""" The OGRGeometry is a wrapper for using the OGR Geometry class (see https://www.gdal.org/classOGRGeometry.html). OGRGeometry may be instantiated when reading geometries from OGR Data Sources (e.g. SHP files), or when given OGC WKT (a string). While the 'full' API is not present yet, the API is "pythonic" unlike the traditional and "next-generation" OGR Python bindings. One major advantage OGR Geometries have over their GEOS counterparts is support for spatial reference systems and their transformation. Example: >>> from django.contrib.gis.gdal import OGRGeometry, OGRGeomType, SpatialReference >>> wkt1, wkt2 = 'POINT(-90 30)', 'POLYGON((0 0, 5 0, 5 5, 0 5)' >>> pnt = OGRGeometry(wkt1) >>> print(pnt) POINT (-90 30) >>> mpnt = OGRGeometry(OGRGeomType('MultiPoint'), SpatialReference('WGS84')) >>> mpnt.add(wkt1) >>> mpnt.add(wkt1) >>> print(mpnt) MULTIPOINT (-90 30,-90 30) >>> print(mpnt.srs.name) WGS 84 >>> print(mpnt.srs.proj) +proj=longlat +ellps=WGS84 +datum=WGS84 +no_defs >>> mpnt.transform(SpatialReference('NAD27')) >>> print(mpnt.proj) +proj=longlat +ellps=clrk66 +datum=NAD27 +no_defs >>> print(mpnt) MULTIPOINT (-89.999930378602485 29.999797886557641,-89.999930378602485 29.999797886557641) The OGRGeomType class is to make it easy to specify an OGR geometry type: >>> from django.contrib.gis.gdal import OGRGeomType >>> gt1 = OGRGeomType(3) # Using an integer for the type >>> gt2 = OGRGeomType('Polygon') # Using a string >>> gt3 = OGRGeomType('POLYGON') # It's case-insensitive >>> print(gt1 == 3, gt1 == 'Polygon') # Equivalence works w/non-OGRGeomType objects True True """ import sys from binascii import b2a_hex from ctypes import byref, c_char_p, c_double, c_ubyte, c_void_p, string_at from django.contrib.gis.gdal.base import GDALBase from django.contrib.gis.gdal.envelope import Envelope, OGREnvelope from django.contrib.gis.gdal.error import GDALException, SRSException from django.contrib.gis.gdal.geomtype import OGRGeomType from django.contrib.gis.gdal.libgdal import GDAL_VERSION from django.contrib.gis.gdal.prototypes import geom as capi, srs as srs_api from django.contrib.gis.gdal.srs import CoordTransform, SpatialReference from django.contrib.gis.geometry import hex_regex, json_regex, wkt_regex from django.utils.encoding import force_bytes # For more information, see the OGR C API source code: # https://www.gdal.org/ogr__api_8h.html # # The OGR_G_* routines are relevant here. class OGRGeometry(GDALBase): """Encapsulate an OGR geometry.""" destructor = capi.destroy_geom def __init__(self, geom_input, srs=None): """Initialize Geometry on either WKT or an OGR pointer as input.""" str_instance = isinstance(geom_input, str) # If HEX, unpack input to a binary buffer. if str_instance and hex_regex.match(geom_input): geom_input = memoryview(bytes.fromhex(geom_input)) str_instance = False # Constructing the geometry, if str_instance: wkt_m = wkt_regex.match(geom_input) json_m = json_regex.match(geom_input) if wkt_m: if wkt_m.group('srid'): # If there's EWKT, set the SRS w/value of the SRID. srs = int(wkt_m.group('srid')) if wkt_m.group('type').upper() == 'LINEARRING': # OGR_G_CreateFromWkt doesn't work with LINEARRING WKT. # See https://trac.osgeo.org/gdal/ticket/1992. g = capi.create_geom(OGRGeomType(wkt_m.group('type')).num) capi.import_wkt(g, byref(c_char_p(wkt_m.group('wkt').encode()))) else: g = capi.from_wkt(byref(c_char_p(wkt_m.group('wkt').encode())), None, byref(c_void_p())) elif json_m: g = self._from_json(geom_input.encode()) else: # Seeing if the input is a valid short-hand string # (e.g., 'Point', 'POLYGON'). OGRGeomType(geom_input) g = capi.create_geom(OGRGeomType(geom_input).num) elif isinstance(geom_input, memoryview): # WKB was passed in g = self._from_wkb(geom_input) elif isinstance(geom_input, OGRGeomType): # OGRGeomType was passed in, an empty geometry will be created. g = capi.create_geom(geom_input.num) elif isinstance(geom_input, self.ptr_type): # OGR pointer (c_void_p) was the input. g = geom_input else: raise GDALException('Invalid input type for OGR Geometry construction: %s' % type(geom_input)) # Now checking the Geometry pointer before finishing initialization # by setting the pointer for the object. if not g: raise GDALException('Cannot create OGR Geometry from input: %s' % geom_input) self.ptr = g # Assigning the SpatialReference object to the geometry, if valid. if srs: self.srs = srs # Setting the class depending upon the OGR Geometry Type self.__class__ = GEO_CLASSES[self.geom_type.num] # Pickle routines def __getstate__(self): srs = self.srs if srs: srs = srs.wkt else: srs = None return bytes(self.wkb), srs def __setstate__(self, state): wkb, srs = state ptr = capi.from_wkb(wkb, None, byref(c_void_p()), len(wkb)) if not ptr: raise GDALException('Invalid OGRGeometry loaded from pickled state.') self.ptr = ptr self.srs = srs @classmethod def _from_wkb(cls, geom_input): return capi.from_wkb(bytes(geom_input), None, byref(c_void_p()), len(geom_input)) @staticmethod def _from_json(geom_input): ptr = capi.from_json(geom_input) if GDAL_VERSION < (2, 0): try: capi.get_geom_srs(ptr) except SRSException: srs = SpatialReference(4326) capi.assign_srs(ptr, srs.ptr) return ptr @classmethod def from_bbox(cls, bbox): "Construct a Polygon from a bounding box (4-tuple)." x0, y0, x1, y1 = bbox return OGRGeometry('POLYGON((%s %s, %s %s, %s %s, %s %s, %s %s))' % ( x0, y0, x0, y1, x1, y1, x1, y0, x0, y0)) @staticmethod def from_json(geom_input): return OGRGeometry(OGRGeometry._from_json(force_bytes(geom_input))) @classmethod def from_gml(cls, gml_string): return cls(capi.from_gml(force_bytes(gml_string))) # ### Geometry set-like operations ### # g = g1 | g2 def __or__(self, other): "Return the union of the two geometries." return self.union(other) # g = g1 & g2 def __and__(self, other): "Return the intersection of this Geometry and the other." return self.intersection(other) # g = g1 - g2 def __sub__(self, other): "Return the difference this Geometry and the other." return self.difference(other) # g = g1 ^ g2 def __xor__(self, other): "Return the symmetric difference of this Geometry and the other." return self.sym_difference(other) def __eq__(self, other): "Is this Geometry equal to the other?" return isinstance(other, OGRGeometry) and self.equals(other) def __str__(self): "WKT is used for the string representation." return self.wkt # #### Geometry Properties #### @property def dimension(self): "Return 0 for points, 1 for lines, and 2 for surfaces." return capi.get_dims(self.ptr) def _get_coord_dim(self): "Return the coordinate dimension of the Geometry." return capi.get_coord_dim(self.ptr) def _set_coord_dim(self, dim): "Set the coordinate dimension of this Geometry." if dim not in (2, 3): raise ValueError('Geometry dimension must be either 2 or 3') capi.set_coord_dim(self.ptr, dim) coord_dim = property(_get_coord_dim, _set_coord_dim) @property def geom_count(self): "Return the number of elements in this Geometry." return capi.get_geom_count(self.ptr) @property def point_count(self): "Return the number of Points in this Geometry." return capi.get_point_count(self.ptr) @property def num_points(self): "Alias for `point_count` (same name method in GEOS API.)" return self.point_count @property def num_coords(self): "Alias for `point_count`." return self.point_count @property def geom_type(self): "Return the Type for this Geometry." return OGRGeomType(capi.get_geom_type(self.ptr)) @property def geom_name(self): "Return the Name of this Geometry." return capi.get_geom_name(self.ptr) @property def area(self): "Return the area for a LinearRing, Polygon, or MultiPolygon; 0 otherwise." return capi.get_area(self.ptr) @property def envelope(self): "Return the envelope for this Geometry." # TODO: Fix Envelope() for Point geometries. return Envelope(capi.get_envelope(self.ptr, byref(OGREnvelope()))) @property def empty(self): return capi.is_empty(self.ptr) @property def extent(self): "Return the envelope as a 4-tuple, instead of as an Envelope object." return self.envelope.tuple # #### SpatialReference-related Properties #### # The SRS property def _get_srs(self): "Return the Spatial Reference for this Geometry." try: srs_ptr = capi.get_geom_srs(self.ptr) return SpatialReference(srs_api.clone_srs(srs_ptr)) except SRSException: return None def _set_srs(self, srs): "Set the SpatialReference for this geometry." # Do not have to clone the `SpatialReference` object pointer because # when it is assigned to this `OGRGeometry` it's internal OGR # reference count is incremented, and will likewise be released # (decremented) when this geometry's destructor is called. if isinstance(srs, SpatialReference): srs_ptr = srs.ptr elif isinstance(srs, (int, str)): sr = SpatialReference(srs) srs_ptr = sr.ptr elif srs is None: srs_ptr = None else: raise TypeError('Cannot assign spatial reference with object of type: %s' % type(srs)) capi.assign_srs(self.ptr, srs_ptr) srs = property(_get_srs, _set_srs) # The SRID property def _get_srid(self): srs = self.srs if srs: return srs.srid return None def _set_srid(self, srid): if isinstance(srid, int) or srid is None: self.srs = srid else: raise TypeError('SRID must be set with an integer.') srid = property(_get_srid, _set_srid) # #### Output Methods #### def _geos_ptr(self): from django.contrib.gis.geos import GEOSGeometry return GEOSGeometry._from_wkb(self.wkb) @property def geos(self): "Return a GEOSGeometry object from this OGRGeometry." from django.contrib.gis.geos import GEOSGeometry return GEOSGeometry(self._geos_ptr(), self.srid) @property def gml(self): "Return the GML representation of the Geometry." return capi.to_gml(self.ptr) @property def hex(self): "Return the hexadecimal representation of the WKB (a string)." return b2a_hex(self.wkb).upper() @property def json(self): """ Return the GeoJSON representation of this Geometry. """ return capi.to_json(self.ptr) geojson = json @property def kml(self): "Return the KML representation of the Geometry." return capi.to_kml(self.ptr, None) @property def wkb_size(self): "Return the size of the WKB buffer." return capi.get_wkbsize(self.ptr) @property def wkb(self): "Return the WKB representation of the Geometry." if sys.byteorder == 'little': byteorder = 1 # wkbNDR (from ogr_core.h) else: byteorder = 0 # wkbXDR sz = self.wkb_size # Creating the unsigned character buffer, and passing it in by reference. buf = (c_ubyte * sz)() capi.to_wkb(self.ptr, byteorder, byref(buf)) # Returning a buffer of the string at the pointer. return memoryview(string_at(buf, sz)) @property def wkt(self): "Return the WKT representation of the Geometry." return capi.to_wkt(self.ptr, byref(c_char_p())) @property def ewkt(self): "Return the EWKT representation of the Geometry." srs = self.srs if srs and srs.srid: return 'SRID=%s;%s' % (srs.srid, self.wkt) else: return self.wkt # #### Geometry Methods #### def clone(self): "Clone this OGR Geometry." return OGRGeometry(capi.clone_geom(self.ptr), self.srs) def close_rings(self): """ If there are any rings within this geometry that have not been closed, this routine will do so by adding the starting point at the end. """ # Closing the open rings. capi.geom_close_rings(self.ptr) def transform(self, coord_trans, clone=False): """ Transform this geometry to a different spatial reference system. May take a CoordTransform object, a SpatialReference object, string WKT or PROJ.4, and/or an integer SRID. By default, return nothing and transform the geometry in-place. However, if the `clone` keyword is set, return a transformed clone of this geometry. """ if clone: klone = self.clone() klone.transform(coord_trans) return klone # Depending on the input type, use the appropriate OGR routine # to perform the transformation. if isinstance(coord_trans, CoordTransform): capi.geom_transform(self.ptr, coord_trans.ptr) elif isinstance(coord_trans, SpatialReference): capi.geom_transform_to(self.ptr, coord_trans.ptr) elif isinstance(coord_trans, (int, str)): sr = SpatialReference(coord_trans) capi.geom_transform_to(self.ptr, sr.ptr) else: raise TypeError('Transform only accepts CoordTransform, ' 'SpatialReference, string, and integer objects.') # #### Topology Methods #### def _topology(self, func, other): """A generalized function for topology operations, takes a GDAL function and the other geometry to perform the operation on.""" if not isinstance(other, OGRGeometry): raise TypeError('Must use another OGRGeometry object for topology operations!') # Returning the output of the given function with the other geometry's # pointer. return func(self.ptr, other.ptr) def intersects(self, other): "Return True if this geometry intersects with the other." return self._topology(capi.ogr_intersects, other) def equals(self, other): "Return True if this geometry is equivalent to the other." return self._topology(capi.ogr_equals, other) def disjoint(self, other): "Return True if this geometry and the other are spatially disjoint." return self._topology(capi.ogr_disjoint, other) def touches(self, other): "Return True if this geometry touches the other." return self._topology(capi.ogr_touches, other) def crosses(self, other): "Return True if this geometry crosses the other." return self._topology(capi.ogr_crosses, other) def within(self, other): "Return True if this geometry is within the other." return self._topology(capi.ogr_within, other) def contains(self, other): "Return True if this geometry contains the other." return self._topology(capi.ogr_contains, other) def overlaps(self, other): "Return True if this geometry overlaps the other." return self._topology(capi.ogr_overlaps, other) # #### Geometry-generation Methods #### def _geomgen(self, gen_func, other=None): "A helper routine for the OGR routines that generate geometries." if isinstance(other, OGRGeometry): return OGRGeometry(gen_func(self.ptr, other.ptr), self.srs) else: return OGRGeometry(gen_func(self.ptr), self.srs) @property def boundary(self): "Return the boundary of this geometry." return self._geomgen(capi.get_boundary) @property def convex_hull(self): """ Return the smallest convex Polygon that contains all the points in this Geometry. """ return self._geomgen(capi.geom_convex_hull) def difference(self, other): """ Return a new geometry consisting of the region which is the difference of this geometry and the other. """ return self._geomgen(capi.geom_diff, other) def intersection(self, other): """ Return a new geometry consisting of the region of intersection of this geometry and the other. """ return self._geomgen(capi.geom_intersection, other) def sym_difference(self, other): """ Return a new geometry which is the symmetric difference of this geometry and the other. """ return self._geomgen(capi.geom_sym_diff, other) def union(self, other): """ Return a new geometry consisting of the region which is the union of this geometry and the other. """ return self._geomgen(capi.geom_union, other) # The subclasses for OGR Geometry. class Point(OGRGeometry): def _geos_ptr(self): from django.contrib.gis import geos return geos.Point._create_empty() if self.empty else super()._geos_ptr() @classmethod def _create_empty(cls): return capi.create_geom(OGRGeomType('point').num) @property def x(self): "Return the X coordinate for this Point." return capi.getx(self.ptr, 0) @property def y(self): "Return the Y coordinate for this Point." return capi.gety(self.ptr, 0) @property def z(self): "Return the Z coordinate for this Point." if self.coord_dim == 3: return capi.getz(self.ptr, 0) @property def tuple(self): "Return the tuple of this point." if self.coord_dim == 2: return (self.x, self.y) elif self.coord_dim == 3: return (self.x, self.y, self.z) coords = tuple class LineString(OGRGeometry): def __getitem__(self, index): "Return the Point at the given index." if 0 <= index < self.point_count: x, y, z = c_double(), c_double(), c_double() capi.get_point(self.ptr, index, byref(x), byref(y), byref(z)) dim = self.coord_dim if dim == 1: return (x.value,) elif dim == 2: return (x.value, y.value) elif dim == 3: return (x.value, y.value, z.value) else: raise IndexError('Index out of range when accessing points of a line string: %s.' % index) def __len__(self): "Return the number of points in the LineString." return self.point_count @property def tuple(self): "Return the tuple representation of this LineString." return tuple(self[i] for i in range(len(self))) coords = tuple def _listarr(self, func): """ Internal routine that returns a sequence (list) corresponding with the given function. """ return [func(self.ptr, i) for i in range(len(self))] @property def x(self): "Return the X coordinates in a list." return self._listarr(capi.getx) @property def y(self): "Return the Y coordinates in a list." return self._listarr(capi.gety) @property def z(self): "Return the Z coordinates in a list." if self.coord_dim == 3: return self._listarr(capi.getz) # LinearRings are used in Polygons. class LinearRing(LineString): pass class Polygon(OGRGeometry): def __len__(self): "Return the number of interior rings in this Polygon." return self.geom_count def __getitem__(self, index): "Get the ring at the specified index." if 0 <= index < self.geom_count: return OGRGeometry(capi.clone_geom(capi.get_geom_ref(self.ptr, index)), self.srs) else: raise IndexError('Index out of range when accessing rings of a polygon: %s.' % index) # Polygon Properties @property def shell(self): "Return the shell of this Polygon." return self[0] # First ring is the shell exterior_ring = shell @property def tuple(self): "Return a tuple of LinearRing coordinate tuples." return tuple(self[i].tuple for i in range(self.geom_count)) coords = tuple @property def point_count(self): "Return the number of Points in this Polygon." # Summing up the number of points in each ring of the Polygon. return sum(self[i].point_count for i in range(self.geom_count)) @property def centroid(self): "Return the centroid (a Point) of this Polygon." # The centroid is a Point, create a geometry for this. p = OGRGeometry(OGRGeomType('Point')) capi.get_centroid(self.ptr, p.ptr) return p # Geometry Collection base class. class GeometryCollection(OGRGeometry): "The Geometry Collection class." def __getitem__(self, index): "Get the Geometry at the specified index." if 0 <= index < self.geom_count: return OGRGeometry(capi.clone_geom(capi.get_geom_ref(self.ptr, index)), self.srs) else: raise IndexError('Index out of range when accessing geometry in a collection: %s.' % index) def __len__(self): "Return the number of geometries in this Geometry Collection." return self.geom_count def add(self, geom): "Add the geometry to this Geometry Collection." if isinstance(geom, OGRGeometry): if isinstance(geom, self.__class__): for g in geom: capi.add_geom(self.ptr, g.ptr) else: capi.add_geom(self.ptr, geom.ptr) elif isinstance(geom, str): tmp = OGRGeometry(geom) capi.add_geom(self.ptr, tmp.ptr) else: raise GDALException('Must add an OGRGeometry.') @property def point_count(self): "Return the number of Points in this Geometry Collection." # Summing up the number of points in each geometry in this collection return sum(self[i].point_count for i in range(self.geom_count)) @property def tuple(self): "Return a tuple representation of this Geometry Collection." return tuple(self[i].tuple for i in range(self.geom_count)) coords = tuple # Multiple Geometry types. class MultiPoint(GeometryCollection): pass class MultiLineString(GeometryCollection): pass class MultiPolygon(GeometryCollection): pass # Class mapping dictionary (using the OGRwkbGeometryType as the key) GEO_CLASSES = {1: Point, 2: LineString, 3: Polygon, 4: MultiPoint, 5: MultiLineString, 6: MultiPolygon, 7: GeometryCollection, 101: LinearRing, 1 + OGRGeomType.wkb25bit: Point, 2 + OGRGeomType.wkb25bit: LineString, 3 + OGRGeomType.wkb25bit: Polygon, 4 + OGRGeomType.wkb25bit: MultiPoint, 5 + OGRGeomType.wkb25bit: MultiLineString, 6 + OGRGeomType.wkb25bit: MultiPolygon, 7 + OGRGeomType.wkb25bit: GeometryCollection, }