@compiles(PlacexGeometryReverseLookuppolygon) # type: ignore[no-untyped-call, misc]
-def _default_intersects(element: SaColumn,
+def _default_intersects(element: PlacexGeometryReverseLookuppolygon,
compiler: 'sa.Compiled', **kw: Any) -> str:
return ("(ST_GeometryType(placex.geometry) in ('ST_Polygon', 'ST_MultiPolygon')"
" AND placex.rank_address between 4 and 25"
@compiles(PlacexGeometryReverseLookuppolygon, 'sqlite') # type: ignore[no-untyped-call, misc]
-def _sqlite_intersects(element: SaColumn,
+def _sqlite_intersects(element: PlacexGeometryReverseLookuppolygon,
compiler: 'sa.Compiled', **kw: Any) -> str:
return ("(ST_GeometryType(placex.geometry) in ('POLYGON', 'MULTIPOLYGON')"
" AND placex.rank_address between 4 and 25"
inherit_cache = True
def __init__(self, table: sa.Table, geom: SaColumn) -> None:
- super().__init__(table.c.geometry, # type: ignore[no-untyped-call]
+ super().__init__(table.c.geometry,
table.c.rank_search, geom)
self.tablename = table.name
@compiles(IntersectsReverseDistance) # type: ignore[no-untyped-call, misc]
-def default_reverse_place_diameter(element: SaColumn,
+def default_reverse_place_diameter(element: IntersectsReverseDistance,
compiler: 'sa.Compiled', **kw: Any) -> str:
table = element.tablename
return f"({table}.rank_address between 4 and 25"\
@compiles(IntersectsReverseDistance, 'sqlite') # type: ignore[no-untyped-call, misc]
-def sqlite_reverse_place_diameter(element: SaColumn,
+def sqlite_reverse_place_diameter(element: IntersectsReverseDistance,
compiler: 'sa.Compiled', **kw: Any) -> str:
geom1, rank, geom2 = list(element.clauses)
table = element.tablename
@compiles(IsBelowReverseDistance) # type: ignore[no-untyped-call, misc]
-def default_is_below_reverse_distance(element: SaColumn,
+def default_is_below_reverse_distance(element: IsBelowReverseDistance,
compiler: 'sa.Compiled', **kw: Any) -> str:
dist, rank = list(element.clauses)
return "%s < reverse_place_diameter(%s)" % (compiler.process(dist, **kw),
@compiles(IsBelowReverseDistance, 'sqlite') # type: ignore[no-untyped-call, misc]
-def sqlite_is_below_reverse_distance(element: SaColumn,
+def sqlite_is_below_reverse_distance(element: IsBelowReverseDistance,
compiler: 'sa.Compiled', **kw: Any) -> str:
dist, rank = list(element.clauses)
return "%s < 14.0 * exp(-0.2 * %s) - 0.03" % (compiler.process(dist, **kw),
compiler.process(rank, **kw))
-def select_index_placex_geometry_reverse_lookupplacenode(table: str) -> 'sa.TextClause':
- """ Create an expression with the necessary conditions over a placex
- table that the index 'idx_placex_geometry_reverse_lookupPlaceNode'
- can be used.
- """
- return sa.text(f"{table}.rank_address between 4 and 25"
- f" AND {table}.type != 'postcode'"
- f" AND {table}.name is not null"
- f" AND {table}.linked_place_id is null"
- f" AND {table}.osm_type = 'N'")
-
-
class IsAddressPoint(sa.sql.functions.GenericFunction[Any]):
name = 'IsAddressPoint'
inherit_cache = True
def __init__(self, table: sa.Table) -> None:
- super().__init__(table.c.rank_address, # type: ignore[no-untyped-call]
+ super().__init__(table.c.rank_address,
table.c.housenumber, table.c.name)
@compiles(IsAddressPoint) # type: ignore[no-untyped-call, misc]
-def default_is_address_point(element: SaColumn,
+def default_is_address_point(element: IsAddressPoint,
compiler: 'sa.Compiled', **kw: Any) -> str:
rank, hnr, name = list(element.clauses)
return "(%s = 30 AND (%s IS NOT NULL OR %s ? 'addr:housename'))" % (
@compiles(IsAddressPoint, 'sqlite') # type: ignore[no-untyped-call, misc]
-def sqlite_is_address_point(element: SaColumn,
+def sqlite_is_address_point(element: IsAddressPoint,
compiler: 'sa.Compiled', **kw: Any) -> str:
rank, hnr, name = list(element.clauses)
return "(%s = 30 AND coalesce(%s, json_extract(%s, '$.addr:housename')) IS NOT NULL)" % (
inherit_cache = True
@compiles(CrosscheckNames) # type: ignore[no-untyped-call, misc]
-def compile_crosscheck_names(element: SaColumn,
+def compile_crosscheck_names(element: CrosscheckNames,
compiler: 'sa.Compiled', **kw: Any) -> str:
arg1, arg2 = list(element.clauses)
return "coalesce(avals(%s) && ARRAY(SELECT * FROM json_array_elements_text(%s)), false)" % (
@compiles(CrosscheckNames, 'sqlite') # type: ignore[no-untyped-call, misc]
-def compile_sqlite_crosscheck_names(element: SaColumn,
+def compile_sqlite_crosscheck_names(element: CrosscheckNames,
compiler: 'sa.Compiled', **kw: Any) -> str:
arg1, arg2 = list(element.clauses)
return "EXISTS(SELECT *"\
@compiles(JsonArrayEach) # type: ignore[no-untyped-call, misc]
-def default_json_array_each(element: SaColumn, compiler: 'sa.Compiled', **kw: Any) -> str:
+def default_json_array_each(element: JsonArrayEach, compiler: 'sa.Compiled', **kw: Any) -> str:
return "json_array_elements(%s)" % compiler.process(element.clauses, **kw)
@compiles(JsonArrayEach, 'sqlite') # type: ignore[no-untyped-call, misc]
-def sqlite_json_array_each(element: SaColumn, compiler: 'sa.Compiled', **kw: Any) -> str:
+def sqlite_json_array_each(element: JsonArrayEach, compiler: 'sa.Compiled', **kw: Any) -> str:
return "json_each(%s)" % compiler.process(element.clauses, **kw)
+
class Greatest(sa.sql.functions.GenericFunction[Any]):
""" Function to compute maximum of all its input parameters.
"""
@compiles(Greatest, 'sqlite') # type: ignore[no-untyped-call, misc]
-def sqlite_greatest(element: SaColumn, compiler: 'sa.Compiled', **kw: Any) -> str:
+def sqlite_greatest(element: Greatest, compiler: 'sa.Compiled', **kw: Any) -> str:
return "max(%s)" % compiler.process(element.clauses, **kw)
+
+
+
+class RegexpWord(sa.sql.functions.GenericFunction[Any]):
+ """ Check if a full word is in a given string.
+ """
+ name = 'RegexpWord'
+ inherit_cache = True
+
+
+@compiles(RegexpWord, 'postgresql') # type: ignore[no-untyped-call, misc]
+def postgres_regexp_nocase(element: RegexpWord, compiler: 'sa.Compiled', **kw: Any) -> str:
+ arg1, arg2 = list(element.clauses)
+ return "%s ~* ('\\m(' || %s || ')\\M')::text" % (compiler.process(arg2, **kw), compiler.process(arg1, **kw))
+
+
+@compiles(RegexpWord, 'sqlite') # type: ignore[no-untyped-call, misc]
+def sqlite_regexp_nocase(element: RegexpWord, compiler: 'sa.Compiled', **kw: Any) -> str:
+ arg1, arg2 = list(element.clauses)
+ return "regexp('\\b(' || %s || ')\\b', %s)" % (compiler.process(arg1, **kw), compiler.process(arg2, **kw))