def test07a_polygons(self):
        "Testing Polygon objects."

        # Testing `from_bbox` class method
        bbox = (-180, -90, 180, 90)
        p = OGRGeometry.from_bbox(bbox)
        self.assertEqual(bbox, p.extent)

        prev = OGRGeometry('POINT(0 0)')
        for p in self.geometries.polygons:
            poly = OGRGeometry(p.wkt)
            self.assertEqual(3, poly.geom_type)
            self.assertEqual('POLYGON', poly.geom_name)
            self.assertEqual(p.n_p, poly.point_count)
            self.assertEqual(p.n_i + 1, len(poly))

            # Testing area & centroid.
            self.assertAlmostEqual(p.area, poly.area, 9)
            x, y = poly.centroid.tuple
            self.assertAlmostEqual(p.centroid[0], x, 9)
            self.assertAlmostEqual(p.centroid[1], y, 9)

            # Testing equivalence
            self.assertEqual(True, poly == OGRGeometry(p.wkt))
            self.assertEqual(True, poly != prev)

            if p.ext_ring_cs:
                ring = poly[0]
                self.assertEqual(p.ext_ring_cs, ring.tuple)
                self.assertEqual(p.ext_ring_cs, poly[0].tuple)
                self.assertEqual(len(p.ext_ring_cs), ring.point_count)

            for r in poly:
                self.assertEqual('LINEARRING', r.geom_name)
 def test01c_hex(self):
     "Testing HEX input/output."
     for g in self.geometries.hex_wkt:
         geom1 = OGRGeometry(g.wkt)
         self.assertEqual(g.hex, geom1.hex)
         # Constructing w/HEX
         geom2 = OGRGeometry(g.hex)
         self.assertEqual(geom1, geom2)
 def test01e_json(self):
     "Testing GeoJSON input/output."
     if not GEOJSON: return
     for g in self.geometries.json_geoms:
         geom = OGRGeometry(g.wkt)
         if not hasattr(g, 'not_equal'):
             self.assertEqual(g.json, geom.json)
             self.assertEqual(g.json, geom.geojson)
         self.assertEqual(OGRGeometry(g.wkt), OGRGeometry(geom.json))
 def test01d_wkb(self):
     "Testing WKB input/output."
     for g in self.geometries.hex_wkt:
         geom1 = OGRGeometry(g.wkt)
         wkb = geom1.wkb
         self.assertEqual(b2a_hex(wkb).upper(), g.hex)
         # Constructing w/WKB.
         geom2 = OGRGeometry(wkb)
         self.assertEqual(geom1, geom2)
 def test16_25D(self):
     "Testing 2.5D geometries."
     pnt_25d = OGRGeometry('POINT(1 2 3)')
     self.assertEqual('Point25D', pnt_25d.geom_type.name)
     self.assertEqual(3.0, pnt_25d.z)
     self.assertEqual(3, pnt_25d.coord_dim)
     ls_25d = OGRGeometry('LINESTRING(1 1 1,2 2 2,3 3 3)')
     self.assertEqual('LineString25D', ls_25d.geom_type.name)
     self.assertEqual([1.0, 2.0, 3.0], ls_25d.z)
     self.assertEqual(3, ls_25d.coord_dim)
 def test01a_ewkt(self):
     "Testing EWKT input/output."
     for ewkt_val in ('POINT (1 2 3)', 'LINEARRING (0 0,1 1,2 1,0 0)'):
         # First with ewkt output when no SRID in EWKT
         self.assertEqual(ewkt_val, OGRGeometry(ewkt_val).ewkt)
         # No test consumption with an SRID specified.
         ewkt_val = 'SRID=4326;%s' % ewkt_val
         geom = OGRGeometry(ewkt_val)
         self.assertEqual(ewkt_val, geom.ewkt)
         self.assertEqual(4326, geom.srs.srid)
 def test06_linearring(self):
     "Testing LinearRing objects."
     prev = OGRGeometry('POINT(0 0)')
     for rr in self.geometries.linearrings:
         lr = OGRGeometry(rr.wkt)
         #self.assertEqual(101, lr.geom_type.num)
         self.assertEqual('LINEARRING', lr.geom_name)
         self.assertEqual(rr.n_p, len(lr))
         self.assertEqual(True, lr == OGRGeometry(rr.wkt))
         self.assertEqual(True, lr != prev)
         prev = lr
 def test10_difference(self):
     "Testing difference()."
     for i in xrange(len(self.geometries.topology_geoms)):
         a = OGRGeometry(self.geometries.topology_geoms[i].wkt_a)
         b = OGRGeometry(self.geometries.topology_geoms[i].wkt_b)
         d1 = OGRGeometry(self.geometries.diff_geoms[i].wkt)
         d2 = a.difference(b)
         self.assertEqual(d1, d2)
         self.assertEqual(d1, a - b)  # __sub__ is difference operator
         a -= b  # testing __isub__
         self.assertEqual(d1, a)
 def test13_union(self):
     "Testing union()."
     for i in xrange(len(self.geometries.topology_geoms)):
         a = OGRGeometry(self.geometries.topology_geoms[i].wkt_a)
         b = OGRGeometry(self.geometries.topology_geoms[i].wkt_b)
         u1 = OGRGeometry(self.geometries.union_geoms[i].wkt)
         u2 = a.union(b)
         self.assertEqual(u1, u2)
         self.assertEqual(u1, a | b)  # __or__ is union operator
         a |= b  # testing __ior__
         self.assertEqual(u1, a)
    def test02_points(self):
        "Testing Point objects."

        prev = OGRGeometry('POINT(0 0)')
        for p in self.geometries.points:
            if not hasattr(p, 'z'):  # No 3D
                pnt = OGRGeometry(p.wkt)
                self.assertEqual(1, pnt.geom_type)
                self.assertEqual('POINT', pnt.geom_name)
                self.assertEqual(p.x, pnt.x)
                self.assertEqual(p.y, pnt.y)
                self.assertEqual((p.x, p.y), pnt.tuple)
    def test09c_transform_dim(self):
        "Testing coordinate dimension is the same on transformed geometries."
        ls_orig = OGRGeometry('LINESTRING(-104.609 38.255)', 4326)
        ls_trans = OGRGeometry('LINESTRING(992385.4472045 481455.4944650)',
                               2774)

        prec = 3
        ls_orig.transform(ls_trans.srs)
        # Making sure the coordinate dimension is still 2D.
        self.assertEqual(2, ls_orig.coord_dim)
        self.assertAlmostEqual(ls_trans.x[0], ls_orig.x[0], prec)
        self.assertAlmostEqual(ls_trans.y[0], ls_orig.y[0], prec)
 def test12_symdifference(self):
     "Testing sym_difference()."
     for i in xrange(len(self.geometries.topology_geoms)):
         a = OGRGeometry(self.geometries.topology_geoms[i].wkt_a)
         b = OGRGeometry(self.geometries.topology_geoms[i].wkt_b)
         d1 = OGRGeometry(self.geometries.sdiff_geoms[i].wkt)
         d2 = a.sym_difference(b)
         self.assertEqual(d1, d2)
         self.assertEqual(d1,
                          a ^ b)  # __xor__ is symmetric difference operator
         a ^= b  # testing __ixor__
         self.assertEqual(d1, a)
 def test15_extent(self):
     "Testing `extent` property."
     # The xmin, ymin, xmax, ymax of the MultiPoint should be returned.
     mp = OGRGeometry('MULTIPOINT(5 23, 0 0, 10 50)')
     self.assertEqual((0.0, 0.0, 10.0, 50.0), mp.extent)
     # Testing on the 'real world' Polygon.
     poly = OGRGeometry(self.geometries.polygons[3].wkt)
     ring = poly.shell
     x, y = ring.x, ring.y
     xmin, ymin = min(x), min(y)
     xmax, ymax = max(x), max(y)
     self.assertEqual((xmin, ymin, xmax, ymax), poly.extent)
 def test08_multipolygons(self):
     "Testing MultiPolygon objects."
     prev = OGRGeometry('POINT(0 0)')
     for mp in self.geometries.multipolygons:
         mpoly = OGRGeometry(mp.wkt)
         self.assertEqual(6, mpoly.geom_type)
         self.assertEqual('MULTIPOLYGON', mpoly.geom_name)
         if mp.valid:
             self.assertEqual(mp.n_p, mpoly.point_count)
             self.assertEqual(mp.num_geom, len(mpoly))
             self.assertRaises(OGRIndexError, mpoly.__getitem__, len(mpoly))
             for p in mpoly:
                 self.assertEqual('POLYGON', p.geom_name)
                 self.assertEqual(3, p.geom_type)
         self.assertEqual(mpoly.wkt, OGRGeometry(mp.wkt).wkt)
 def test17_pickle(self):
     "Testing pickle support."
     g1 = OGRGeometry('LINESTRING(1 1 1,2 2 2,3 3 3)', 'WGS84')
     g2 = pickle.loads(pickle.dumps(g1))
     self.assertEqual(g1, g2)
     self.assertEqual(4326, g2.srs.srid)
     self.assertEqual(g1.srs.wkt, g2.srs.wkt)
 def test05_multilinestring(self):
     "Testing MultiLineString objects."
     prev = OGRGeometry('POINT(0 0)')
     for mls in self.geometries.multilinestrings:
         mlinestr = OGRGeometry(mls.wkt)
         self.assertEqual(5, mlinestr.geom_type)
         self.assertEqual('MULTILINESTRING', mlinestr.geom_name)
         self.assertEqual(mls.n_p, mlinestr.point_count)
         self.assertEqual(mls.coords, mlinestr.tuple)
         self.assertEqual(True, mlinestr == OGRGeometry(mls.wkt))
         self.assertEqual(True, mlinestr != prev)
         prev = mlinestr
         for ls in mlinestr:
             self.assertEqual(2, ls.geom_type)
             self.assertEqual('LINESTRING', ls.geom_name)
         self.assertRaises(OGRIndexError, mlinestr.__getitem__,
                           len(mlinestr))
 def test03_multipoints(self):
     "Testing MultiPoint objects."
     for mp in self.geometries.multipoints:
         mgeom1 = OGRGeometry(mp.wkt)  # First one from WKT
         self.assertEqual(4, mgeom1.geom_type)
         self.assertEqual('MULTIPOINT', mgeom1.geom_name)
         mgeom2 = OGRGeometry('MULTIPOINT')  # Creating empty multipoint
         mgeom3 = OGRGeometry('MULTIPOINT')
         for g in mgeom1:
             mgeom2.add(g)  # adding each point from the multipoints
             mgeom3.add(g.wkt)  # should take WKT as well
         self.assertEqual(mgeom1, mgeom2)  # they should equal
         self.assertEqual(mgeom1, mgeom3)
         self.assertEqual(mp.coords, mgeom2.coords)
         self.assertEqual(mp.n_p, mgeom2.point_count)
    def test04_linestring(self):
        "Testing LineString objects."
        prev = OGRGeometry('POINT(0 0)')
        for ls in self.geometries.linestrings:
            linestr = OGRGeometry(ls.wkt)
            self.assertEqual(2, linestr.geom_type)
            self.assertEqual('LINESTRING', linestr.geom_name)
            self.assertEqual(ls.n_p, linestr.point_count)
            self.assertEqual(ls.coords, linestr.tuple)
            self.assertEqual(True, linestr == OGRGeometry(ls.wkt))
            self.assertEqual(True, linestr != prev)
            self.assertRaises(OGRIndexError, linestr.__getitem__, len(linestr))
            prev = linestr

            # Testing the x, y properties.
            x = [tmpx for tmpx, tmpy in ls.coords]
            y = [tmpy for tmpx, tmpy in ls.coords]
            self.assertEqual(x, linestr.x)
            self.assertEqual(y, linestr.y)
 def test01b_gml(self):
     "Testing GML output."
     for g in self.geometries.wkt_out:
         geom = OGRGeometry(g.wkt)
         exp_gml = g.gml
         if GDAL_VERSION >= (1, 8):
             # In GDAL 1.8, the non-conformant GML tag  <gml:GeometryCollection> was
             # replaced with <gml:MultiGeometry>.
             exp_gml = exp_gml.replace('GeometryCollection',
                                       'MultiGeometry')
         self.assertEqual(exp_gml, geom.gml)
Exemplo n.º 20
0
    def verify_geom(self, geom, model_field):
        """
        Verifies the geometry -- will construct and return a GeometryCollection
        if necessary (for example if the model field is MultiPolygonField while
        the mapped shapefile only contains Polygons).
        """
        # Downgrade a 3D geom to a 2D one, if necessary.
        if self.coord_dim != geom.coord_dim:
            geom.coord_dim = self.coord_dim

        if self.make_multi(geom.geom_type, model_field):
            # Constructing a multi-geometry type to contain the single geometry
            multi_type = self.MULTI_TYPES[geom.geom_type.num]
            g = OGRGeometry(multi_type)
            g.add(geom)
        else:
            g = geom

        # Transforming the geometry with our Coordinate Transformation object,
        # but only if the class variable `transform` is set w/a CoordTransform
        # object.
        if self.transform: g.transform(self.transform)

        # Returning the WKT of the geometry.
        return g.wkt
    def test07b_closepolygons(self):
        "Testing closing Polygon objects."
        # Both rings in this geometry are not closed.
        poly = OGRGeometry(
            'POLYGON((0 0, 5 0, 5 5, 0 5), (1 1, 2 1, 2 2, 2 1))')
        self.assertEqual(8, poly.point_count)
        print "\nBEGIN - expecting IllegalArgumentException; safe to ignore.\n"
        try:
            c = poly.centroid
        except OGRException:
            # Should raise an OGR exception, rings are not closed
            pass
        else:
            self.fail('Should have raised an OGRException!')
        print "\nEND - expecting IllegalArgumentException; safe to ignore.\n"

        # Closing the rings -- doesn't work on GDAL versions 1.4.1 and below:
        # http://trac.osgeo.org/gdal/ticket/1673
        if GDAL_VERSION <= (1, 4, 1): return
        poly.close_rings()
        self.assertEqual(
            10, poly.point_count)  # Two closing points should've been added
        self.assertEqual(OGRGeometry('POINT(2.5 2.5)'), poly.centroid)
    def test06_spatial_filter(self):
        "Testing the Layer.spatial_filter property."
        ds = DataSource(get_ds_file('cities', 'shp'))
        lyr = ds[0]

        # When not set, it should be None.
        self.assertEqual(None, lyr.spatial_filter)

        # Must be set a/an OGRGeometry or 4-tuple.
        self.assertRaises(TypeError, lyr._set_spatial_filter, 'foo')

        # Setting the spatial filter with a tuple/list with the extent of
        # a buffer centering around Pueblo.
        self.assertRaises(ValueError, lyr._set_spatial_filter, range(5))
        filter_extent = (-105.609252, 37.255001, -103.609252, 39.255001)
        lyr.spatial_filter = (-105.609252, 37.255001, -103.609252, 39.255001)
        self.assertEqual(OGRGeometry.from_bbox(filter_extent),
                         lyr.spatial_filter)
        feats = [feat for feat in lyr]
        self.assertEqual(1, len(feats))
        self.assertEqual('Pueblo', feats[0].get('Name'))

        # Setting the spatial filter with an OGRGeometry for buffer centering
        # around Houston.
        filter_geom = OGRGeometry(
            'POLYGON((-96.363151 28.763374,-94.363151 28.763374,-94.363151 30.763374,-96.363151 30.763374,-96.363151 28.763374))'
        )
        lyr.spatial_filter = filter_geom
        self.assertEqual(filter_geom, lyr.spatial_filter)
        feats = [feat for feat in lyr]
        self.assertEqual(1, len(feats))
        self.assertEqual('Houston', feats[0].get('Name'))

        # Clearing the spatial filter by setting it to None.  Now
        # should indicate that there are 3 features in the Layer.
        lyr.spatial_filter = None
        self.assertEqual(3, len(lyr))
 def test11_intersection(self):
     "Testing intersects() and intersection()."
     for i in xrange(len(self.geometries.topology_geoms)):
         a = OGRGeometry(self.geometries.topology_geoms[i].wkt_a)
         b = OGRGeometry(self.geometries.topology_geoms[i].wkt_b)
         i1 = OGRGeometry(self.geometries.intersect_geoms[i].wkt)
         self.assertEqual(True, a.intersects(b))
         i2 = a.intersection(b)
         self.assertEqual(i1, i2)
         self.assertEqual(i1, a & b)  # __and__ is intersection operator
         a &= b  # testing __iand__
         self.assertEqual(i1, a)
    def test18_ogrgeometry_transform_workaround(self):
        "Testing coordinate dimensions on geometries after transformation."
        # A bug in GDAL versions prior to 1.7 changes the coordinate
        # dimension of a geometry after it has been transformed.
        # This test ensures that the bug workarounds employed within
        # `OGRGeometry.transform` indeed work.
        wkt_2d = "MULTILINESTRING ((0 0,1 1,2 2))"
        wkt_3d = "MULTILINESTRING ((0 0 0,1 1 1,2 2 2))"
        srid = 4326

        # For both the 2D and 3D MultiLineString, ensure _both_ the dimension
        # of the collection and the component LineString have the expected
        # coordinate dimension after transform.
        geom = OGRGeometry(wkt_2d, srid)
        geom.transform(srid)
        self.assertEqual(2, geom.coord_dim)
        self.assertEqual(2, geom[0].coord_dim)
        self.assertEqual(wkt_2d, geom.wkt)

        geom = OGRGeometry(wkt_3d, srid)
        geom.transform(srid)
        self.assertEqual(3, geom.coord_dim)
        self.assertEqual(3, geom[0].coord_dim)
        self.assertEqual(wkt_3d, geom.wkt)
    def test09b_srs_transform(self):
        "Testing transform()."
        orig = OGRGeometry('POINT (-104.609 38.255)', 4326)
        trans = OGRGeometry('POINT (992385.4472045 481455.4944650)', 2774)

        # Using an srid, a SpatialReference object, and a CoordTransform object
        # or transformations.
        t1, t2, t3 = orig.clone(), orig.clone(), orig.clone()
        t1.transform(trans.srid)
        t2.transform(SpatialReference('EPSG:2774'))
        ct = CoordTransform(SpatialReference('WGS84'), SpatialReference(2774))
        t3.transform(ct)

        # Testing use of the `clone` keyword.
        k1 = orig.clone()
        k2 = k1.transform(trans.srid, clone=True)
        self.assertEqual(k1, orig)
        self.assertNotEqual(k1, k2)

        prec = 3
        for p in (t1, t2, t3, k2):
            self.assertAlmostEqual(trans.x, p.x, prec)
            self.assertAlmostEqual(trans.y, p.y, prec)
    def test14_add(self):
        "Testing GeometryCollection.add()."
        # Can't insert a Point into a MultiPolygon.
        mp = OGRGeometry('MultiPolygon')
        pnt = OGRGeometry('POINT(5 23)')
        self.assertRaises(OGRException, mp.add, pnt)

        # GeometryCollection.add may take an OGRGeometry (if another collection
        # of the same type all child geoms will be added individually) or WKT.
        for mp in self.geometries.multipolygons:
            mpoly = OGRGeometry(mp.wkt)
            mp1 = OGRGeometry('MultiPolygon')
            mp2 = OGRGeometry('MultiPolygon')
            mp3 = OGRGeometry('MultiPolygon')

            for poly in mpoly:
                mp1.add(poly)  # Adding a geometry at a time
                mp2.add(poly.wkt)  # Adding WKT
            mp3.add(mpoly)  # Adding a MultiPolygon's entire contents at once.
            for tmp in (mp1, mp2, mp3):
                self.assertEqual(mpoly, tmp)
    def test09a_srs(self):
        "Testing OGR Geometries with Spatial Reference objects."
        for mp in self.geometries.multipolygons:
            # Creating a geometry w/spatial reference
            sr = SpatialReference('WGS84')
            mpoly = OGRGeometry(mp.wkt, sr)
            self.assertEqual(sr.wkt, mpoly.srs.wkt)

            # Ensuring that SRS is propagated to clones.
            klone = mpoly.clone()
            self.assertEqual(sr.wkt, klone.srs.wkt)

            # Ensuring all children geometries (polygons and their rings) all
            # return the assigned spatial reference as well.
            for poly in mpoly:
                self.assertEqual(sr.wkt, poly.srs.wkt)
                for ring in poly:
                    self.assertEqual(sr.wkt, ring.srs.wkt)

            # Ensuring SRS propagate in topological ops.
            a = OGRGeometry(self.geometries.topology_geoms[0].wkt_a, sr)
            b = OGRGeometry(self.geometries.topology_geoms[0].wkt_b, sr)
            diff = a.difference(b)
            union = a.union(b)
            self.assertEqual(sr.wkt, diff.srs.wkt)
            self.assertEqual(sr.srid, union.srs.srid)

            # Instantiating w/an integer SRID
            mpoly = OGRGeometry(mp.wkt, 4326)
            self.assertEqual(4326, mpoly.srid)
            mpoly.srs = SpatialReference(4269)
            self.assertEqual(4269, mpoly.srid)
            self.assertEqual('NAD83', mpoly.srs.name)

            # Incrementing through the multipolyogn after the spatial reference
            # has been re-assigned.
            for poly in mpoly:
                self.assertEqual(mpoly.srs.wkt, poly.srs.wkt)
                poly.srs = 32140
                for ring in poly:
                    # Changing each ring in the polygon
                    self.assertEqual(32140, ring.srs.srid)
                    self.assertEqual('NAD83 / Texas South Central',
                                     ring.srs.name)
                    ring.srs = str(SpatialReference(4326))  # back to WGS84
                    self.assertEqual(4326, ring.srs.srid)

                    # Using the `srid` property.
                    ring.srid = 4322
                    self.assertEqual('WGS 72', ring.srs.name)
                    self.assertEqual(4322, ring.srid)
Exemplo n.º 28
0
        def _save(feat_range=default_range, num_feat=0, num_saved=0):
            if feat_range:
                layer_iter = self.layer[feat_range]
            else:
                layer_iter = self.layer

            for feat in layer_iter:
                num_feat += 1
                # Getting the keyword arguments
                try:
                    kwargs = self.feature_kwargs(feat)
                except LayerMapError, msg:
                    # Something borked the validation
                    if strict: raise
                    elif not silent:
                        stream.write('Ignoring Feature ID %s because: %s\n' % (feat.fid, msg))
                else:
                    # Constructing the model using the keyword args
                    is_update = False
                    if self.unique:
                        # If we want unique models on a particular field, handle the
                        # geometry appropriately.
                        try:
                            # Getting the keyword arguments and retrieving
                            # the unique model.
                            u_kwargs = self.unique_kwargs(kwargs)
                            m = self.model.objects.using(self.using).get(**u_kwargs)
                            is_update = True

                            # Getting the geometry (in OGR form), creating
                            # one from the kwargs WKT, adding in additional
                            # geometries, and update the attribute with the
                            # just-updated geometry WKT.
                            geom = getattr(m, self.geom_field).ogr
                            new = OGRGeometry(kwargs[self.geom_field])
                            for g in new: geom.add(g)
                            setattr(m, self.geom_field, geom.wkt)
                        except ObjectDoesNotExist:
                            # No unique model exists yet, create.
                            m = self.model(**kwargs)
                    else:
                        m = self.model(**kwargs)

                    try:
                        # Attempting to save.
                        m.save(using=self.using)
                        num_saved += 1
                        if verbose: stream.write('%s: %s\n' % (is_update and 'Updated' or 'Saved', m))
                    except SystemExit:
                        raise
                    except Exception, msg:
                        if self.transaction_mode == 'autocommit':
                            # Rolling back the transaction so that other model saves
                            # will work.
                            transaction.rollback_unless_managed()
                        if strict:
                            # Bailing out if the `strict` keyword is set.
                            if not silent:
                                stream.write('Failed to save the feature (id: %s) into the model with the keyword arguments:\n' % feat.fid)
                                stream.write('%s\n' % kwargs)
                            raise
                        elif not silent:
                            stream.write('Failed to save %s:\n %s\nContinuing\n' % (kwargs, msg))
 def test01a_wkt(self):
     "Testing WKT output."
     for g in self.geometries.wkt_out:
         geom = OGRGeometry(g.wkt)
         self.assertEqual(g.wkt, geom.wkt)
 def test19_equivalence_regression(self):
     "Testing equivalence methods with non-OGRGeometry instances."
     self.assertNotEqual(None, OGRGeometry('POINT(0 0)'))
     self.assertEqual(False, OGRGeometry('LINESTRING(0 0, 1 1)') == 3)