Mercurial > dive4elements > river
view backend/contrib/shpimporter/hws.py @ 8587:07c9ac22f611
(issue1755) Generalise BedQuality result handling
The bedquality calculation now produces a result for each time period
which has BedQualityResultValues for each specific result type.
Formally this was split up in density, porosity and diameter classes
with some bedload diameter classes mixed in for extra fun.
The intent of this commit is to allow more shared code and generic
access patterns to the BedQuality results.
| author | Andre Heinecke <andre.heinecke@intevation.de> |
|---|---|
| date | Wed, 18 Mar 2015 18:42:08 +0100 |
| parents | 5aa05a7a34b7 |
| children | aef987124822 |
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# -*- coding: utf-8 -*- import os try: from osgeo import ogr except ImportError: import ogr from importer import Importer import utils import logging logger = logging.getLogger("HWS") PATH="Hydrologie/HW-Schutzanlagen" NAME="HWS" # Keep in sync with hws_kinds table: # strings need to be lowercase HWS_KIND = { "durchlass" : 1, "damm" : 2, "deich" : 2, "hochufer" : 2, "graben" : 3, "rohr1" : 1, "rohr 1" : 1, "rohr 2" : 1, "hauptdeich" : 2, "sommerdeich" : 2 } # Keep in sync with fed_states table: # strings need to be lowercase FED_STATES = { "bayern" : 1, "hessen" : 2, "niedersachsen" : 3, "nordrhein-westfalen" : 4, "nordrhein westfalen" : 4, "rheinland-pfalz" : 5, "rheinland pfalz" : 5, "saarland" : 6, "schleswig-holstein" : 7, "schleswig holstein" : 7, "brandenburg" : 8, "mecklenburg-vorpommern" : 9, "mecklenburg vorpommern" : 9, "thüringen" : 10, "baden-württemberg" : 11, "baden württemberg" : 11, "sachsen-anhalt" : 12, "sachsen anhalt" : 12, "sachsen" : 13, "berlin" : 14, "bremen" : 15, "hamburg" : 16, } class HWSPoints(Importer): fieldmap = { "name$" : "name", "quelle$" : "source", "anmerkung$" : "description", "stand$" : "status_date", "verband$" : "agency", "Deich_{0,1}KM$" : "dike_km", "Bereich$" : "range", "H[oeö]{0,2}he_{0,1}SOLL$" : "z_target", "(WSP_){0,1}BfG_{0,1}100$" : "rated_level", "H[oeö]{0,2}he_{0,1}IST$" : "z", } printedforpath=[] def getPath(self, base): return "%s/%s" % (base, PATH) def getTablename(self): return "hws_points" def getName(self): return "HWS_POINTS" def isGeometryValid(self, geomType): return geomType == ogr.wkbPoint or geomType == ogr.wkbPoint25D def isShapeRelevant(self, name, path): shp = ogr.Open(path) return self.isGeometryValid(shp.GetLayerByName(name).GetGeomType()) def getFedStateIDfromPath(self, path): """ Tries to get extract a bundesland from the path """ for state in sorted(FED_STATES.keys(), key = len, reverse = True): if state in path.lower(): if not path in self.printedforpath: logger.info("Extracted federal state from path: %s" % state) self.printedforpath.append(path) return FED_STATES[state] def createNewFeature(self, featureDef, feat, **args): newFeat = ogr.Feature(featureDef) geometry = feat.GetGeometryRef() geometry.SetCoordinateDimension(2) self.copyFields(feat, newFeat, self.fieldmap) newFeat.SetGeometry(geometry) artname = self.searchField("art$") if self.IsFieldSet(feat, artname): self.handled(artname) kind_id = HWS_KIND.get(feat.GetField(artname).lower()) if not kind_id: logger.warn("Unknown Art: %s" % \ feat.GetField(artname)) newFeat.SetField("kind_id", 2) else: newFeat.SetField("kind_id", kind_id) else: newFeat.SetField("kind_id", 2) fname = self.searchField("Bundesland$") if self.IsFieldSet(feat, fname): self.handled(fname) fed_id = FED_STATES.get(feat.GetField(fname).lower()) if not fed_id: logger.warn("Unknown Bundesland: %s" % \ feat.GetField(fname)) else: newFeat.SetField("fed_state_id", fed_id) else: # Try to get the bundesland from path fed_id = self.getFedStateIDfromPath(args['path']) if fed_id: newFeat.SetField("fed_state_id", fed_id) fname = self.searchField("(ufer$)|(flussseite$)") if self.IsFieldSet(feat, fname): self.handled(fname) shoreString = feat.GetField(fname) if "links" in shoreString.lower(): newFeat.SetField("shore_side", True) elif "rechts" in shoreString.lower(): newFeat.SetField("shore_side", False) fname = self.searchField("river_{0,1}id$") if self.IsFieldSet(feat, fname): self.handled(fname) if feat.GetField(fname) != self.river_id: logger.warn("River_id mismatch between shapefile and" " importer parameter.") newFeat.SetField("river_id", feat.GetField(fname)) else: newFeat.SetField("river_id", self.river_id) fname = self.searchField("name$") if not self.IsFieldSet(feat, fname): newFeat.SetField("name", args['name']) fname = self.searchField("offiziell$") if self.IsFieldSet(feat, fname): self.handled(fname) offiziell = feat.GetField(fname) if offiziell == "1" or offiziell == 1: newFeat.SetField("official", True) # Set the official value based on the file name as a fallback elif args.get("name", "").lower() == "rohre_und_sperren" or \ args.get("name", "").lower() == "rohre-und-sperren": newFeat.SetField("official", True) else: newFeat.SetField("official", False) if self.IsFieldSet(newFeat, "z") and \ self.IsFieldSet(newFeat, "rated_level"): fname = self.searchField("freibord(_m){0,1}$") self.handled(fname) z = newFeat.GetFieldAsDouble("z") rl = newFeat.GetFieldAsDouble("rated_level") newFeat.SetField("freeboard", z - rl) return newFeat class HWSLines(HWSPoints): # TODO: GEOM_target, GEOM_rated_level, dike_km_from, dike_km_to fieldmap = { "name$" : "name", "quelle$" : "source", "anmerkung$" : "description", "stand$" : "status_date", "verband$" : "agency", "Bereich$" : "range", } def getPath(self, base): return "%s/%s" % (base, PATH) def getTablename(self): return "hws_lines" def getName(self): return "HWS_LINES" def isGeometryValid(self, geomType): return geomType in [ogr.wkbLineString, ogr.wkbLineString25D, ogr.wkbMultiLineString25D, ogr.wkbMultiLineString] def isShapeRelevant(self, name, path): shp = ogr.Open(path) return self.isGeometryValid(shp.GetLayerByName(name).GetGeomType()) def createNewFeature(self, featureDef, feat, **args): newFeat = HWSPoints.createNewFeature(self, featureDef, feat, **args) geometry = feat.GetGeometryRef() if geometry.GetCoordinateDimension() == 2: geometry.SetCoordinateDimension(3) for i in range(0, geometry.GetPointCount()): x,y,z = geometry.GetPoint(i) z = 9999 geometry.SetPoint(i, x, y, z) newFeat.SetGeometry(geometry) return utils.convertToMultiLine(newFeat)