import enum
import math
from struct import unpack
-
-from geoalchemy2 import WKTElement
-import geoalchemy2.functions
+from binascii import unhexlify
from nominatim.errors import UsageError
@staticmethod
- def from_wkb(wkb: bytes) -> 'Point':
+ def from_wkb(wkb: Union[str, bytes]) -> 'Point':
""" Create a point from EWKB as returned from the database.
"""
+ if isinstance(wkb, str):
+ wkb = unhexlify(wkb)
if len(wkb) != 25:
- raise ValueError("Point wkb has unexpected length")
+ raise ValueError(f"Point wkb has unexpected length {len(wkb)}")
if wkb[0] == 0:
gtype, srid, x, y = unpack('>iidd', wkb[1:])
elif wkb[0] == 1:
return Point(x, y)
- def sql_value(self) -> WKTElement:
- """ Create an SQL expression for the point.
+ def to_wkt(self) -> str:
+ """ Return the WKT representation of the point.
"""
- return WKTElement(f'POINT({self.x} {self.y})', srid=4326)
+ return f'POINT({self.x} {self.y})'
return (self.coords[2] - self.coords[0]) * (self.coords[3] - self.coords[1])
- def sql_value(self) -> Any:
- """ Create an SQL expression for the box.
- """
- return geoalchemy2.functions.ST_MakeEnvelope(*self.coords, 4326)
-
-
def contains(self, pt: Point) -> bool:
""" Check if the point is inside or on the boundary of the box.
"""
and self.coords[2] >= pt[0] and self.coords[3] >= pt[1]
+ def to_wkt(self) -> str:
+ """ Return the WKT representation of the Bbox. This
+ is a simple polygon with four points.
+ """
+ return 'POLYGON(({0} {1},{0} {3},{2} {3},{2} {1},{0} {1}))'\
+ .format(*self.coords) # pylint: disable=consider-using-f-string
+
+
@staticmethod
- def from_wkb(wkb: Optional[bytes]) -> 'Optional[Bbox]':
+ def from_wkb(wkb: Union[None, str, bytes]) -> 'Optional[Bbox]':
""" Create a Bbox from a bounding box polygon as returned by
the database. Return s None if the input value is None.
"""
if wkb is None:
return None
+ if isinstance(wkb, str):
+ wkb = unhexlify(wkb)
+
if len(wkb) != 97:
raise ValueError("WKB must be a bounding box polygon")
if wkb.startswith(WKB_BBOX_HEADER_LE):
except ValueError as exc:
raise UsageError('Bounding box parameter needs to be numbers.') from exc
- if x1 < -180.0 or x1 > 180.0 or y1 < -90.0 or y1 > 90.0 \
- or x2 < -180.0 or x2 > 180.0 or y2 < -90.0 or y2 > 90.0:
- raise UsageError('Bounding box coordinates invalid.')
+ x1 = min(180, max(-180, x1))
+ x2 = min(180, max(-180, x2))
+ y1 = min(90, max(-90, y1))
+ y2 = min(90, max(-90, y2))
if x1 == x2 or y1 == y2:
raise UsageError('Bounding box with invalid parameters.')
else:
raise UsageError("Parameter 'excluded' needs to be a comma-separated list "
"or a Python list of numbers.")
- if not all(isinstance(i, int) or (isinstance(i, str) and i.isdigit()) for i in plist):
+ if not all(isinstance(i, int) or
+ (isinstance(i, str) and (not i or i.isdigit())) for i in plist):
raise UsageError("Parameter 'excluded' only takes place IDs.")
- return [int(id) for id in plist if id]
+ return [int(id) for id in plist if id] or [0]
def format_categories(categories: List[Tuple[str, str]]) -> List[Tuple[str, str]]:
)
""" Highest address rank to return.
"""
- layers: Optional[DataLayer] = None
+ layers: Optional[DataLayer] = dataclasses.field(default=None,
+ metadata={'transform': lambda r : r})
""" Filter which kind of data to include. When 'None' (the default) then
filtering by layers is disabled.
"""
metadata={'transform': Point.from_param})
""" Order results by distance to the given point.
"""
- near_radius: Optional[float] = None
+ near_radius: Optional[float] = dataclasses.field(default=None,
+ metadata={'transform': lambda r : r})
""" Use near point as a filter and drop results outside the given
radius. Radius is given in degrees WSG84.
"""
""" Restrict search to places with one of the given class/type categories.
An empty list (the default) will disable this filter.
"""
+ viewbox_x2: Optional[Bbox] = None
def __post_init__(self) -> None:
if self.viewbox is not None: