlyIds=False): QApplication.setOverrideCursor(QCursor(Qt.WaitCursor)) # recupera il valore del raggio di ricerca settings = QgsSettings() radius = settings.value( "/Map/searchRadiusMM", Qgis.DEFAULT_SEARCH_RADIUS_MM, type=float) if radius <= 0: radius = Qgis.DEFAULT_SEARCH_RADIUS_MM radius = canvas.extent().width() * radius/100 # crea il rettangolo da usare per la ricerca rect = QgsRectangle() rect.setXMinimum(point.x() - radius) rect.setXMaximum(point.x() + radius) rect.setYMinimum(point.y() - radius) rect.setYMaximum(point.y() + radius) rect = canvas.mapSettings().mapToLayerCoordinates(layer, rect) # recupera le feature che intersecano il rettangolo ret = None if onlyTheClosestOne: request=QgsFeatureRequest() request.setFilterRect(rect) minDist = -1 featureId = None rect = QgsGeometry.fromRect(rect) count = 0 for f in layer.getFeatures(request): if onlyTheClosestOne: geom = f.geometry() distance = geom.distance(rect) if minDist < 0 or distance < minDist: minDist = distance featureId = f.id() if onlyIds: ret = featureId elif featureId != None: f = QgsFeature() feats = layer.getFeature( QgsFeatureRequest(featureId) ) feats.nextFeature(f) ret = f else: IDs = [] for f in layer.getFeatures(): IDs.append( f.id() ) if onlyIds: ret = IDs else: ret = [] request = QgsFeatureRequest() QgsFeatureRequest.setFilterFids(IDs) for f in layer.getFeatures( request ): ret.append( f ) QApplication.restoreOverrideCursor() return ret
def findAtPoint(self,
layer,
point,
canvas,
onlyTheClosestOne=True,
onlyIds=False):
QApplication.setOverrideCursor(QCursor(Qt.WaitCursor))
# recupera il valore del raggio di ricerca
settings = QgsSettings()
radius = settings.value("/Map/searchRadiusMM",
Qgis.DEFAULT_SEARCH_RADIUS_MM,
type=float)
if radius <= 0:
radius = Qgis.DEFAULT_SEARCH_RADIUS_MM
radius = canvas.extent().width() * radius / 100
# crea il rettangolo da usare per la ricerca
rect = QgsRectangle()
rect.setXMinimum(point.x() - radius)
rect.setXMaximum(point.x() + radius)
rect.setYMinimum(point.y() - radius)
rect.setYMaximum(point.y() + radius)
rect = canvas.mapSettings().mapToLayerCoordinates(layer, rect)
# recupera le feature che intersecano il rettangolo
ret = None
if onlyTheClosestOne:
request = QgsFeatureRequest()
request.setFilterRect(rect)
minDist = -1
featureId = None
rect = QgsGeometry.fromRect(rect)
count = 0
for f in layer.getFeatures(request):
if onlyTheClosestOne:
geom = f.geometry()
distance = geom.distance(rect)
if minDist < 0 or distance < minDist:
minDist = distance
featureId = f.id()
if onlyIds:
ret = featureId
elif featureId != None:
f = QgsFeature()
feats = layer.getFeature(QgsFeatureRequest(featureId))
feats.nextFeature(f)
ret = f
else:
IDs = []
for f in layer.getFeatures():
IDs.append(f.id())
if onlyIds:
ret = IDs
else:
ret = []
request = QgsFeatureRequest()
QgsFeatureRequest.setFilterFids(IDs)
for f in layer.getFeatures(request):
ret.append(f)
QApplication.restoreOverrideCursor()
return ret
def identifyLayer(self, point):
self.results[:] = []
if not self.layer.hasGeometryType():
return False
if (self.layer.hasScaleBasedVisibility() and
(self.layer.minimumScale() > self.canvas.mapSettings().scale() or
self.layer.maximumScale() <= self.canvas.mapSettings().scale())):
print 'Out of scale limits'
return False
QApplication.setOverrideCursor(Qt.WaitCursor)
featureCount = 0
featureList = []
try:
searchRadius = self.searchRadiusMU(self.canvas)
r = QgsRectangle()
r.setXMinimum(point.x() - searchRadius)
r.setXMaximum(point.x() + searchRadius)
r.setYMinimum(point.y() - searchRadius)
r.setYMaximum(point.y() + searchRadius)
r = self.toLayerCoordinates(self.layer, r)
req = QgsFeatureRequest()
req.setFilterRect(r)
req.setFlags(QgsFeatureRequest.ExactIntersect)
for f in self.layer.getFeatures(req):
featureList.append(QgsFeature(f))
except QgsCsException as cse:
print 'Caught CRS exception', cse.what()
myFilter = False
context = QgsRenderContext(
QgsRenderContext.fromMapSettings(self.canvas.mapSettings()))
renderer = self.layer.rendererV2()
if (renderer is not None and
(renderer.capabilities() | QgsFeatureRendererV2.ScaleDependent)):
renderer.startRender(context, self.layer.pendingFields())
myFilter = renderer.capabilities() and QgsFeatureRendererV2.Filter
for f in featureList:
if myFilter and not renderer.willRenderFeature(f):
continue
featureCount += 1
self.results.append((self.layer, f))
if (renderer is not None and
(renderer.capabilities() | QgsFeatureRendererV2.ScaleDependent)):
renderer.stopRender(context)
print 'Feature count on identify:', featureCount
QApplication.restoreOverrideCursor()
return featureCount > 0
def run(bar,layer1_path,layer2_path,obstacles_path,research_ray):
output = {}
#layer1 receiver
layer1 = QgsVectorLayer(layer1_path,"layer1","ogr")
#layer 2 source
layer2 = QgsVectorLayer(layer2_path,"layer2","ogr")
layer2_feat_all_dict = {}
layer2_feat_all = layer2.dataProvider().getFeatures()
layer2_spIndex = QgsSpatialIndex()
for layer2_feat in layer2_feat_all:
layer2_spIndex.insertFeature(layer2_feat)
layer2_feat_all_dict[layer2_feat.id()] = layer2_feat
if obstacles_path is not None:
obstacles_layer = QgsVectorLayer(obstacles_path,"obstacles","ogr")
obstacles_feat_all = obstacles_layer.dataProvider().getFeatures()
obstacles_spIndex = QgsSpatialIndex()
obstacles_feat_all_dict = {}
for obstacles_feat in obstacles_feat_all:
obstacles_spIndex.insertFeature(obstacles_feat)
obstacles_feat_all_dict[obstacles_feat.id()] = obstacles_feat
layer1_feat_all = layer1.dataProvider().getFeatures()
layer1_feat_total = layer1.dataProvider().featureCount()
layer1_feat_number = 0
for layer1_feat in layer1_feat_all:
layer1_feat_number = layer1_feat_number + 1
barValue = layer1_feat_number/float(layer1_feat_total)*100
bar.setValue(barValue)
# researches the layer2 points in a rectangle created by the research_ray
# creates the search rectangle
rect = QgsRectangle()
rect.setXMinimum( layer1_feat.geometry().asPoint().x() - research_ray )
rect.setXMaximum( layer1_feat.geometry().asPoint().x() + research_ray )
rect.setYMinimum( layer1_feat.geometry().asPoint().y() - research_ray )
rect.setYMaximum( layer1_feat.geometry().asPoint().y() + research_ray )
layer2_request = layer2_spIndex.intersects(rect)
layer2_points = []
for layer2_id in layer2_request:
layer2_feat = layer2_feat_all_dict[layer2_id]
ray_to_test_length = compute_distance(layer1_feat.geometry().asPoint(),layer2_feat.geometry().asPoint())
if ray_to_test_length <= research_ray:
ray_to_test = QgsGeometry.fromPolylineXY( [ layer1_feat.geometry().asPoint() , layer2_feat.geometry().asPoint() ] )
intersect = 0
if obstacles_path is not None:
obstacles_request = obstacles_spIndex.intersects(ray_to_test.boundingBox())
for obstacles_id in obstacles_request:
if obstacles_feat_all_dict[obstacles_id].geometry().crosses(ray_to_test) == 1:
intersect = 1
break
if intersect == 0:
layer2_points.append(layer2_feat.id())
output[layer1_feat.id()] = layer2_points
return output
def run_selection_distance(bar,layer1_path,layer2_path,obstacles_path,research_ray,dict_selection_layer2TOlayer3,layer3_path):
'''runs only in the selection dict and check the distance also with the selection dict rays'''
output = {}
layer1 = QgsVectorLayer(layer1_path,"layer1","ogr")
layer2 = QgsVectorLayer(layer2_path,"layer2","ogr")
layer2_feat_all_dict = {}
layer2_feat_all = layer2.dataProvider().getFeatures()
layer2_spIndex = QgsSpatialIndex()
for layer2_feat in layer2_feat_all:
layer2_spIndex.insertFeature(layer2_feat)
layer2_feat_all_dict[layer2_feat.id()] = layer2_feat
if obstacles_path is not None:
obstacles_layer = QgsVectorLayer(obstacles_path,"obstacles","ogr")
obstacles_feat_all = obstacles_layer.dataProvider().getFeatures()
obstacles_spIndex = QgsSpatialIndex()
obstacles_feat_all_dict = {}
for obstacles_feat in obstacles_feat_all:
obstacles_spIndex.insertFeature(obstacles_feat)
obstacles_feat_all_dict[obstacles_feat.id()] = obstacles_feat
layer3 = QgsVectorLayer(layer3_path,"layer3","ogr")
layer3_feat_all = layer3.dataProvider().getFeatures()
layer3_feat_all_dict = {}
for layer3_feat in layer3_feat_all:
layer3_feat_all_dict[layer3_feat.id()] = layer3_feat
layer1_feat_all = layer1.dataProvider().getFeatures()
layer1_feat_total = layer1.dataProvider().featureCount()
layer1_feat_number = 0
for layer1_feat in layer1_feat_all:
layer1_feat_number = layer1_feat_number + 1
barValue = layer1_feat_number/float(layer1_feat_total)*100
bar.setValue(barValue)
# researches the layer2 points in a rectangle created by the research_ray
# creates the search rectangle
rect = QgsRectangle()
rect.setXMinimum( layer1_feat.geometry().asPoint().x() - research_ray )
rect.setXMaximum( layer1_feat.geometry().asPoint().x() + research_ray )
rect.setYMinimum( layer1_feat.geometry().asPoint().y() - research_ray )
rect.setYMaximum( layer1_feat.geometry().asPoint().y() + research_ray )
layer2_request = layer2_spIndex.intersects(rect)
layer2_points = []
for layer2_id in layer2_request:
if layer2_id in dict_selection_layer2TOlayer3:
layer2_feat = layer2_feat_all_dict[layer2_id]
ray_to_test_length = compute_distance(layer1_feat.geometry().asPoint(),layer2_feat.geometry().asPoint())
distance_layer2_layer3 = []
min_distance_layer2_layer3 = research_ray
for layer3_id in dict_selection_layer2TOlayer3[layer2_id]:
layer3_feat = layer3_feat_all_dict[layer3_id]
ray_layer2_layer3 = compute_distance(layer2_feat.geometry().asPoint(),layer3_feat.geometry().asPoint())
if ray_layer2_layer3 < min_distance_layer2_layer3:
min_distance_layer2_layer3 = ray_layer2_layer3
if min_distance_layer2_layer3 + ray_to_test_length <= research_ray:
ray_to_test = QgsGeometry.fromPolyline( [ layer1_feat.geometry().asPoint() , layer2_feat.geometry().asPoint() ] )
intersect = 0
if obstacles_path is not None:
obstacles_request = obstacles_spIndex.intersects(ray_to_test.boundingBox())
for obstacles_id in obstacles_request:
if obstacles_feat_all_dict[obstacles_id].geometry().crosses(ray_to_test) == 1:
intersect = 1
break
if intersect == 0:
layer2_points.append(layer2_feat.id())
output[layer1_feat.id()] = layer2_points
return output
class HeatmapPixelSizeWidget(BASE, WIDGET):
def __init__(self):
super(HeatmapPixelSizeWidget, self).__init__(None)
self.setupUi(self)
self.layer_bounds = QgsRectangle()
self.layer = None
self.raster_bounds = QgsRectangle()
self.radius = 100
self.radius_field = None
self.mCellXSpinBox.setShowClearButton(False)
self.mCellYSpinBox.setShowClearButton(False)
self.mRowsSpinBox.setShowClearButton(False)
self.mColumnsSpinBox.setShowClearButton(False)
self.mCellYSpinBox.valueChanged.connect(self.mCellXSpinBox.setValue)
self.mCellXSpinBox.valueChanged.connect(self.pixelSizeChanged)
self.mRowsSpinBox.valueChanged.connect(self.rowsChanged)
self.mColumnsSpinBox.valueChanged.connect(self.columnsChanged)
def setRadius(self, radius):
self.radius = radius
self.recalculate_bounds()
def setRadiusField(self, radius_field):
self.radius_field = radius_field
self.recalculate_bounds()
def setLayer(self, layer):
if not layer:
return
bounds = layer.extent()
if bounds.isNull():
return
self.layer = layer
self.layer_bounds = bounds
self.recalculate_bounds()
def recalculate_bounds(self):
self.raster_bounds = QgsRectangle(self.layer_bounds)
if not self.layer:
return
max_radius = self.radius
if self.radius_field:
idx = self.layer.fields().lookupField(self.radius_field)
try:
max_radius = float(self.layer.maximumValue(idx))
except:
pass
self.raster_bounds.setXMinimum(self.raster_bounds.xMinimum() -
max_radius)
self.raster_bounds.setYMinimum(self.raster_bounds.yMinimum() -
max_radius)
self.raster_bounds.setXMaximum(self.raster_bounds.xMaximum() +
max_radius)
self.raster_bounds.setYMaximum(self.raster_bounds.yMaximum() +
max_radius)
self.pixelSizeChanged()
def pixelSizeChanged(self):
cell_size = self.mCellXSpinBox.value()
if cell_size <= 0:
return
self.mCellYSpinBox.blockSignals(True)
self.mCellYSpinBox.setValue(cell_size)
self.mCellYSpinBox.blockSignals(False)
rows = max(round(self.raster_bounds.height() / cell_size) + 1, 1)
cols = max(round(self.raster_bounds.width() / cell_size) + 1, 1)
self.mRowsSpinBox.blockSignals(True)
self.mRowsSpinBox.setValue(rows)
self.mRowsSpinBox.blockSignals(False)
self.mColumnsSpinBox.blockSignals(True)
self.mColumnsSpinBox.setValue(cols)
self.mColumnsSpinBox.blockSignals(False)
def rowsChanged(self):
rows = self.mRowsSpinBox.value()
if rows <= 0:
return
cell_size = self.raster_bounds.height() / rows
cols = max(round(self.raster_bounds.width() / cell_size) + 1, 1)
self.mColumnsSpinBox.blockSignals(True)
self.mColumnsSpinBox.setValue(cols)
self.mColumnsSpinBox.blockSignals(False)
for w in [self.mCellXSpinBox, self.mCellYSpinBox]:
w.blockSignals(True)
w.setValue(cell_size)
w.blockSignals(False)
def columnsChanged(self):
cols = self.mColumnsSpinBox.value()
if cols < 2:
return
cell_size = self.raster_bounds.width() / (cols - 1)
rows = max(round(self.raster_bounds.height() / cell_size), 1)
self.mRowsSpinBox.blockSignals(True)
self.mRowsSpinBox.setValue(rows)
self.mRowsSpinBox.blockSignals(False)
for w in [self.mCellXSpinBox, self.mCellYSpinBox]:
w.blockSignals(True)
w.setValue(cell_size)
w.blockSignals(False)
def setValue(self, value):
try:
numeric_value = float(value)
except:
return False
self.mCellXSpinBox.setValue(numeric_value)
self.mCellYSpinBox.setValue(numeric_value)
return True
def value(self):
return self.mCellXSpinBox.value()
class HeatmapPixelSizeWidget(BASE, WIDGET):
def __init__(self):
super(HeatmapPixelSizeWidget, self).__init__(None)
self.setupUi(self)
self.layer_bounds = QgsRectangle()
self.layer = None
self.raster_bounds = QgsRectangle()
self.radius = 100
self.radius_field = None
self.mCellXSpinBox.setShowClearButton(False)
self.mCellYSpinBox.setShowClearButton(False)
self.mRowsSpinBox.setShowClearButton(False)
self.mColumnsSpinBox.setShowClearButton(False)
self.mCellYSpinBox.valueChanged.connect(self.mCellXSpinBox.setValue)
self.mCellXSpinBox.valueChanged.connect(self.pixelSizeChanged)
self.mRowsSpinBox.valueChanged.connect(self.rowsChanged)
self.mColumnsSpinBox.valueChanged.connect(self.columnsChanged)
def setRadius(self, radius):
self.radius = radius
self.recalculate_bounds()
def setRadiusField(self, radius_field):
self.radius_field = radius_field
self.recalculate_bounds()
def setLayer(self, layer):
if not layer:
return
bounds = layer.extent()
if bounds.isNull():
return
self.layer = layer
self.layer_bounds = bounds
self.recalculate_bounds()
def recalculate_bounds(self):
self.raster_bounds = QgsRectangle(self.layer_bounds)
if not self.layer:
return
max_radius = self.radius
if self.radius_field:
idx = self.layer.fields().lookupField(self.radius_field)
try:
max_radius = float(self.layer.maximumValue(idx))
except:
pass
self.raster_bounds.setXMinimum(self.raster_bounds.xMinimum() - max_radius)
self.raster_bounds.setYMinimum(self.raster_bounds.yMinimum() - max_radius)
self.raster_bounds.setXMaximum(self.raster_bounds.xMaximum() + max_radius)
self.raster_bounds.setYMaximum(self.raster_bounds.yMaximum() + max_radius)
self.pixelSizeChanged()
def pixelSizeChanged(self):
cell_size = self.mCellXSpinBox.value()
if cell_size <= 0:
return
self.mCellYSpinBox.blockSignals(True)
self.mCellYSpinBox.setValue(cell_size)
self.mCellYSpinBox.blockSignals(False)
rows = max(round(self.raster_bounds.height() / cell_size) + 1, 1)
cols = max(round(self.raster_bounds.width() / cell_size) + 1, 1)
self.mRowsSpinBox.blockSignals(True)
self.mRowsSpinBox.setValue(rows)
self.mRowsSpinBox.blockSignals(False)
self.mColumnsSpinBox.blockSignals(True)
self.mColumnsSpinBox.setValue(cols)
self.mColumnsSpinBox.blockSignals(False)
def rowsChanged(self):
rows = self.mRowsSpinBox.value()
if rows <= 0:
return
cell_size = self.raster_bounds.height() / rows
cols = max(round(self.raster_bounds.width() / cell_size) + 1, 1)
self.mColumnsSpinBox.blockSignals(True)
self.mColumnsSpinBox.setValue(cols)
self.mColumnsSpinBox.blockSignals(False)
for w in [self.mCellXSpinBox, self.mCellYSpinBox]:
w.blockSignals(True)
w.setValue(cell_size)
w.blockSignals(False)
def columnsChanged(self):
cols = self.mColumnsSpinBox.value()
if cols < 2:
return
cell_size = self.raster_bounds.width() / (cols - 1)
rows = max(round(self.raster_bounds.height() / cell_size), 1)
self.mRowsSpinBox.blockSignals(True)
self.mRowsSpinBox.setValue(rows)
self.mRowsSpinBox.blockSignals(False)
for w in [self.mCellXSpinBox, self.mCellYSpinBox]:
w.blockSignals(True)
w.setValue(cell_size)
w.blockSignals(False)
def setValue(self, value):
try:
numeric_value = float(value)
except:
return False
self.mCellXSpinBox.setValue(numeric_value)
self.mCellYSpinBox.setValue(numeric_value)
return True
def value(self):
return self.mCellXSpinBox.value()
def response_geotiff_mode(self, request):
"""
Export raster as geotiff
i.e:
192.168.1.137:8006/raster/api/geotiff/qdjango/190/sfondo_clip_c60533a4_743e_4734_9b95_514ac765ec4e/
192.168.1.137:8006/raster/api/geotiff/qdjango/190/europa_dem_8f0a9c30_5b96_4661_b747_8ce4f2679d6b/?map_extent=10.515901325263899%2C43.875701513907146%2C10.55669628723769%2C43.92294901234999
:param request: Http Django request object
:return: http response with attached file
"""
#if not self.layer.download:
# return HttpResponseForbidden()
tmp_dir = tempfile.TemporaryDirectory()
filename = f"{self.metadata_layer.qgis_layer.name()}.tif"
file_path = os.path.join(tmp_dir.name, filename)
writer = QgsRasterFileWriter(file_path)
provider = self.metadata_layer.qgis_layer.dataProvider()
renderer = self.metadata_layer.qgis_layer.renderer()
# Check for Url Params
if request.query_params.get('map_extent'):
me = request.query_params.get('map_extent').split(',')
orig_extent =provider.extent()
extent = QgsRectangle(float(me[0]), float(me[1]), float(me[2]), float(me[3]))
# If crs layer is not equal to project crs
if self.reproject:
ct = QgsCoordinateTransform(
QgsCoordinateReferenceSystem(f'EPSG:{self.layer.project.group.srid.srid}'),
self.metadata_layer.qgis_layer.crs(),
QgsCoordinateTransformContext()
)
extent = ct.transform(extent)
# Calc columns and rows
cols = int((extent.xMaximum() - extent.xMinimum()) /
(orig_extent.xMaximum() - orig_extent.xMinimum()) * provider.xSize())
rows = int((extent.yMaximum() - extent.yMinimum()) /
(orig_extent.yMaximum() - orig_extent.yMinimum()) * provider.ySize())
# For cols or rows lower than 0, we have to recalculate extent to guarantee minimal raster cell
if cols < 1:
cols = 1
new_wide_x_extent = (orig_extent.xMaximum() - orig_extent.xMinimum()) / provider.xSize()
off = (new_wide_x_extent - (extent.xMaximum() - extent.xMinimum())) / 2
extent.setXMinimum(extent.xMinimum() - off)
extent.setXMaximum(extent.xMaximum() + off)
if rows < 1:
rows = 1
new_wide_y_extent = (orig_extent.yMaximum() - orig_extent.yMinimum()) / provider.ySize()
off = (new_wide_y_extent - (extent.yMaximum() - extent.yMinimum())) / 2
extent.setYMinimum(extent.yMinimum() - off)
extent.setYMaximum(extent.yMaximum() + off)
else:
extent = provider.extent()
cols = provider.xSize()
rows = provider.ySize()
pipe = QgsRasterPipe()
pipe.set(provider.clone())
pipe.set(renderer.clone())
error_code = writer.writeRaster(
pipe,
cols,
rows,
extent,
self.metadata_layer.qgis_layer.crs(),
self.metadata_layer.qgis_layer.transformContext()
)
if error_code != QgsRasterFileWriter.NoError:
tmp_dir.cleanup()
raise APIException(f"An error occoured on create raster file for export")
# Grab ZIP file from in-memory, make response with correct MIME-type
response = HttpResponse(
open(file_path, 'rb').read(), content_type='image/tif')
response['Content-Disposition'] = f'attachment; filename={filename}'
response.set_cookie('fileDownload', 'true')
return response
def run(sources_layer_path, receivers_layer_path, emission_pts_layer_path,
research_ray):
sources_layer = QgsVectorLayer(sources_layer_path, "input layer", "ogr")
receivers_layer = QgsVectorLayer(receivers_layer_path, "output layer",
"ogr")
sources_feat_all = sources_layer.dataProvider().getFeatures()
receivers_feat_all_dict = {}
receivers_feat_all = receivers_layer.dataProvider().getFeatures()
receivers_spIndex = QgsSpatialIndex()
for receivers_feat in receivers_feat_all:
receivers_spIndex.insertFeature(receivers_feat)
receivers_feat_all_dict[receivers_feat.id()] = receivers_feat
emission_pts_fields = QgsFields()
emission_pts_fields.append(QgsField("id_emi", QVariant.Int))
emission_pts_fields.append(QgsField("id_emi_source", QVariant.Int))
emission_pts_fields.append(QgsField("id_source", QVariant.Int))
emission_pts_fields.append(
QgsField("d_rTOe", QVariant.Double, len=10, prec=2))
# update for QGIS 3 converting VectorWriter to QgsVectorFileWriter
# emission_pts_writer = VectorWriter(emission_pts_layer_path, None, emission_pts_fields, 0, sources_layer.crs())
emission_pts_writer = QgsVectorFileWriter(emission_pts_layer_path,
"System", emission_pts_fields,
QgsWkbTypes.Point,
sources_layer.crs(),
"ESRI Shapefile")
# initializes ray and emission point id
emission_pt_id = 0
for sources_feat in sources_feat_all:
# researches the receiver points in a rectangle created by the research_ray
# creates the search rectangle
rect = QgsRectangle()
rect.setXMinimum(sources_feat.geometry().boundingBox().xMinimum() -
research_ray)
rect.setXMaximum(sources_feat.geometry().boundingBox().xMaximum() +
research_ray)
rect.setYMinimum(sources_feat.geometry().boundingBox().yMinimum() -
research_ray)
rect.setYMaximum(sources_feat.geometry().boundingBox().yMaximum() +
research_ray)
receiver_pts_request = receivers_spIndex.intersects(rect)
distance_min = []
for receiver_pts_id in receiver_pts_request:
receiver_pts_feat = receivers_feat_all_dict[receiver_pts_id]
result = sources_feat.geometry().closestSegmentWithContext(
receiver_pts_feat.geometry().asPoint())
distance_min_tmp = sqrt(result[0])
if distance_min_tmp <= research_ray:
distance_min.append(distance_min_tmp)
# defines segment max length
if len(distance_min) >= 1:
segment_max = min(distance_min) / 2
if segment_max < 2:
segment_max = 2
else:
continue
# splits the sources line in emission points at a fix distance (minimum distance/2) and create the emission point layer
# gets vertex
sources_geom = sources_feat.geometry()
if sources_geom.isMultipart():
sources_geom.convertToSingleType()
sources_feat_vertex_pt_all = sources_geom.asPolyline()
emission_pt_id_road = 0
for i in range(0, len(sources_feat_vertex_pt_all)):
pt1 = QgsPointXY(sources_feat_vertex_pt_all[i])
add_point_to_layer(emission_pts_writer, pt1, [
emission_pt_id, emission_pt_id_road,
sources_feat.id(), segment_max
])
emission_pt_id = emission_pt_id + 1
emission_pt_id_road = emission_pt_id_road + 1
if i < len(sources_feat_vertex_pt_all) - 1:
pt2 = QgsPoint(sources_feat_vertex_pt_all[i + 1])
x1 = pt1.x()
y1 = pt1.y()
x2 = pt2.x()
y2 = pt2.y()
if y2 == y1:
dx = segment_max
dy = 0
m = 0
elif x2 == x1:
dx = 0
dy = segment_max
else:
m = (y2 - y1) / (x2 - x1)
dx = sqrt((segment_max**2) / (1 + m**2))
dy = sqrt(((segment_max**2) * (m**2)) / (1 + m**2))
pt = pt1
while compute_distance(pt, pt2) > segment_max:
x_temp = pt.x()
y_temp = pt.y()
if x_temp < x2:
if m > 0:
pt = QgsPointXY(x_temp + dx, y_temp + dy)
elif m < 0:
pt = QgsPointXY(x_temp + dx, y_temp - dy)
elif m == 0:
pt = QgsPointXY(x_temp + dx, y_temp)
elif x_temp > x2:
if m > 0:
pt = QgsPointXY(x_temp - dx, y_temp - dy)
elif m < 0:
pt = QgsPointXY(x_temp - dx, y_temp + dy)
elif m == 0:
pt = QgsPointXY(x_temp - dx, y_temp)
elif x_temp == x2:
if y2 > y_temp:
pt = QgsPointXY(x_temp, y_temp + dy)
else:
pt = QgsPointXY(x_temp, y_temp - dy)
add_point_to_layer(emission_pts_writer, pt, [
emission_pt_id, emission_pt_id_road,
sources_feat.id(), segment_max
])
emission_pt_id = emission_pt_id + 1
emission_pt_id_road = emission_pt_id_road + 1
del emission_pts_writer
def spaced(bar, buildings_layer_path, receiver_points_layer_path,
spaced_pts_distance):
distance_from_facades = 0.1
buildings_layer_name = os.path.splitext(
os.path.basename(buildings_layer_path))[0]
buildings_layer = QgsVectorLayer(buildings_layer_path,
buildings_layer_name, "ogr")
# cp building layer to delete all fields
buildings_memory_layer = QgsVectorLayer(
"Polygon?crs=" + str(buildings_layer.crs().authid()),
"polygon_memory_layer", "memory")
buildings_memory_layer.dataProvider().addAttributes([])
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
buildings_feat_list = []
for buildings_feat in buildings_feat_all:
buildings_feat_list.append(buildings_feat)
buildings_memory_layer.dataProvider().addFeatures(buildings_feat_list)
buildings_memory_layer.updateExtents()
# this is crazy: I had to addd this line otherwise the first processing doesn't work...
QgsProject.instance().addMapLayers([buildings_memory_layer])
bar.setValue(1)
# this processing alg has as output['OUTPUT'] the layer
output = processing.run(
"native:buffer", {
'INPUT': buildings_memory_layer,
'DISTANCE': distance_from_facades,
'DISSOLVE': False,
'OUTPUT': 'memory:'
})
# I can now remove the layer from map...
QgsProject.instance().removeMapLayers([buildings_memory_layer.id()])
bar.setValue(25)
# this processing alg has as output['OUTPUT'] the layer
output = processing.run("qgis:polygonstolines", {
'INPUT': output['OUTPUT'],
'OUTPUT': 'memory:'
})
bar.setValue(50)
# this processing alg has as output['output'] the layer path...
poly_to_lines = output['OUTPUT']
output = processing.run(
"qgis:pointsalonglines", {
'INPUT': poly_to_lines,
'DISTANCE': spaced_pts_distance,
'START_OFFSET': 0,
'END_OFFSET': 0,
'OUTPUT': 'memory:'
})
bar.setValue(75)
receiver_points_memory_layer = output['OUTPUT']
del output
## Delete pts in buildings
# creates SpatialIndex
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
buildings_spIndex = QgsSpatialIndex()
buildings_feat_all_dict = {}
for buildings_feat in buildings_feat_all:
buildings_spIndex.insertFeature(buildings_feat)
buildings_feat_all_dict[buildings_feat.id()] = buildings_feat
receiver_points_memory_layer_all = receiver_points_memory_layer.dataProvider(
).getFeatures()
receiver_points_layer_fields = QgsFields()
receiver_points_layer_fields.append(QgsField("id_pt", QVariant.Int))
receiver_points_layer_fields.append(QgsField("id_bui", QVariant.Int))
receiver_points_layer_writer = QgsVectorFileWriter(
receiver_points_layer_path, "System", receiver_points_layer_fields,
QgsWkbTypes.Point, buildings_layer.crs(), "ESRI Shapefile")
receiver_points_feat_id = 0
receiver_memory_feat_total = receiver_points_memory_layer.dataProvider(
).featureCount()
receiver_memory_feat_number = 0
for receiver_memory_feat in receiver_points_memory_layer_all:
receiver_memory_feat_number = receiver_memory_feat_number + 1
barValue = receiver_memory_feat_number / float(
receiver_memory_feat_total) * 25 + 75
bar.setValue(barValue)
rect = QgsRectangle()
rect.setXMinimum(receiver_memory_feat.geometry().asPoint().x() -
distance_from_facades)
rect.setXMaximum(receiver_memory_feat.geometry().asPoint().x() +
distance_from_facades)
rect.setYMinimum(receiver_memory_feat.geometry().asPoint().y() -
distance_from_facades)
rect.setYMaximum(receiver_memory_feat.geometry().asPoint().y() +
distance_from_facades)
buildings_selection = buildings_spIndex.intersects(rect)
to_add = True
receiver_geom = receiver_memory_feat.geometry()
building_id_correct = None
for buildings_id in buildings_selection:
building_geom = buildings_feat_all_dict[buildings_id].geometry()
intersectBuilding = QgsGeometry.intersects(receiver_geom,
building_geom)
building_id_correct = buildings_id
if intersectBuilding:
to_add = False
building_id_correct = None
break
# picking the nearest building to the receiver point analysed
nearestIds = buildings_spIndex.nearestNeighbor(receiver_geom.asPoint(),
1)
building_fid = []
for featureId in nearestIds:
request = QgsFeatureRequest().setFilterFid(featureId)
for feature in buildings_layer.getFeatures(request):
dist = receiver_geom.distance(feature.geometry())
building_fid.append((dist, feature.id()))
building_fid_correct = min(building_fid, key=lambda x: x[0])[-1]
if to_add:
attributes = [receiver_points_feat_id, building_fid_correct]
fet = QgsFeature()
fet.setGeometry(receiver_memory_feat.geometry())
fet.setAttributes(attributes)
receiver_points_layer_writer.addFeature(fet)
receiver_points_feat_id = receiver_points_feat_id + 1
del receiver_points_layer_writer
receiver_points_layer_name = os.path.splitext(
os.path.basename(receiver_points_layer_path))[0]
receiver_points_layer = QgsVectorLayer(receiver_points_layer_path,
str(receiver_points_layer_name),
"ogr")
QgsProject.instance().addMapLayers([receiver_points_layer])
QgsProject.instance().reloadAllLayers()
def ReadAndMergeVectorLayers(vectorLayers):
# pylint: disable=too-many-locals
# pylint: disable=too-many-branches
# pylint: disable=too-many-statements
category = ""
feats = []
for i in vectorLayers:
if shared.vectorFileType[i] == "ogr":
thisLayer = QgsVectorLayer(shared.vectorFileName[i],
shared.vectorFileTitle[i], "ogr")
elif shared.vectorFileType[i] == "spatialite":
uri = QgsDataSourceUri()
uri.setDatabase(shared.vectorFileName[i])
schema = ''
geom_column = 'Geometry'
uri.setDataSource(schema, shared.vectorFileTable[i], geom_column)
thisLayer = QgsVectorLayer(uri.uri(), shared.vectorFileTitle[i],
shared.vectorFileType[i])
elif shared.vectorFileType[i] == "xyz":
uri = shared.vectorFileName[
i] + "?type=csv&useHeader=No&xField=field_1&yField=field_2&spatialIndex=no&subsetIndex=no&watchFile=no"
thisLayer = QgsVectorLayer(uri, shared.vectorFileTitle[i],
"delimitedtext")
else:
shared.fpOut.write("Cannot load vector file of type '" +
shared.vectorFileType[i] + "'")
return -1, -1
if not thisLayer.isValid():
shared.fpOut.write("Vector layer '" + shared.vectorFileTitle[i] +
"' failed to load")
return -1, -1
shared.fpOut.write("Vector layer '" + shared.vectorFileTitle[i] +
"' loaded\n")
# Copy the features from this layer that are within the displayed extent, to a new list
extentRectWithBorder = QgsRectangle()
borderSize = 100
extentRectWithBorder.setXMinimum(shared.extentRect.xMinimum() -
borderSize)
extentRectWithBorder.setYMinimum(shared.extentRect.yMinimum() -
borderSize)
extentRectWithBorder.setXMaximum(shared.extentRect.xMaximum() +
borderSize)
extentRectWithBorder.setYMaximum(shared.extentRect.yMaximum() +
borderSize)
request = QgsFeatureRequest(extentRectWithBorder)
features = thisLayer.getFeatures(request)
#features = thisLayer.getFeatures()
print("Copying features from vector layer '" +
shared.vectorFileTitle[i] + "'")
feats += features
#print("N features =", len(feats))
#for feat in features:
#newFeature = QgsFeature()
#newFeature.setGeometry(feat.geometry())
#fields = feat.fields()
#newFeature.setFields(fields)
#attrs = feat.attributes()
#newFeature.setAttributes(attrs)
#feats.append(newFeature)
##print(feat)
##feats.append(feat)
flds = thisLayer.fields()
#print(shared.vectorFileTitle[i] + " FIELD NAMES " + str(flds.names()))
#print(shared.vectorFileTitle[i] + " number of attribute fields = " + str(len(flds.names())))
category = shared.vectorFileCategory[i]
# Get the Coordinate Reference System and the list of fields from the last input file
thisLayerCRS = thisLayer.crs().toWkt()
thisLayerFieldList = thisLayer.dataProvider().fields().toList()
# Create the merged layer by checking the geometry type of the input files
layerGeom = thisLayer.geometryType()
layerWkb = thisLayer.wkbType()
isMulti = QgsWkbTypes.isMultiType(layerWkb)
if layerGeom == QgsWkbTypes.PointGeometry:
if isMulti:
mergedLayer = QgsVectorLayer('MultiPoint?crs=' + thisLayerCRS,
'merged', "memory")
else:
mergedLayer = QgsVectorLayer('Point?crs=' + thisLayerCRS, 'merged',
"memory")
elif layerGeom == QgsWkbTypes.LineGeometry:
if isMulti:
mergedLayer = QgsVectorLayer('MultiLineString?crs=' + thisLayerCRS,
'merged', "memory")
else:
mergedLayer = QgsVectorLayer('LineString?crs=' + thisLayerCRS,
'merged', "memory")
elif layerGeom == QgsWkbTypes.PolygonGeometry:
if isMulti:
mergedLayer = QgsVectorLayer('MultiPolygon?crs=' + thisLayerCRS,
'merged', "memory")
else:
mergedLayer = QgsVectorLayer('Polygon?crs=' + thisLayerCRS,
'merged', "memory")
else:
geomTypeString = QgsWkbTypes.displayString(int(layerWkb))
errStr = "ERROR: layer type " + geomTypeString + " could not be merged"
print(errStr)
shared.fpOut.write(errStr + "\n")
return -1, -1
# Is the new (but still empty) merged layer OK?
if not mergedLayer.isValid():
titleStr = ""
for i in vectorLayers:
titleStr += shared.vectorFileTitle[i]
if i < len(vectorLayers):
titleStr += "' '"
errStr = "ERROR: could not create new vector layer for merge of '" + titleStr + "'"
print(errStr)
shared.fpOut.write(errStr + "\n")
return -1, -1
# Sort the list of features by identifier
feats.sort(key=lambda feat: feat.attributes()[1])
#for i in range(10):
#print("BEFORE MERGE " + str(feats[i].attributes()))
#print("=================")
##BODGE This is needed because QGIS 3 handles Boolean layers incorrectly
#print("*********************")
#print("*** ORIGINAL: " + str(thisLayerFieldList))
#for fld in thisLayerFieldList:
#print(fld.type())
#print("*********************")
#for fld in thisLayerFieldList:
#fldName = fld.typeName()
#if fldName == "Boolean":
#fld.setTypeName("Integer64")
#fld.setType(4)
#print("**** CHANGED : " + str(thisLayerFieldList))
#for fld in thisLayerFieldList:
#print(fld.type())
#print("*********************")
# Add the field attributes to the merged layer
provider = mergedLayer.dataProvider()
#print("PROVIDER: " + str(provider))
#print("PROVIDER Number of attribute fields = " + str(len(thisLayerFieldList)))
if not provider.addAttributes(thisLayerFieldList):
errStr = "ERROR: could not add attributes to merged layer"
print(errStr)
shared.fpOut.write(errStr + "\n")
return -1, -1
mergedLayer.updateFields()
flds = mergedLayer.fields()
#print("MERGED FIELD NAMES " + str(flds.names()))
#print("MERGED number of attribute fields = " + str(len(flds.names())))
if not mergedLayer.startEditing():
errStr = "ERROR: could not edit merged layer"
print(errStr)
shared.fpOut.write(errStr + "\n")
return -1, -1
if not mergedLayer.addFeatures(feats):
errStr = "ERROR: could not add features to merged layer"
print(errStr)
shared.fpOut.write(errStr + "\n")
return -1, -1
#testFeats = mergedLayer.getFeatures()
#print("BEFORE testFeats = " + str(testFeats))
#nMergedFeat = 0
#for feat in features:
#nMergedFeat += 1
#print("BEFORE N features in testFeats =", nMergedFeat)
mergedLayer.commitChanges()
#testFeats = mergedLayer.getFeatures()
#print("AFTER testFeats = " + str(testFeats))
#nMergedFeat = 0
#for feat in features:
#nMergedFeat += 1
#print("AFTER N features in testFeats =", nMergedFeat)
#features = mergedLayer.getFeatures()
#for feat in features:
#shared.fpOut.write(str(feat.attributes()))
#for field in mergedLayer.fields().toList():
#shared.fpOut.write(str(field.name()))
# Sort out style
i = vectorLayers[-1]
if not shared.vectorFileStyle[i]:
shared.vectorFileStyle[i] = mergedLayer.styleURI()
#shared.fpOut.write(shared.vectorFileStyle[i])
if not mergedLayer.loadDefaultStyle():
errStr = "ERROR: could not load default style '" + shared.vectorFileStyle[
i] + "' for vector layer '" + shared.vectorFileTitle[i] + "'"
print(errStr)
shared.fpOut.write(errStr + "\n")
else:
if not mergedLayer.loadNamedStyle(shared.vectorFileStyle[i]):
errStr = "ERROR: could not load style '" + shared.vectorFileStyle[
i] + "' for vector layer '" + shared.vectorFileTitle[i] + "'"
print(errStr)
shared.fpOut.write(errStr + "\n")
# Set transparency
mergedLayer.setOpacity(shared.vectorFileOpacity[i])
# Add this layer to the app's registry
QgsProject.instance().addMapLayer(mergedLayer)
mergedNames = ""
for i in vectorLayers:
mergedNames += "'"
mergedNames += shared.vectorFileTitle[i]
mergedNames += "' "
shared.fpOut.write("\tMerged layers " + mergedNames + "\n")
print("Merged layers " + mergedNames)
return mergedLayer, category
def middle(bar, buildings_layer_path, receiver_points_layer_path):
buildings_layer_name = os.path.splitext(
os.path.basename(buildings_layer_path))[0]
buildings_layer = QgsVectorLayer(buildings_layer_path,
buildings_layer_name, "ogr")
# defines emission_points layer
receiver_points_fields = QgsFields()
receiver_points_fields.append(QgsField("id_pt", QVariant.Int))
receiver_points_fields.append(QgsField("id_bui", QVariant.Int))
receiver_points_writer = QgsVectorFileWriter(receiver_points_layer_path,
"System",
receiver_points_fields,
QgsWkbTypes.Point,
buildings_layer.crs(),
"ESRI Shapefile")
# gets features from layer
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
# creates SpatialIndex
buildings_spIndex = QgsSpatialIndex()
buildings_feat_all_dict = {}
for buildings_feat in buildings_feat_all:
buildings_spIndex.insertFeature(buildings_feat)
buildings_feat_all_dict[buildings_feat.id()] = buildings_feat
# defines distanze_point
distance_point = 0.1
# re-gets features from layer
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
buildings_feat_total = buildings_layer.dataProvider().featureCount()
pt_id = 0
buildings_feat_number = 0
for buildings_feat in buildings_feat_all:
buildings_feat_number = buildings_feat_number + 1
barValue = buildings_feat_number / float(buildings_feat_total) * 100
bar.setValue(barValue)
building_geom = buildings_feat.geometry()
if building_geom.isMultipart():
buildings_pt = building_geom.asMultiPolygon()[0]
#building_geom.convertToSingleType()
else:
buildings_pt = buildings_feat.geometry().asPolygon()
# creates the search rectangle to match the receiver point in the building and del them
rect = QgsRectangle()
rect.setXMinimum(buildings_feat.geometry().boundingBox().xMinimum() -
distance_point)
rect.setXMaximum(buildings_feat.geometry().boundingBox().xMaximum() +
distance_point)
rect.setYMinimum(buildings_feat.geometry().boundingBox().yMinimum() -
distance_point)
rect.setYMaximum(buildings_feat.geometry().boundingBox().yMaximum() +
distance_point)
buildings_selection = buildings_spIndex.intersects(rect)
if len(buildings_pt) > 0:
for i in range(0, len(buildings_pt)):
buildings_pts = buildings_pt[i]
####
# start part to delete pseudo vertex
# this part it's different from the diffraction delete pseudo vertex part
pts_index_to_delete_list = []
m_delta = 0.01
for ii in range(0, len(buildings_pts) - 1):
x1 = buildings_pts[ii - 1][0]
x2 = buildings_pts[ii][0]
x3 = buildings_pts[ii + 1][0]
y1 = buildings_pts[ii - 1][1]
y2 = buildings_pts[ii][1]
y3 = buildings_pts[ii + 1][1]
# particular cases: first point to delete! (remember that the first and the last have the same coordinates)
if ii == 0 and (x2 == x1 and y2 == y1):
x1 = buildings_pts[ii - 2][0]
y1 = buildings_pts[ii - 2][1]
# angular coefficient to find pseudo vertex
if x2 - x1 != 0 and x3 - x1 != 0:
m1 = (y2 - y1) / (x2 - x1)
m2 = (y3 - y1) / (x3 - x1)
#if round(m1,2) <= round(m2,2) + m_delta and round(m1,2) >= round(m2,2) - m_delta:
if m1 <= m2 + m_delta and m1 >= m2 - m_delta:
pts_index_to_delete_list.append(ii)
# particular cases: first point to delete! (remember that the first and the last have the same coordinates)
# here we delete the last and add x3,y3 (buildings_pts[ii+1] - the new last point)
if ii == 0:
pts_index_to_delete_list.append(
len(buildings_pts) - 1)
buildings_pts.append(buildings_pts[ii + 1])
# del pseudo vertex
pts_index_to_delete_list = sorted(pts_index_to_delete_list,
reverse=True)
for pt_index_to_del in pts_index_to_delete_list:
del buildings_pts[pt_index_to_del]
# end part to delete pseudo vertex
# for to generate receiver points
for ii in range(0, len(buildings_pts) - 1):
x1 = buildings_pts[ii][0]
x2 = buildings_pts[ii + 1][0]
y1 = buildings_pts[ii][1]
y2 = buildings_pts[ii + 1][1]
xm = (x1 + x2) / 2
ym = (y1 + y2) / 2
if y2 == y1:
dx = 0
dy = distance_point
elif x2 == x1:
dx = distance_point
dy = 0
else:
m = (y2 - y1) / (x2 - x1)
m_p = -1 / m
dx = sqrt((distance_point**2) / (1 + m_p**2))
dy = sqrt(
((distance_point**2) * (m_p**2)) / (1 + m_p**2))
if (x2 >= x1 and y2 >= y1) or (x2 < x1 and y2 < y1):
pt1 = QgsPointXY(xm + dx, ym - dy)
pt2 = QgsPointXY(xm - dx, ym + dy)
if (x2 >= x1 and y2 < y1) or (x2 < x1 and y2 >= y1):
pt1 = QgsPointXY(xm + dx, ym + dy)
pt2 = QgsPointXY(xm - dx, ym - dy)
pt = QgsFeature()
# pt1, check if is in a building and eventually add it
pt.setGeometry(QgsGeometry.fromPointXY(pt1))
intersect = 0
for buildings_id in buildings_selection:
if buildings_feat_all_dict[buildings_id].geometry(
).intersects(pt.geometry()) == 1:
intersect = 1
break
if intersect == 0:
pt.setAttributes([pt_id, buildings_feat.id()])
receiver_points_writer.addFeature(pt)
pt_id = pt_id + 1
# pt2, check if is in a building and eventually add it
pt.setGeometry(QgsGeometry.fromPointXY(pt2))
intersect = 0
for buildings_id in buildings_selection:
if buildings_feat_all_dict[buildings_id].geometry(
).intersects(pt.geometry()) == 1:
intersect = 1
break
if intersect == 0:
pt.setAttributes([pt_id, buildings_feat.id()])
receiver_points_writer.addFeature(pt)
pt_id = pt_id + 1
del receiver_points_writer
#print receiver_points_layer_path
receiver_points_layer_name = os.path.splitext(
os.path.basename(receiver_points_layer_path))[0]
#print receiver_points_layer_name
receiver_points_layer = QgsVectorLayer(receiver_points_layer_path,
str(receiver_points_layer_name),
"ogr")
QgsProject.instance().addMapLayers([receiver_points_layer])
def spaced(bar,buildings_layer_path,receiver_points_layer_path,spaced_pts_distance):
distance_from_facades = 0.1
buildings_layer_name = os.path.splitext(os.path.basename(buildings_layer_path))[0]
buildings_layer = QgsVectorLayer(buildings_layer_path,buildings_layer_name,"ogr")
# cp building layer to delete all fields
buildings_memory_layer = QgsVectorLayer("Polygon?crs=" + str(buildings_layer.crs().authid()), "polygon_memory_layer", "memory")
buildings_memory_layer.dataProvider().addAttributes([])
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
buildings_feat_list = []
for buildings_feat in buildings_feat_all:
buildings_feat_list.append(buildings_feat)
buildings_memory_layer.dataProvider().addFeatures(buildings_feat_list)
buildings_memory_layer.updateExtents()
# this is crazy: I had to addd this line otherwise the first processing doesn't work...
QgsProject.instance().addMapLayers([buildings_memory_layer])
bar.setValue(1)
# this processing alg has as output['OUTPUT'] the layer
output = processing.run("native:buffer", {'INPUT': buildings_memory_layer,
'DISTANCE': distance_from_facades,
'DISSOLVE': False,
'OUTPUT': 'memory:'})
# I can now remove the layer from map...
QgsProject.instance().removeMapLayers( [buildings_memory_layer.id()] )
bar.setValue(25)
# this processing alg has as output['OUTPUT'] the layer
output = processing.run("qgis:polygonstolines", {'INPUT': output['OUTPUT'],
'OUTPUT': 'memory:'})
bar.setValue(50)
# this processing alg has as output['output'] the layer path...
poly_to_lines = output['OUTPUT']
output = processing.run("qgis:pointsalonglines", {'INPUT': poly_to_lines,
'DISTANCE': spaced_pts_distance,
'START_OFFSET': 0,
'END_OFFSET': 0,
'OUTPUT': 'memory:'})
bar.setValue(75)
receiver_points_memory_layer = output['OUTPUT']
del output
## Delete pts in buildings
# creates SpatialIndex
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
buildings_spIndex = QgsSpatialIndex()
buildings_feat_all_dict = {}
for buildings_feat in buildings_feat_all:
buildings_spIndex.insertFeature(buildings_feat)
buildings_feat_all_dict[buildings_feat.id()] = buildings_feat
receiver_points_memory_layer_all = receiver_points_memory_layer.dataProvider().getFeatures()
receiver_points_layer_fields = QgsFields()
receiver_points_layer_fields.append(QgsField("id_pt", QVariant.Int))
receiver_points_layer_fields.append(QgsField("id_bui", QVariant.Int))
receiver_points_layer_writer = QgsVectorFileWriter(receiver_points_layer_path, "System",
receiver_points_layer_fields, QgsWkbTypes.Point,
buildings_layer.crs(), "ESRI Shapefile")
receiver_points_feat_id = 0
receiver_memory_feat_total = receiver_points_memory_layer.dataProvider().featureCount()
receiver_memory_feat_number = 0
for receiver_memory_feat in receiver_points_memory_layer_all:
receiver_memory_feat_number = receiver_memory_feat_number + 1
barValue = receiver_memory_feat_number/float(receiver_memory_feat_total)*25 + 75
bar.setValue(barValue)
rect = QgsRectangle()
rect.setXMinimum(receiver_memory_feat.geometry().asPoint().x() - distance_from_facades)
rect.setXMaximum(receiver_memory_feat.geometry().asPoint().x() + distance_from_facades)
rect.setYMinimum(receiver_memory_feat.geometry().asPoint().y() - distance_from_facades)
rect.setYMaximum(receiver_memory_feat.geometry().asPoint().y() + distance_from_facades)
buildings_selection = buildings_spIndex.intersects(rect)
to_add = True
receiver_geom = receiver_memory_feat.geometry()
building_id_correct = None
for buildings_id in buildings_selection:
building_geom = buildings_feat_all_dict[buildings_id].geometry()
intersectBuilding = QgsGeometry.intersects(receiver_geom, building_geom)
building_id_correct = buildings_id
if intersectBuilding:
to_add = False
building_id_correct = None
break
# picking the nearest building to the receiver point analysed
nearestIds = buildings_spIndex.nearestNeighbor(receiver_geom.asPoint(), 1)
building_fid = []
for featureId in nearestIds:
request = QgsFeatureRequest().setFilterFid(featureId)
for feature in buildings_layer.getFeatures(request):
dist = receiver_geom.distance(feature.geometry())
building_fid.append((dist, feature.id()))
building_fid_correct = min(building_fid, key=lambda x: x[0])[-1]
if to_add:
attributes = [receiver_points_feat_id, building_fid_correct]
fet = QgsFeature()
fet.setGeometry(receiver_memory_feat.geometry())
fet.setAttributes(attributes)
receiver_points_layer_writer.addFeature(fet)
receiver_points_feat_id = receiver_points_feat_id + 1
del receiver_points_layer_writer
receiver_points_layer_name = os.path.splitext(os.path.basename(receiver_points_layer_path))[0]
receiver_points_layer = QgsVectorLayer(receiver_points_layer_path, str(receiver_points_layer_name), "ogr")
QgsProject.instance().addMapLayers([receiver_points_layer])
QgsProject.instance().reloadAllLayers()
def run(sources_layer_path, receivers_layer_path, emission_pts_layer_path, research_ray):
sources_layer = QgsVectorLayer(sources_layer_path, "input layer", "ogr")
receivers_layer = QgsVectorLayer(receivers_layer_path, "output layer", "ogr")
sources_feat_all = sources_layer.dataProvider().getFeatures()
receivers_feat_all_dict = {}
receivers_feat_all = receivers_layer.dataProvider().getFeatures()
receivers_spIndex = QgsSpatialIndex()
for receivers_feat in receivers_feat_all:
receivers_spIndex.insertFeature(receivers_feat)
receivers_feat_all_dict[receivers_feat.id()] = receivers_feat
emission_pts_fields = QgsFields()
emission_pts_fields.append(QgsField("id_emi", QVariant.Int))
emission_pts_fields.append(QgsField("id_emi_source", QVariant.Int))
emission_pts_fields.append(QgsField("id_source", QVariant.Int))
emission_pts_fields.append(QgsField("d_rTOe", QVariant.Double, len=10, prec=2))
# update for QGIS 3 converting VectorWriter to QgsVectorFileWriter
# emission_pts_writer = VectorWriter(emission_pts_layer_path, None, emission_pts_fields, 0, sources_layer.crs())
emission_pts_writer = QgsVectorFileWriter(emission_pts_layer_path, "System",
emission_pts_fields, QgsWkbTypes.Point, sources_layer.crs(),
"ESRI Shapefile")
# initializes ray and emission point id
emission_pt_id = 0
for sources_feat in sources_feat_all:
# researches the receiver points in a rectangle created by the research_ray
# creates the search rectangle
rect = QgsRectangle()
rect.setXMinimum(sources_feat.geometry().boundingBox().xMinimum() - research_ray)
rect.setXMaximum(sources_feat.geometry().boundingBox().xMaximum() + research_ray)
rect.setYMinimum(sources_feat.geometry().boundingBox().yMinimum() - research_ray)
rect.setYMaximum(sources_feat.geometry().boundingBox().yMaximum() + research_ray)
receiver_pts_request = receivers_spIndex.intersects(rect)
distance_min = []
for receiver_pts_id in receiver_pts_request:
receiver_pts_feat = receivers_feat_all_dict[receiver_pts_id]
result = sources_feat.geometry().closestSegmentWithContext(receiver_pts_feat.geometry().asPoint())
distance_min_tmp = sqrt(result[0])
if distance_min_tmp <= research_ray:
distance_min.append(distance_min_tmp)
# defines segment max length
if len(distance_min) >= 1:
segment_max = min(distance_min) / 2
if segment_max < 2:
segment_max = 2
else:
continue
# splits the sources line in emission points at a fix distance (minimum distance/2) and create the emission point layer
# gets vertex
sources_geom = sources_feat.geometry()
if sources_geom.isMultipart():
sources_geom.convertToSingleType()
sources_feat_vertex_pt_all = sources_geom.asPolyline()
emission_pt_id_road = 0
for i in range(0, len(sources_feat_vertex_pt_all)):
pt1 = QgsPointXY(sources_feat_vertex_pt_all[i])
add_point_to_layer(emission_pts_writer, pt1,
[emission_pt_id, emission_pt_id_road, sources_feat.id(), segment_max])
emission_pt_id = emission_pt_id + 1
emission_pt_id_road = emission_pt_id_road + 1
if i < len(sources_feat_vertex_pt_all) - 1:
pt2 = QgsPoint(sources_feat_vertex_pt_all[i + 1])
x1 = pt1.x()
y1 = pt1.y()
x2 = pt2.x()
y2 = pt2.y()
if y2 == y1:
dx = segment_max
dy = 0
m = 0
elif x2 == x1:
dx = 0
dy = segment_max
else:
m = (y2 - y1) / (x2 - x1)
dx = sqrt((segment_max ** 2) / (1 + m ** 2))
dy = sqrt(((segment_max ** 2) * (m ** 2)) / (1 + m ** 2))
pt = pt1
while compute_distance(pt, pt2) > segment_max:
x_temp = pt.x()
y_temp = pt.y()
if x_temp < x2:
if m > 0:
pt = QgsPointXY(x_temp + dx, y_temp + dy)
elif m < 0:
pt = QgsPointXY(x_temp + dx, y_temp - dy)
elif m == 0:
pt = QgsPointXY(x_temp + dx, y_temp)
elif x_temp > x2:
if m > 0:
pt = QgsPointXY(x_temp - dx, y_temp - dy)
elif m < 0:
pt = QgsPointXY(x_temp - dx, y_temp + dy)
elif m == 0:
pt = QgsPointXY(x_temp - dx, y_temp)
elif x_temp == x2:
if y2 > y_temp:
pt = QgsPointXY(x_temp, y_temp + dy)
else:
pt = QgsPointXY(x_temp, y_temp - dy)
add_point_to_layer(emission_pts_writer, pt,
[emission_pt_id, emission_pt_id_road, sources_feat.id(), segment_max])
emission_pt_id = emission_pt_id + 1
emission_pt_id_road = emission_pt_id_road + 1
del emission_pts_writer
def middle(bar,buildings_layer_path,receiver_points_layer_path):
buildings_layer_name = os.path.splitext(os.path.basename(buildings_layer_path))[0]
buildings_layer = QgsVectorLayer(buildings_layer_path,buildings_layer_name,"ogr")
# defines emission_points layer
receiver_points_fields = QgsFields()
receiver_points_fields.append(QgsField("id_pt", QVariant.Int))
receiver_points_fields.append(QgsField("id_bui", QVariant.Int))
receiver_points_writer = QgsVectorFileWriter(receiver_points_layer_path, "System",
receiver_points_fields, QgsWkbTypes.Point, buildings_layer.crs(),"ESRI Shapefile")
# gets features from layer
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
# creates SpatialIndex
buildings_spIndex = QgsSpatialIndex()
buildings_feat_all_dict = {}
for buildings_feat in buildings_feat_all:
buildings_spIndex.insertFeature(buildings_feat)
buildings_feat_all_dict[buildings_feat.id()] = buildings_feat
# defines distanze_point
distance_point = 0.1
# re-gets features from layer
buildings_feat_all = buildings_layer.dataProvider().getFeatures()
buildings_feat_total = buildings_layer.dataProvider().featureCount()
pt_id = 0
buildings_feat_number = 0
for buildings_feat in buildings_feat_all:
buildings_feat_number = buildings_feat_number + 1
barValue = buildings_feat_number/float(buildings_feat_total)*100
bar.setValue(barValue)
building_geom = buildings_feat.geometry()
if building_geom.isMultipart():
buildings_pt = building_geom.asMultiPolygon()[0]
#building_geom.convertToSingleType()
else:
buildings_pt = buildings_feat.geometry().asPolygon()
# creates the search rectangle to match the receiver point in the building and del them
rect = QgsRectangle()
rect.setXMinimum( buildings_feat.geometry().boundingBox().xMinimum() - distance_point )
rect.setXMaximum( buildings_feat.geometry().boundingBox().xMaximum() + distance_point )
rect.setYMinimum( buildings_feat.geometry().boundingBox().yMinimum() - distance_point )
rect.setYMaximum( buildings_feat.geometry().boundingBox().yMaximum() + distance_point )
buildings_selection = buildings_spIndex.intersects(rect)
if len(buildings_pt) > 0:
for i in range(0,len(buildings_pt)):
buildings_pts = buildings_pt[i]
####
# start part to delete pseudo vertex
# this part it's different from the diffraction delete pseudo vertex part
pts_index_to_delete_list = []
m_delta = 0.01
for ii in range(0,len(buildings_pts)-1):
x1 = buildings_pts[ii-1][0]
x2 = buildings_pts[ii][0]
x3 = buildings_pts[ii+1][0]
y1 = buildings_pts[ii-1][1]
y2 = buildings_pts[ii][1]
y3 = buildings_pts[ii+1][1]
# particular cases: first point to delete! (remember that the first and the last have the same coordinates)
if ii == 0 and (x2 == x1 and y2 == y1):
x1 = buildings_pts[ii-2][0]
y1 = buildings_pts[ii-2][1]
# angular coefficient to find pseudo vertex
if x2 - x1 != 0 and x3 - x1 != 0:
m1 = ( y2 - y1 ) / ( x2 - x1 )
m2 = ( y3 - y1 ) / ( x3 - x1 )
#if round(m1,2) <= round(m2,2) + m_delta and round(m1,2) >= round(m2,2) - m_delta:
if m1 <= m2 + m_delta and m1 >= m2 - m_delta:
pts_index_to_delete_list.append(ii)
# particular cases: first point to delete! (remember that the first and the last have the same coordinates)
# here we delete the last and add x3,y3 (buildings_pts[ii+1] - the new last point)
if ii == 0:
pts_index_to_delete_list.append(len(buildings_pts)-1)
buildings_pts.append(buildings_pts[ii+1])
# del pseudo vertex
pts_index_to_delete_list = sorted(pts_index_to_delete_list, reverse=True)
for pt_index_to_del in pts_index_to_delete_list:
del buildings_pts[pt_index_to_del]
# end part to delete pseudo vertex
# for to generate receiver points
for ii in range(0,len(buildings_pts)-1):
x1 = buildings_pts[ii][0]
x2 = buildings_pts[ii+1][0]
y1 = buildings_pts[ii][1]
y2 = buildings_pts[ii+1][1]
xm = ( x1 + x2 )/2
ym = ( y1 + y2 )/2
if y2 == y1:
dx = 0
dy = distance_point
elif x2 == x1:
dx = distance_point
dy = 0
else:
m = ( y2 - y1 )/ ( x2 - x1 )
m_p = -1/m
dx = sqrt((distance_point**2)/(1 + m_p**2))
dy = sqrt(((distance_point**2)*(m_p**2))/(1 + m_p**2))
if (x2 >= x1 and y2 >= y1) or (x2 < x1 and y2 < y1):
pt1 = QgsPointXY(xm + dx, ym - dy)
pt2 = QgsPointXY(xm - dx, ym + dy)
if (x2 >= x1 and y2 < y1) or (x2 < x1 and y2 >= y1):
pt1 = QgsPointXY(xm + dx, ym + dy)
pt2 = QgsPointXY(xm - dx, ym - dy)
pt = QgsFeature()
# pt1, check if is in a building and eventually add it
pt.setGeometry(QgsGeometry.fromPointXY(pt1))
intersect = 0
for buildings_id in buildings_selection:
if buildings_feat_all_dict[buildings_id].geometry().intersects(pt.geometry()) == 1:
intersect = 1
break
if intersect == 0:
pt.setAttributes([pt_id, buildings_feat.id()])
receiver_points_writer.addFeature(pt)
pt_id = pt_id + 1
# pt2, check if is in a building and eventually add it
pt.setGeometry(QgsGeometry.fromPointXY(pt2))
intersect = 0
for buildings_id in buildings_selection:
if buildings_feat_all_dict[buildings_id].geometry().intersects(pt.geometry()) == 1:
intersect = 1
break
if intersect == 0:
pt.setAttributes([pt_id, buildings_feat.id()])
receiver_points_writer.addFeature(pt)
pt_id = pt_id + 1
del receiver_points_writer
#print receiver_points_layer_path
receiver_points_layer_name = os.path.splitext(os.path.basename(receiver_points_layer_path))[0]
#print receiver_points_layer_name
receiver_points_layer = QgsVectorLayer(receiver_points_layer_path, str(receiver_points_layer_name), "ogr")
QgsProject.instance().addMapLayers([receiver_points_layer])
