]> git.openstreetmap.org Git - nominatim.git/blobdiff - nominatim/api/reverse.py
Merge pull request #3159 from lonvia/fix-name-lookup-for-housenames
[nominatim.git] / nominatim / api / reverse.py
index d6976c06c2f8307cae1dcf8fc3f9972672ef557f..63836b4924f18589ddec07b52bc78ff11f942e64 100644 (file)
@@ -7,16 +7,19 @@
 """
 Implementation of reverse geocoding.
 """
 """
 Implementation of reverse geocoding.
 """
-from typing import Optional, List, Callable, Type, Tuple
+from typing import Optional, List, Callable, Type, Tuple, Dict, Any, cast, Union
+import functools
 
 import sqlalchemy as sa
 
 import sqlalchemy as sa
-from geoalchemy2 import WKTElement
 
 
-from nominatim.typing import SaColumn, SaSelect, SaFromClause, SaLabel, SaRow
+from nominatim.typing import SaColumn, SaSelect, SaFromClause, SaLabel, SaRow,\
+                             SaBind, SaLambdaSelect
 from nominatim.api.connection import SearchConnection
 import nominatim.api.results as nres
 from nominatim.api.logging import log
 from nominatim.api.types import AnyPoint, DataLayer, ReverseDetails, GeometryFormat, Bbox
 from nominatim.api.connection import SearchConnection
 import nominatim.api.results as nres
 from nominatim.api.logging import log
 from nominatim.api.types import AnyPoint, DataLayer, ReverseDetails, GeometryFormat, Bbox
+from nominatim.db.sqlalchemy_types import Geometry
+import nominatim.db.sqlalchemy_functions as snfn
 
 # In SQLAlchemy expression which compare with NULL need to be expressed with
 # the equal sign.
 
 # In SQLAlchemy expression which compare with NULL need to be expressed with
 # the equal sign.
@@ -24,20 +27,27 @@ from nominatim.api.types import AnyPoint, DataLayer, ReverseDetails, GeometryFor
 
 RowFunc = Callable[[Optional[SaRow], Type[nres.ReverseResult]], Optional[nres.ReverseResult]]
 
 
 RowFunc = Callable[[Optional[SaRow], Type[nres.ReverseResult]], Optional[nres.ReverseResult]]
 
-def _select_from_placex(t: SaFromClause, wkt: Optional[str] = None) -> SaSelect:
+WKT_PARAM: SaBind = sa.bindparam('wkt', type_=Geometry)
+MAX_RANK_PARAM: SaBind = sa.bindparam('max_rank')
+
+def no_index(expr: SaColumn) -> SaColumn:
+    """ Wrap the given expression, so that the query planner will
+        refrain from using the expression for index lookup.
+    """
+    return sa.func.coalesce(sa.null(), expr) # pylint: disable=not-callable
+
+
+def _select_from_placex(t: SaFromClause, use_wkt: bool = True) -> SaSelect:
     """ Create a select statement with the columns relevant for reverse
         results.
     """
     """ Create a select statement with the columns relevant for reverse
         results.
     """
-    if wkt is None:
+    if not use_wkt:
         distance = t.c.distance
         centroid = t.c.centroid
     else:
         distance = t.c.distance
         centroid = t.c.centroid
     else:
-        distance = t.c.geometry.ST_Distance(wkt)
-        centroid = sa.case(
-                       (t.c.geometry.ST_GeometryType().in_(('ST_LineString',
-                                                           'ST_MultiLineString')),
-                        t.c.geometry.ST_ClosestPoint(wkt)),
-                       else_=t.c.centroid).label('centroid')
+        distance = t.c.geometry.ST_Distance(WKT_PARAM)
+        centroid = sa.case((t.c.geometry.is_line_like(), t.c.geometry.ST_ClosestPoint(WKT_PARAM)),
+                           else_=t.c.centroid).label('centroid')
 
 
     return sa.select(t.c.place_id, t.c.osm_type, t.c.osm_id, t.c.name,
 
 
     return sa.select(t.c.place_id, t.c.osm_type, t.c.osm_id, t.c.name,
@@ -66,22 +76,24 @@ def _interpolated_position(table: SaFromClause) -> SaLabel:
               else_=table.c.linegeo.ST_LineInterpolatePoint(rounded_pos)).label('centroid')
 
 
               else_=table.c.linegeo.ST_LineInterpolatePoint(rounded_pos)).label('centroid')
 
 
-def _locate_interpolation(table: SaFromClause, wkt: WKTElement) -> SaLabel:
+def _locate_interpolation(table: SaFromClause) -> SaLabel:
     """ Given a position, locate the closest point on the line.
     """
     """ Given a position, locate the closest point on the line.
     """
-    return sa.case((table.c.linegeo.ST_GeometryType() == 'ST_LineString',
-                    sa.func.ST_LineLocatePoint(table.c.linegeo, wkt)),
+    return sa.case((table.c.linegeo.is_line_like(),
+                    table.c.linegeo.ST_LineLocatePoint(WKT_PARAM)),
                    else_=0).label('position')
 
 
 def _is_address_point(table: SaFromClause) -> SaColumn:
     return sa.and_(table.c.rank_address == 30,
                    sa.or_(table.c.housenumber != None,
                    else_=0).label('position')
 
 
 def _is_address_point(table: SaFromClause) -> SaColumn:
     return sa.and_(table.c.rank_address == 30,
                    sa.or_(table.c.housenumber != None,
-                          table.c.name.has_key('housename')))
+                          table.c.name.has_key('addr:housename')))
+
 
 def _get_closest(*rows: Optional[SaRow]) -> Optional[SaRow]:
     return min(rows, key=lambda row: 1000 if row is None else row.distance)
 
 
 def _get_closest(*rows: Optional[SaRow]) -> Optional[SaRow]:
     return min(rows, key=lambda row: 1000 if row is None else row.distance)
 
+
 class ReverseGeocoder:
     """ Class implementing the logic for looking up a place from a
         coordinate.
 class ReverseGeocoder:
     """ Class implementing the logic for looking up a place from a
         coordinate.
@@ -91,6 +103,8 @@ class ReverseGeocoder:
         self.conn = conn
         self.params = params
 
         self.conn = conn
         self.params = params
 
+        self.bind_params: Dict[str, Any] = {'max_rank': params.max_rank}
+
 
     @property
     def max_rank(self) -> int:
 
     @property
     def max_rank(self) -> int:
@@ -122,23 +136,21 @@ class ReverseGeocoder:
         """
         return self.layer_enabled(DataLayer.RAILWAY, DataLayer.MANMADE, DataLayer.NATURAL)
 
         """
         return self.layer_enabled(DataLayer.RAILWAY, DataLayer.MANMADE, DataLayer.NATURAL)
 
-    def _add_geometry_columns(self, sql: SaSelect, col: SaColumn) -> SaSelect:
-        if not self.has_geometries():
-            return sql
 
 
+    def _add_geometry_columns(self, sql: SaLambdaSelect, col: SaColumn) -> SaSelect:
         out = []
 
         if self.params.geometry_simplification > 0.0:
         out = []
 
         if self.params.geometry_simplification > 0.0:
-            col = col.ST_SimplifyPreserveTopology(self.params.geometry_simplification)
+            col = sa.func.ST_SimplifyPreserveTopology(col, self.params.geometry_simplification)
 
         if self.params.geometry_output & GeometryFormat.GEOJSON:
 
         if self.params.geometry_output & GeometryFormat.GEOJSON:
-            out.append(col.ST_AsGeoJSON().label('geometry_geojson'))
+            out.append(sa.func.ST_AsGeoJSON(col).label('geometry_geojson'))
         if self.params.geometry_output & GeometryFormat.TEXT:
         if self.params.geometry_output & GeometryFormat.TEXT:
-            out.append(col.ST_AsText().label('geometry_text'))
+            out.append(sa.func.ST_AsText(col).label('geometry_text'))
         if self.params.geometry_output & GeometryFormat.KML:
         if self.params.geometry_output & GeometryFormat.KML:
-            out.append(col.ST_AsKML().label('geometry_kml'))
+            out.append(sa.func.ST_AsKML(col).label('geometry_kml'))
         if self.params.geometry_output & GeometryFormat.SVG:
         if self.params.geometry_output & GeometryFormat.SVG:
-            out.append(col.ST_AsSVG().label('geometry_svg'))
+            out.append(sa.func.ST_AsSVG(col).label('geometry_svg'))
 
         return sql.add_columns(*out)
 
 
         return sql.add_columns(*out)
 
@@ -160,136 +172,143 @@ class ReverseGeocoder:
         return table.c.class_.in_(tuple(include))
 
 
         return table.c.class_.in_(tuple(include))
 
 
-    async def _find_closest_street_or_poi(self, wkt: WKTElement,
-                                          distance: float) -> Optional[SaRow]:
+    async def _find_closest_street_or_poi(self, distance: float) -> Optional[SaRow]:
         """ Look up the closest rank 26+ place in the database, which
             is closer than the given distance.
         """
         t = self.conn.t.placex
 
         """ Look up the closest rank 26+ place in the database, which
             is closer than the given distance.
         """
         t = self.conn.t.placex
 
-        sql = _select_from_placex(t, wkt)\
-                .where(t.c.geometry.ST_DWithin(wkt, distance))\
-                .where(t.c.indexed_status == 0)\
-                .where(t.c.linked_place_id == None)\
-                .where(sa.or_(t.c.geometry.ST_GeometryType()
-                                          .not_in(('ST_Polygon', 'ST_MultiPolygon')),
-                              t.c.centroid.ST_Distance(wkt) < distance))\
-                .order_by('distance')\
-                .limit(1)
+        # PostgreSQL must not get the distance as a parameter because
+        # there is a danger it won't be able to proberly estimate index use
+        # when used with prepared statements
+        diststr = sa.text(f"{distance}")
 
 
-        sql = self._add_geometry_columns(sql, t.c.geometry)
+        sql: SaLambdaSelect = sa.lambda_stmt(lambda: _select_from_placex(t)
+                .where(t.c.geometry.ST_DWithin(WKT_PARAM, diststr))
+                .where(t.c.indexed_status == 0)
+                .where(t.c.linked_place_id == None)
+                .where(sa.or_(sa.not_(t.c.geometry.is_area()),
+                              t.c.centroid.ST_Distance(WKT_PARAM) < diststr))
+                .order_by('distance')
+                .limit(1))
 
 
-        restrict: List[SaColumn] = []
+        if self.has_geometries():
+            sql = self._add_geometry_columns(sql, t.c.geometry)
+
+        restrict: List[Union[SaColumn, Callable[[], SaColumn]]] = []
 
         if self.layer_enabled(DataLayer.ADDRESS):
 
         if self.layer_enabled(DataLayer.ADDRESS):
-            restrict.append(sa.and_(t.c.rank_address >= 26,
-                                    t.c.rank_address <= min(29, self.max_rank)))
+            max_rank = min(29, self.max_rank)
+            restrict.append(lambda: no_index(t.c.rank_address).between(26, max_rank))
             if self.max_rank == 30:
             if self.max_rank == 30:
-                restrict.append(_is_address_point(t))
+                restrict.append(lambda: _is_address_point(t))
         if self.layer_enabled(DataLayer.POI) and self.max_rank == 30:
         if self.layer_enabled(DataLayer.POI) and self.max_rank == 30:
-            restrict.append(sa.and_(t.c.rank_search == 30,
-                                    t.c.class_.not_in(('place', 'building')),
-                                    t.c.geometry.ST_GeometryType() != 'ST_LineString'))
+            restrict.append(lambda: sa.and_(no_index(t.c.rank_search) == 30,
+                                            t.c.class_.not_in(('place', 'building')),
+                                            sa.not_(t.c.geometry.is_line_like())))
         if self.has_feature_layers():
         if self.has_feature_layers():
-            restrict.append(sa.and_(t.c.rank_search.between(26, self.max_rank),
-                                    t.c.rank_address == 0,
+            restrict.append(sa.and_(no_index(t.c.rank_search).between(26, MAX_RANK_PARAM),
+                                    no_index(t.c.rank_address) == 0,
                                     self._filter_by_layer(t)))
 
         if not restrict:
             return None
 
                                     self._filter_by_layer(t)))
 
         if not restrict:
             return None
 
-        return (await self.conn.execute(sql.where(sa.or_(*restrict)))).one_or_none()
+        sql = sql.where(sa.or_(*restrict))
+
+        return (await self.conn.execute(sql, self.bind_params)).one_or_none()
 
 
 
 
-    async def _find_housenumber_for_street(self, parent_place_id: int,
-                                           wkt: WKTElement) -> Optional[SaRow]:
+    async def _find_housenumber_for_street(self, parent_place_id: int) -> Optional[SaRow]:
         t = self.conn.t.placex
 
         t = self.conn.t.placex
 
-        sql = _select_from_placex(t, wkt)\
-                .where(t.c.geometry.ST_DWithin(wkt, 0.001))\
-                .where(t.c.parent_place_id == parent_place_id)\
-                .where(_is_address_point(t))\
-                .where(t.c.indexed_status == 0)\
-                .where(t.c.linked_place_id == None)\
-                .order_by('distance')\
-                .limit(1)
+        sql: SaLambdaSelect = sa.lambda_stmt(lambda: _select_from_placex(t)
+                .where(t.c.geometry.ST_DWithin(WKT_PARAM, 0.001))
+                .where(t.c.parent_place_id == parent_place_id)
+                .where(_is_address_point(t))
+                .where(t.c.indexed_status == 0)
+                .where(t.c.linked_place_id == None)
+                .order_by('distance')
+                .limit(1))
 
 
-        sql = self._add_geometry_columns(sql, t.c.geometry)
+        if self.has_geometries():
+            sql = self._add_geometry_columns(sql, t.c.geometry)
 
 
-        return (await self.conn.execute(sql)).one_or_none()
+        return (await self.conn.execute(sql, self.bind_params)).one_or_none()
 
 
     async def _find_interpolation_for_street(self, parent_place_id: Optional[int],
 
 
     async def _find_interpolation_for_street(self, parent_place_id: Optional[int],
-                                             wkt: WKTElement,
                                              distance: float) -> Optional[SaRow]:
         t = self.conn.t.osmline
 
                                              distance: float) -> Optional[SaRow]:
         t = self.conn.t.osmline
 
-        sql = sa.select(t,
-                        t.c.linegeo.ST_Distance(wkt).label('distance'),
-                        _locate_interpolation(t, wkt))\
-                .where(t.c.linegeo.ST_DWithin(wkt, distance))\
-                .where(t.c.startnumber != None)\
-                .order_by('distance')\
-                .limit(1)
+        sql: Any = sa.lambda_stmt(lambda:
+                   sa.select(t,
+                             t.c.linegeo.ST_Distance(WKT_PARAM).label('distance'),
+                             _locate_interpolation(t))
+                     .where(t.c.linegeo.ST_DWithin(WKT_PARAM, distance))
+                     .where(t.c.startnumber != None)
+                     .order_by('distance')
+                     .limit(1))
 
         if parent_place_id is not None:
 
         if parent_place_id is not None:
-            sql = sql.where(t.c.parent_place_id == parent_place_id)
+            sql += lambda s: s.where(t.c.parent_place_id == parent_place_id)
+
+        def _wrap_query(base_sql: SaLambdaSelect) -> SaSelect:
+            inner = base_sql.subquery('ipol')
 
 
-        inner = sql.subquery('ipol')
+            return sa.select(inner.c.place_id, inner.c.osm_id,
+                             inner.c.parent_place_id, inner.c.address,
+                             _interpolated_housenumber(inner),
+                             _interpolated_position(inner),
+                             inner.c.postcode, inner.c.country_code,
+                             inner.c.distance)
 
 
-        sql = sa.select(inner.c.place_id, inner.c.osm_id,
-                        inner.c.parent_place_id, inner.c.address,
-                        _interpolated_housenumber(inner),
-                        _interpolated_position(inner),
-                        inner.c.postcode, inner.c.country_code,
-                        inner.c.distance)
+        sql += _wrap_query
 
         if self.has_geometries():
             sub = sql.subquery('geom')
             sql = self._add_geometry_columns(sa.select(sub), sub.c.centroid)
 
 
         if self.has_geometries():
             sub = sql.subquery('geom')
             sql = self._add_geometry_columns(sa.select(sub), sub.c.centroid)
 
-        return (await self.conn.execute(sql)).one_or_none()
+        return (await self.conn.execute(sql, self.bind_params)).one_or_none()
 
 
 
 
-    async def _find_tiger_number_for_street(self, parent_place_id: int,
-                                            parent_type: str, parent_id: int,
-                                            wkt: WKTElement) -> Optional[SaRow]:
+    async def _find_tiger_number_for_street(self, parent_place_id: int) -> Optional[SaRow]:
         t = self.conn.t.tiger
 
         t = self.conn.t.tiger
 
-        inner = sa.select(t,
-                          t.c.linegeo.ST_Distance(wkt).label('distance'),
-                          _locate_interpolation(t, wkt))\
-                  .where(t.c.linegeo.ST_DWithin(wkt, 0.001))\
-                  .where(t.c.parent_place_id == parent_place_id)\
-                  .order_by('distance')\
-                  .limit(1)\
-                  .subquery('tiger')
-
-        sql = sa.select(inner.c.place_id,
-                        inner.c.parent_place_id,
-                        sa.literal(parent_type).label('osm_type'),
-                        sa.literal(parent_id).label('osm_id'),
-                        _interpolated_housenumber(inner),
-                        _interpolated_position(inner),
-                        inner.c.postcode,
-                        inner.c.distance)
+        def _base_query() -> SaSelect:
+            inner = sa.select(t,
+                              t.c.linegeo.ST_Distance(WKT_PARAM).label('distance'),
+                              _locate_interpolation(t))\
+                      .where(t.c.linegeo.ST_DWithin(WKT_PARAM, 0.001))\
+                      .where(t.c.parent_place_id == parent_place_id)\
+                      .order_by('distance')\
+                      .limit(1)\
+                      .subquery('tiger')
+
+            return sa.select(inner.c.place_id,
+                             inner.c.parent_place_id,
+                             _interpolated_housenumber(inner),
+                             _interpolated_position(inner),
+                             inner.c.postcode,
+                             inner.c.distance)
+
+        sql: SaLambdaSelect = sa.lambda_stmt(_base_query)
 
         if self.has_geometries():
             sub = sql.subquery('geom')
             sql = self._add_geometry_columns(sa.select(sub), sub.c.centroid)
 
 
         if self.has_geometries():
             sub = sql.subquery('geom')
             sql = self._add_geometry_columns(sa.select(sub), sub.c.centroid)
 
-        return (await self.conn.execute(sql)).one_or_none()
+        return (await self.conn.execute(sql, self.bind_params)).one_or_none()
 
 
 
 
-    async def lookup_street_poi(self,
-                                wkt: WKTElement) -> Tuple[Optional[SaRow], RowFunc]:
+    async def lookup_street_poi(self) -> Tuple[Optional[SaRow], RowFunc]:
         """ Find a street or POI/address for the given WKT point.
         """
         log().section('Reverse lookup on street/address level')
         distance = 0.006
         parent_place_id = None
 
         """ Find a street or POI/address for the given WKT point.
         """
         log().section('Reverse lookup on street/address level')
         distance = 0.006
         parent_place_id = None
 
-        row = await self._find_closest_street_or_poi(wkt, distance)
+        row = await self._find_closest_street_or_poi(distance)
         row_func: RowFunc = nres.create_from_placex_row
         log().var_dump('Result (street/building)', row)
 
         row_func: RowFunc = nres.create_from_placex_row
         log().var_dump('Result (street/building)', row)
 
@@ -302,7 +321,7 @@ class ReverseGeocoder:
                 distance = 0.001
                 parent_place_id = row.place_id
                 log().comment('Find housenumber for street')
                 distance = 0.001
                 parent_place_id = row.place_id
                 log().comment('Find housenumber for street')
-                addr_row = await self._find_housenumber_for_street(parent_place_id, wkt)
+                addr_row = await self._find_housenumber_for_street(parent_place_id)
                 log().var_dump('Result (street housenumber)', addr_row)
 
                 if addr_row is not None:
                 log().var_dump('Result (street housenumber)', addr_row)
 
                 if addr_row is not None:
@@ -311,15 +330,15 @@ class ReverseGeocoder:
                     distance = addr_row.distance
                 elif row.country_code == 'us' and parent_place_id is not None:
                     log().comment('Find TIGER housenumber for street')
                     distance = addr_row.distance
                 elif row.country_code == 'us' and parent_place_id is not None:
                     log().comment('Find TIGER housenumber for street')
-                    addr_row = await self._find_tiger_number_for_street(parent_place_id,
-                                                                        row.osm_type,
-                                                                        row.osm_id,
-                                                                        wkt)
+                    addr_row = await self._find_tiger_number_for_street(parent_place_id)
                     log().var_dump('Result (street Tiger housenumber)', addr_row)
 
                     if addr_row is not None:
                     log().var_dump('Result (street Tiger housenumber)', addr_row)
 
                     if addr_row is not None:
+                        row_func = cast(RowFunc,
+                                        functools.partial(nres.create_from_tiger_row,
+                                                          osm_type=row.osm_type,
+                                                          osm_id=row.osm_id))
                         row = addr_row
                         row = addr_row
-                        row_func = nres.create_from_tiger_row
             else:
                 distance = row.distance
 
             else:
                 distance = row.distance
 
@@ -328,7 +347,7 @@ class ReverseGeocoder:
         if self.max_rank > 27 and self.layer_enabled(DataLayer.ADDRESS):
             log().comment('Find interpolation for street')
             addr_row = await self._find_interpolation_for_street(parent_place_id,
         if self.max_rank > 27 and self.layer_enabled(DataLayer.ADDRESS):
             log().comment('Find interpolation for street')
             addr_row = await self._find_interpolation_for_street(parent_place_id,
-                                                                 wkt, distance)
+                                                                 distance)
             log().var_dump('Result (street interpolation)', addr_row)
             if addr_row is not None:
                 row = addr_row
             log().var_dump('Result (street interpolation)', addr_row)
             if addr_row is not None:
                 row = addr_row
@@ -337,67 +356,69 @@ class ReverseGeocoder:
         return row, row_func
 
 
         return row, row_func
 
 
-    async def _lookup_area_address(self, wkt: WKTElement) -> Optional[SaRow]:
+    async def _lookup_area_address(self) -> Optional[SaRow]:
         """ Lookup large addressable areas for the given WKT point.
         """
         log().comment('Reverse lookup by larger address area features')
         t = self.conn.t.placex
 
         """ Lookup large addressable areas for the given WKT point.
         """
         log().comment('Reverse lookup by larger address area features')
         t = self.conn.t.placex
 
-        # The inner SQL brings results in the right order, so that
-        # later only a minimum of results needs to be checked with ST_Contains.
-        inner = sa.select(t, sa.literal(0.0).label('distance'))\
-                  .where(t.c.rank_search.between(5, self.max_rank))\
-                  .where(t.c.rank_address.between(5, 25))\
-                  .where(t.c.geometry.ST_GeometryType().in_(('ST_Polygon', 'ST_MultiPolygon')))\
-                  .where(t.c.geometry.intersects(wkt))\
-                  .where(t.c.name != None)\
-                  .where(t.c.indexed_status == 0)\
-                  .where(t.c.linked_place_id == None)\
-                  .where(t.c.type != 'postcode')\
-                  .order_by(sa.desc(t.c.rank_search))\
-                  .limit(50)\
-                  .subquery('area')
+        def _base_query() -> SaSelect:
+            # The inner SQL brings results in the right order, so that
+            # later only a minimum of results needs to be checked with ST_Contains.
+            inner = sa.select(t, sa.literal(0.0).label('distance'))\
+                      .where(t.c.rank_search.between(5, MAX_RANK_PARAM))\
+                      .where(t.c.geometry.intersects(WKT_PARAM))\
+                      .where(snfn.select_index_placex_geometry_reverse_lookuppolygon('placex'))\
+                      .order_by(sa.desc(t.c.rank_search))\
+                      .limit(50)\
+                      .subquery('area')
 
 
-        sql = _select_from_placex(inner)\
-                  .where(inner.c.geometry.ST_Contains(wkt))\
-                  .order_by(sa.desc(inner.c.rank_search))\
-                  .limit(1)
+            return _select_from_placex(inner, False)\
+                      .where(inner.c.geometry.ST_Contains(WKT_PARAM))\
+                      .order_by(sa.desc(inner.c.rank_search))\
+                      .limit(1)
 
 
-        sql = self._add_geometry_columns(sql, inner.c.geometry)
+        sql: SaLambdaSelect = sa.lambda_stmt(_base_query)
+        if self.has_geometries():
+            sql = self._add_geometry_columns(sql, sa.literal_column('area.geometry'))
 
 
-        address_row = (await self.conn.execute(sql)).one_or_none()
+        address_row = (await self.conn.execute(sql, self.bind_params)).one_or_none()
         log().var_dump('Result (area)', address_row)
 
         if address_row is not None and address_row.rank_search < self.max_rank:
             log().comment('Search for better matching place nodes inside the area')
         log().var_dump('Result (area)', address_row)
 
         if address_row is not None and address_row.rank_search < self.max_rank:
             log().comment('Search for better matching place nodes inside the area')
-            inner = sa.select(t,
-                              t.c.geometry.ST_Distance(wkt).label('distance'))\
-                      .where(t.c.osm_type == 'N')\
-                      .where(t.c.rank_search > address_row.rank_search)\
-                      .where(t.c.rank_search <= self.max_rank)\
-                      .where(t.c.rank_address.between(5, 25))\
-                      .where(t.c.name != None)\
+
+            address_rank = address_row.rank_search
+            address_id = address_row.place_id
+
+            def _place_inside_area_query() -> SaSelect:
+                inner = \
+                    sa.select(t,
+                              t.c.geometry.ST_Distance(WKT_PARAM).label('distance'))\
+                      .where(t.c.rank_search > address_rank)\
+                      .where(t.c.rank_search <= MAX_RANK_PARAM)\
                       .where(t.c.indexed_status == 0)\
                       .where(t.c.indexed_status == 0)\
-                      .where(t.c.linked_place_id == None)\
-                      .where(t.c.type != 'postcode')\
+                      .where(snfn.select_index_placex_geometry_reverse_lookupplacenode('placex'))\
                       .where(t.c.geometry
                                 .ST_Buffer(sa.func.reverse_place_diameter(t.c.rank_search))
                       .where(t.c.geometry
                                 .ST_Buffer(sa.func.reverse_place_diameter(t.c.rank_search))
-                                .intersects(wkt))\
+                                .intersects(WKT_PARAM))\
                       .order_by(sa.desc(t.c.rank_search))\
                       .limit(50)\
                       .subquery('places')
 
                       .order_by(sa.desc(t.c.rank_search))\
                       .limit(50)\
                       .subquery('places')
 
-            touter = self.conn.t.placex.alias('outer')
-            sql = _select_from_placex(inner)\
-                  .join(touter, touter.c.geometry.ST_Contains(inner.c.geometry))\
-                  .where(touter.c.place_id == address_row.place_id)\
-                  .where(inner.c.distance < sa.func.reverse_place_diameter(inner.c.rank_search))\
-                  .order_by(sa.desc(inner.c.rank_search), inner.c.distance)\
-                  .limit(1)
+                touter = t.alias('outer')
+                return _select_from_placex(inner, False)\
+                    .join(touter, touter.c.geometry.ST_Contains(inner.c.geometry))\
+                    .where(touter.c.place_id == address_id)\
+                    .where(inner.c.distance < sa.func.reverse_place_diameter(inner.c.rank_search))\
+                    .order_by(sa.desc(inner.c.rank_search), inner.c.distance)\
+                    .limit(1)
 
 
-            sql = self._add_geometry_columns(sql, inner.c.geometry)
+            sql = sa.lambda_stmt(_place_inside_area_query)
+            if self.has_geometries():
+                sql = self._add_geometry_columns(sql, sa.literal_column('places.geometry'))
 
 
-            place_address_row = (await self.conn.execute(sql)).one_or_none()
+            place_address_row = (await self.conn.execute(sql, self.bind_params)).one_or_none()
             log().var_dump('Result (place node)', place_address_row)
 
             if place_address_row is not None:
             log().var_dump('Result (place node)', place_address_row)
 
             if place_address_row is not None:
@@ -406,65 +427,65 @@ class ReverseGeocoder:
         return address_row
 
 
         return address_row
 
 
-    async def _lookup_area_others(self, wkt: WKTElement) -> Optional[SaRow]:
+    async def _lookup_area_others(self) -> Optional[SaRow]:
         t = self.conn.t.placex
 
         t = self.conn.t.placex
 
-        inner = sa.select(t, t.c.geometry.ST_Distance(wkt).label('distance'))\
+        inner = sa.select(t, t.c.geometry.ST_Distance(WKT_PARAM).label('distance'))\
                   .where(t.c.rank_address == 0)\
                   .where(t.c.rank_address == 0)\
-                  .where(t.c.rank_search.between(5, self.max_rank))\
+                  .where(t.c.rank_search.between(5, MAX_RANK_PARAM))\
                   .where(t.c.name != None)\
                   .where(t.c.indexed_status == 0)\
                   .where(t.c.linked_place_id == None)\
                   .where(self._filter_by_layer(t))\
                   .where(t.c.geometry
                                 .ST_Buffer(sa.func.reverse_place_diameter(t.c.rank_search))
                   .where(t.c.name != None)\
                   .where(t.c.indexed_status == 0)\
                   .where(t.c.linked_place_id == None)\
                   .where(self._filter_by_layer(t))\
                   .where(t.c.geometry
                                 .ST_Buffer(sa.func.reverse_place_diameter(t.c.rank_search))
-                                .intersects(wkt))\
+                                .intersects(WKT_PARAM))\
                   .order_by(sa.desc(t.c.rank_search))\
                   .limit(50)\
                   .subquery()
 
                   .order_by(sa.desc(t.c.rank_search))\
                   .limit(50)\
                   .subquery()
 
-        sql = _select_from_placex(inner)\
-                  .where(sa.or_(inner.c.geometry.ST_GeometryType()
-                                                .not_in(('ST_Polygon', 'ST_MultiPolygon')),
-                                inner.c.geometry.ST_Contains(wkt)))\
+        sql = _select_from_placex(inner, False)\
+                  .where(sa.or_(sa.not_(inner.c.geometry.is_area()),
+                                inner.c.geometry.ST_Contains(WKT_PARAM)))\
                   .order_by(sa.desc(inner.c.rank_search), inner.c.distance)\
                   .limit(1)
 
                   .order_by(sa.desc(inner.c.rank_search), inner.c.distance)\
                   .limit(1)
 
-        sql = self._add_geometry_columns(sql, inner.c.geometry)
+        if self.has_geometries():
+            sql = self._add_geometry_columns(sql, inner.c.geometry)
 
 
-        row = (await self.conn.execute(sql)).one_or_none()
+        row = (await self.conn.execute(sql, self.bind_params)).one_or_none()
         log().var_dump('Result (non-address feature)', row)
 
         return row
 
 
         log().var_dump('Result (non-address feature)', row)
 
         return row
 
 
-    async def lookup_area(self, wkt: WKTElement) -> Optional[SaRow]:
-        """ Lookup large areas for the given WKT point.
+    async def lookup_area(self) -> Optional[SaRow]:
+        """ Lookup large areas for the current search.
         """
         log().section('Reverse lookup by larger area features')
 
         if self.layer_enabled(DataLayer.ADDRESS):
         """
         log().section('Reverse lookup by larger area features')
 
         if self.layer_enabled(DataLayer.ADDRESS):
-            address_row = await self._lookup_area_address(wkt)
+            address_row = await self._lookup_area_address()
         else:
             address_row = None
 
         if self.has_feature_layers():
         else:
             address_row = None
 
         if self.has_feature_layers():
-            other_row = await self._lookup_area_others(wkt)
+            other_row = await self._lookup_area_others()
         else:
             other_row = None
 
         return _get_closest(address_row, other_row)
 
 
         else:
             other_row = None
 
         return _get_closest(address_row, other_row)
 
 
-    async def lookup_country(self, wkt: WKTElement) -> Optional[SaRow]:
-        """ Lookup the country for the given WKT point.
+    async def lookup_country(self) -> Optional[SaRow]:
+        """ Lookup the country for the current search.
         """
         log().section('Reverse lookup by country code')
         t = self.conn.t.country_grid
         """
         log().section('Reverse lookup by country code')
         t = self.conn.t.country_grid
-        sql = sa.select(t.c.country_code).distinct()\
-                .where(t.c.geometry.ST_Contains(wkt))
+        sql: SaLambdaSelect = sa.select(t.c.country_code).distinct()\
+                .where(t.c.geometry.ST_Contains(WKT_PARAM))
 
 
-        ccodes = tuple((r[0] for r in await self.conn.execute(sql)))
+        ccodes = tuple((r[0] for r in await self.conn.execute(sql, self.bind_params)))
         log().var_dump('Country codes', ccodes)
 
         if not ccodes:
         log().var_dump('Country codes', ccodes)
 
         if not ccodes:
@@ -474,49 +495,50 @@ class ReverseGeocoder:
         if self.max_rank > 4:
             log().comment('Search for place nodes in country')
 
         if self.max_rank > 4:
             log().comment('Search for place nodes in country')
 
-            inner = sa.select(t,
-                              t.c.geometry.ST_Distance(wkt).label('distance'))\
-                      .where(t.c.osm_type == 'N')\
+            def _base_query() -> SaSelect:
+                inner = \
+                    sa.select(t,
+                              t.c.geometry.ST_Distance(WKT_PARAM).label('distance'))\
                       .where(t.c.rank_search > 4)\
                       .where(t.c.rank_search > 4)\
-                      .where(t.c.rank_search <= self.max_rank)\
-                      .where(t.c.rank_address.between(5, 25))\
-                      .where(t.c.name != None)\
+                      .where(t.c.rank_search <= MAX_RANK_PARAM)\
                       .where(t.c.indexed_status == 0)\
                       .where(t.c.indexed_status == 0)\
-                      .where(t.c.linked_place_id == None)\
-                      .where(t.c.type != 'postcode')\
                       .where(t.c.country_code.in_(ccodes))\
                       .where(t.c.country_code.in_(ccodes))\
+                      .where(snfn.select_index_placex_geometry_reverse_lookupplacenode('placex'))\
                       .where(t.c.geometry
                                 .ST_Buffer(sa.func.reverse_place_diameter(t.c.rank_search))
                       .where(t.c.geometry
                                 .ST_Buffer(sa.func.reverse_place_diameter(t.c.rank_search))
-                                .intersects(wkt))\
+                                .intersects(WKT_PARAM))\
                       .order_by(sa.desc(t.c.rank_search))\
                       .limit(50)\
                       .order_by(sa.desc(t.c.rank_search))\
                       .limit(50)\
-                      .subquery()
+                      .subquery('area')
 
 
-            sql = _select_from_placex(inner)\
-                  .where(inner.c.distance < sa.func.reverse_place_diameter(inner.c.rank_search))\
-                  .order_by(sa.desc(inner.c.rank_search), inner.c.distance)\
-                  .limit(1)
+                return _select_from_placex(inner, False)\
+                    .where(inner.c.distance < sa.func.reverse_place_diameter(inner.c.rank_search))\
+                    .order_by(sa.desc(inner.c.rank_search), inner.c.distance)\
+                    .limit(1)
 
 
-            sql = self._add_geometry_columns(sql, inner.c.geometry)
+            sql = sa.lambda_stmt(_base_query)
+            if self.has_geometries():
+                sql = self._add_geometry_columns(sql, sa.literal_column('area.geometry'))
 
 
-            address_row = (await self.conn.execute(sql)).one_or_none()
+            address_row = (await self.conn.execute(sql, self.bind_params)).one_or_none()
             log().var_dump('Result (addressable place node)', address_row)
         else:
             address_row = None
 
         if address_row is None:
             # Still nothing, then return a country with the appropriate country code.
             log().var_dump('Result (addressable place node)', address_row)
         else:
             address_row = None
 
         if address_row is None:
             # Still nothing, then return a country with the appropriate country code.
-            sql = _select_from_placex(t, wkt)\
+            sql = sa.lambda_stmt(lambda: _select_from_placex(t)\
                       .where(t.c.country_code.in_(ccodes))\
                       .where(t.c.rank_address == 4)\
                       .where(t.c.rank_search == 4)\
                       .where(t.c.linked_place_id == None)\
                       .order_by('distance')\
                       .where(t.c.country_code.in_(ccodes))\
                       .where(t.c.rank_address == 4)\
                       .where(t.c.rank_search == 4)\
                       .where(t.c.linked_place_id == None)\
                       .order_by('distance')\
-                      .limit(1)
+                      .limit(1))
 
 
-            sql = self._add_geometry_columns(sql, t.c.geometry)
+            if self.has_geometries():
+                sql = self._add_geometry_columns(sql, t.c.geometry)
 
 
-            address_row = (await self.conn.execute(sql)).one_or_none()
+            address_row = (await self.conn.execute(sql, self.bind_params)).one_or_none()
 
         return address_row
 
 
         return address_row
 
@@ -528,26 +550,26 @@ class ReverseGeocoder:
         log().function('reverse_lookup', coord=coord, params=self.params)
 
 
         log().function('reverse_lookup', coord=coord, params=self.params)
 
 
-        wkt = WKTElement(f'POINT({coord[0]} {coord[1]})', srid=4326)
+        self.bind_params['wkt'] = f'POINT({coord[0]} {coord[1]})'
 
         row: Optional[SaRow] = None
         row_func: RowFunc = nres.create_from_placex_row
 
         if self.max_rank >= 26:
 
         row: Optional[SaRow] = None
         row_func: RowFunc = nres.create_from_placex_row
 
         if self.max_rank >= 26:
-            row, tmp_row_func = await self.lookup_street_poi(wkt)
+            row, tmp_row_func = await self.lookup_street_poi()
             if row is not None:
                 row_func = tmp_row_func
         if row is None and self.max_rank > 4:
             if row is not None:
                 row_func = tmp_row_func
         if row is None and self.max_rank > 4:
-            row = await self.lookup_area(wkt)
+            row = await self.lookup_area()
         if row is None and self.layer_enabled(DataLayer.ADDRESS):
         if row is None and self.layer_enabled(DataLayer.ADDRESS):
-            row = await self.lookup_country(wkt)
+            row = await self.lookup_country()
 
         result = row_func(row, nres.ReverseResult)
         if result is not None:
             assert row is not None
             result.distance = row.distance
             if hasattr(row, 'bbox'):
 
         result = row_func(row, nres.ReverseResult)
         if result is not None:
             assert row is not None
             result.distance = row.distance
             if hasattr(row, 'bbox'):
-                result.bbox = Bbox.from_wkb(row.bbox.data)
-            await nres.add_result_details(self.conn, result, self.params)
+                result.bbox = Bbox.from_wkb(row.bbox)
+            await nres.add_result_details(self.conn, [result], self.params)
 
         return result
 
         return result