webapp/django/contrib/gis/db/backend/postgis/query.py - gerrit - Git at Google

 """
  This module contains the spatial lookup types, and the get_geo_where_clause()
  routine for PostGIS.
 """
 import re
 from decimal import Decimal
 from django.db import connection
 from django.contrib.gis.measure import Distance
 from django.contrib.gis.db.backend.postgis.management import postgis_version_tuple
 from django.contrib.gis.db.backend.util import SpatialOperation, SpatialFunction
 qn = connection.ops.quote_name

 # Getting the PostGIS version information
 POSTGIS_VERSION, MAJOR_VERSION, MINOR_VERSION1, MINOR_VERSION2 = postgis_version_tuple()

 # The supported PostGIS versions.
 #  TODO: Confirm tests with PostGIS versions 1.1.x -- should work.
 #        Versions <= 1.0.x do not use GEOS C API, and will not be supported.
 if MAJOR_VERSION != 1 or (MAJOR_VERSION == 1 and MINOR_VERSION1 < 1):
     raise Exception('PostGIS version %s not supported.' % POSTGIS_VERSION)

 # Versions of PostGIS >= 1.2.2 changed their naming convention to be
 #  'SQL-MM-centric' to conform with the ISO standard. Practically, this
 #  means that 'ST_' prefixes geometry function names.
 GEOM_FUNC_PREFIX = ''
 if MAJOR_VERSION >= 1:
     if (MINOR_VERSION1 > 2 or
         (MINOR_VERSION1 == 2 and MINOR_VERSION2 >= 2)):
         GEOM_FUNC_PREFIX = 'ST_'

     def get_func(func): return '%s%s' % (GEOM_FUNC_PREFIX, func)

     # Custom selection not needed for PostGIS because GEOS geometries are
     # instantiated directly from the HEXEWKB returned by default.  If
     # WKT is needed for some reason in the future, this value may be changed,
     # e.g,, 'AsText(%s)'.
     GEOM_SELECT = None

     # Functions used by the GeoManager & GeoQuerySet
     AREA = get_func('Area')
     ASKML = get_func('AsKML')
     ASGML = get_func('AsGML')
     ASSVG = get_func('AsSVG')
     CENTROID = get_func('Centroid')
     DIFFERENCE = get_func('Difference')
     DISTANCE = get_func('Distance')
     DISTANCE_SPHERE = get_func('distance_sphere')
     DISTANCE_SPHEROID = get_func('distance_spheroid')
     ENVELOPE = get_func('Envelope')
     EXTENT = get_func('extent')
     GEOM_FROM_TEXT = get_func('GeomFromText')
     GEOM_FROM_WKB = get_func('GeomFromWKB')
     INTERSECTION = get_func('Intersection')
     LENGTH = get_func('Length')
     LENGTH_SPHEROID = get_func('length_spheroid')
     MAKE_LINE = get_func('MakeLine')
     MEM_SIZE = get_func('mem_size')
     NUM_GEOM = get_func('NumGeometries')
     NUM_POINTS = get_func('npoints')
     PERIMETER = get_func('Perimeter')
     POINT_ON_SURFACE = get_func('PointOnSurface')
     SCALE = get_func('Scale')
     SYM_DIFFERENCE = get_func('SymDifference')
     TRANSFORM = get_func('Transform')
     TRANSLATE = get_func('Translate')

     # Special cases for union and KML methods.
     if MINOR_VERSION1 < 3:
         UNIONAGG = 'GeomUnion'
         UNION = 'Union'
     else:
         UNIONAGG = 'ST_Union'
         UNION = 'ST_Union'

     if MINOR_VERSION1 == 1:
         ASKML = False
 else:
     raise NotImplementedError('PostGIS versions < 1.0 are not supported.')

 #### Classes used in constructing PostGIS spatial SQL ####
 class PostGISOperator(SpatialOperation):
     "For PostGIS operators (e.g. `&&`, `~`)."
     def __init__(self, operator):
         super(PostGISOperator, self).__init__(operator=operator, beg_subst='%s %s %%s')

 class PostGISFunction(SpatialFunction):
     "For PostGIS function calls (e.g., `ST_Contains(table, geom)`)."
     def __init__(self, function, **kwargs):
         super(PostGISFunction, self).__init__(get_func(function), **kwargs)

 class PostGISFunctionParam(PostGISFunction):
     "For PostGIS functions that take another parameter (e.g. DWithin, Relate)."
     def __init__(self, func):
         super(PostGISFunctionParam, self).__init__(func, end_subst=', %%s)')

 class PostGISDistance(PostGISFunction):
     "For PostGIS distance operations."
     dist_func = 'Distance'
     def __init__(self, operator):
         super(PostGISDistance, self).__init__(self.dist_func, end_subst=') %s %s',
                                               operator=operator, result='%%s')

 class PostGISSpheroidDistance(PostGISFunction):
     "For PostGIS spherical distance operations (using the spheroid)."
     dist_func = 'distance_spheroid'
     def __init__(self, operator):
         # An extra parameter in `end_subst` is needed for the spheroid string.
         super(PostGISSpheroidDistance, self).__init__(self.dist_func,
                                                       beg_subst='%s(%s, %%s, %%s',
                                                       end_subst=') %s %s',
                                                       operator=operator, result='%%s')

 class PostGISSphereDistance(PostGISFunction):
     "For PostGIS spherical distance operations."
     dist_func = 'distance_sphere'
     def __init__(self, operator):
         super(PostGISSphereDistance, self).__init__(self.dist_func, end_subst=') %s %s',
                                                     operator=operator, result='%%s')

 class PostGISRelate(PostGISFunctionParam):
     "For PostGIS Relate(<geom>, <pattern>) calls."
     pattern_regex = re.compile(r'^[012TF\*]{9}$')
     def __init__(self, pattern):
         if not self.pattern_regex.match(pattern):
             raise ValueError('Invalid intersection matrix pattern "%s".' % pattern)
         super(PostGISRelate, self).__init__('Relate')

 #### Lookup type mapping dictionaries of PostGIS operations. ####

 # PostGIS-specific operators. The commented descriptions of these
 # operators come from Section 6.2.2 of the official PostGIS documentation.
 POSTGIS_OPERATORS = {
     # The "&<" operator returns true if A's bounding box overlaps or
     #  is to the left of B's bounding box.
     'overlaps_left' : PostGISOperator('&<'),
     # The "&>" operator returns true if A's bounding box overlaps or
     #  is to the right of B's bounding box.
     'overlaps_right' : PostGISOperator('&>'),
     # The "<<" operator returns true if A's bounding box is strictly
     #  to the left of B's bounding box.
     'left' : PostGISOperator('<<'),
     # The ">>" operator returns true if A's bounding box is strictly
     #  to the right of B's bounding box.
     'right' : PostGISOperator('>>'),
     # The "&<|" operator returns true if A's bounding box overlaps or
     #  is below B's bounding box.
     'overlaps_below' : PostGISOperator('&<|'),
     # The "|&>" operator returns true if A's bounding box overlaps or
     #  is above B's bounding box.
     'overlaps_above' : PostGISOperator('|&>'),
     # The "<<|" operator returns true if A's bounding box is strictly
     #  below B's bounding box.
     'strictly_below' : PostGISOperator('<<|'),
     # The "|>>" operator returns true if A's bounding box is strictly
     # above B's bounding box.
     'strictly_above' : PostGISOperator('|>>'),
     # The "~=" operator is the "same as" operator. It tests actual
     #  geometric equality of two features. So if A and B are the same feature,
     #  vertex-by-vertex, the operator returns true.
     'same_as' : PostGISOperator('~='),
     'exact' : PostGISOperator('~='),
     # The "@" operator returns true if A's bounding box is completely contained
     #  by B's bounding box.
     'contained' : PostGISOperator('@'),
     # The "~" operator returns true if A's bounding box completely contains
     #  by B's bounding box.
     'bbcontains' : PostGISOperator('~'),
     # The "&&" operator returns true if A's bounding box overlaps
     #  B's bounding box.
     'bboverlaps' : PostGISOperator('&&'),
     }

 # For PostGIS >= 1.2.2 the following lookup types will do a bounding box query
 # first before calling the more computationally expensive GEOS routines (called
 # "inline index magic"):
 # 'touches', 'crosses', 'contains', 'intersects', 'within', 'overlaps', and
 # 'covers'.
 POSTGIS_GEOMETRY_FUNCTIONS = {
     'equals' : PostGISFunction('Equals'),
     'disjoint' : PostGISFunction('Disjoint'),
     'touches' : PostGISFunction('Touches'),
     'crosses' : PostGISFunction('Crosses'),
     'within' : PostGISFunction('Within'),
     'overlaps' : PostGISFunction('Overlaps'),
     'contains' : PostGISFunction('Contains'),
     'intersects' : PostGISFunction('Intersects'),
     'relate' : (PostGISRelate, basestring),
     }

 # Valid distance types and substitutions
 dtypes = (Decimal, Distance, float, int, long)
 def get_dist_ops(operator):
     "Returns operations for both regular and spherical distances."
     return (PostGISDistance(operator), PostGISSphereDistance(operator), PostGISSpheroidDistance(operator))
 DISTANCE_FUNCTIONS = {
     'distance_gt' : (get_dist_ops('>'), dtypes),
     'distance_gte' : (get_dist_ops('>='), dtypes),
     'distance_lt' : (get_dist_ops('<'), dtypes),
     'distance_lte' : (get_dist_ops('<='), dtypes),
     }

 if GEOM_FUNC_PREFIX == 'ST_':
     # The ST_DWithin, ST_CoveredBy, and ST_Covers routines become available in 1.2.2+
     POSTGIS_GEOMETRY_FUNCTIONS.update(
         {'coveredby' : PostGISFunction('CoveredBy'),
          'covers' : PostGISFunction('Covers'),
          })
     DISTANCE_FUNCTIONS['dwithin'] = (PostGISFunctionParam('DWithin'), dtypes)

 # Distance functions are a part of PostGIS geometry functions.
 POSTGIS_GEOMETRY_FUNCTIONS.update(DISTANCE_FUNCTIONS)

 # Any other lookup types that do not require a mapping.
 MISC_TERMS = ['isnull']

 # These are the PostGIS-customized QUERY_TERMS -- a list of the lookup types
 #  allowed for geographic queries.
 POSTGIS_TERMS = POSTGIS_OPERATORS.keys() # Getting the operators first
 POSTGIS_TERMS += POSTGIS_GEOMETRY_FUNCTIONS.keys() # Adding on the Geometry Functions
 POSTGIS_TERMS += MISC_TERMS # Adding any other miscellaneous terms (e.g., 'isnull')
 POSTGIS_TERMS = dict((term, None) for term in POSTGIS_TERMS) # Making a dictionary for fast lookups

 # For checking tuple parameters -- not very pretty but gets job done.
 def exactly_two(val): return val == 2
 def two_to_three(val): return val >= 2 and val <=3
 def num_params(lookup_type, val):
     if lookup_type in DISTANCE_FUNCTIONS and lookup_type != 'dwithin': return two_to_three(val)
     else: return exactly_two(val)

 #### The `get_geo_where_clause` function for PostGIS. ####
 def get_geo_where_clause(table_alias, name, lookup_type, geo_annot):
     "Returns the SQL WHERE clause for use in PostGIS SQL construction."
     # Getting the quoted field as `geo_col`.
     geo_col = '%s.%s' % (qn(table_alias), qn(name))
     if lookup_type in POSTGIS_OPERATORS:
         # See if a PostGIS operator matches the lookup type.
         return POSTGIS_OPERATORS[lookup_type].as_sql(geo_col)
     elif lookup_type in POSTGIS_GEOMETRY_FUNCTIONS:
         # See if a PostGIS geometry function matches the lookup type.
         tmp = POSTGIS_GEOMETRY_FUNCTIONS[lookup_type]

         # Lookup types that are tuples take tuple arguments, e.g., 'relate' and
         # distance lookups.
         if isinstance(tmp, tuple):
             # First element of tuple is the PostGISOperation instance, and the
             # second element is either the type or a tuple of acceptable types
             # that may passed in as further parameters for the lookup type.
             op, arg_type = tmp

             # Ensuring that a tuple _value_ was passed in from the user
             if not isinstance(geo_annot.value, (tuple, list)):
                 raise TypeError('Tuple required for `%s` lookup type.' % lookup_type)

             # Number of valid tuple parameters depends on the lookup type.
             nparams = len(geo_annot.value)
             if not num_params(lookup_type, nparams):
                 raise ValueError('Incorrect number of parameters given for `%s` lookup type.' % lookup_type)

             # Ensuring the argument type matches what we expect.
             if not isinstance(geo_annot.value[1], arg_type):
                 raise TypeError('Argument type should be %s, got %s instead.' % (arg_type, type(geo_annot.value[1])))

             # For lookup type `relate`, the op instance is not yet created (has
             # to be instantiated here to check the pattern parameter).
             if lookup_type == 'relate':
                 op = op(geo_annot.value[1])
             elif lookup_type in DISTANCE_FUNCTIONS and lookup_type != 'dwithin':
                 if geo_annot.geodetic:
                     # Geodetic distances are only availble from Points to PointFields.
                     if geo_annot.geom_type != 'POINT':
                         raise TypeError('PostGIS spherical operations are only valid on PointFields.')
                     if geo_annot.value[0].geom_typeid != 0:
                         raise TypeError('PostGIS geometry distance parameter is required to be of type Point.')
                     # Setting up the geodetic operation appropriately.
                     if nparams == 3 and geo_annot.value[2] == 'spheroid': op = op[2]
                     else: op = op[1]
                 else:
                     op = op[0]
         else:
             op = tmp
         # Calling the `as_sql` function on the operation instance.
         return op.as_sql(geo_col)
     elif lookup_type == 'isnull':
         # Handling 'isnull' lookup type
         return "%s IS %sNULL" % (geo_col, (not geo_annot.value and 'NOT ' or ''))

     raise TypeError("Got invalid lookup_type: %s" % repr(lookup_type))
	"""
	This module contains the spatial lookup types, and the get_geo_where_clause()
	routine for PostGIS.
	"""
	import re
	from decimal import Decimal
	from django.db import connection
	from django.contrib.gis.measure import Distance
	from django.contrib.gis.db.backend.postgis.management import postgis_version_tuple
	from django.contrib.gis.db.backend.util import SpatialOperation, SpatialFunction
	qn = connection.ops.quote_name

	# Getting the PostGIS version information
	POSTGIS_VERSION, MAJOR_VERSION, MINOR_VERSION1, MINOR_VERSION2 = postgis_version_tuple()

	# The supported PostGIS versions.
	# TODO: Confirm tests with PostGIS versions 1.1.x -- should work.
	# Versions <= 1.0.x do not use GEOS C API, and will not be supported.
	if MAJOR_VERSION != 1 or (MAJOR_VERSION == 1 and MINOR_VERSION1 < 1):
	raise Exception('PostGIS version %s not supported.' % POSTGIS_VERSION)

	# Versions of PostGIS >= 1.2.2 changed their naming convention to be
	# 'SQL-MM-centric' to conform with the ISO standard. Practically, this
	# means that 'ST_' prefixes geometry function names.
	GEOM_FUNC_PREFIX = ''
	if MAJOR_VERSION >= 1:
	if (MINOR_VERSION1 > 2 or
	(MINOR_VERSION1 == 2 and MINOR_VERSION2 >= 2)):
	GEOM_FUNC_PREFIX = 'ST_'

	def get_func(func): return '%s%s' % (GEOM_FUNC_PREFIX, func)

	# Custom selection not needed for PostGIS because GEOS geometries are
	# instantiated directly from the HEXEWKB returned by default. If
	# WKT is needed for some reason in the future, this value may be changed,
	# e.g,, 'AsText(%s)'.
	GEOM_SELECT = None

	# Functions used by the GeoManager & GeoQuerySet
	AREA = get_func('Area')
	ASKML = get_func('AsKML')
	ASGML = get_func('AsGML')
	ASSVG = get_func('AsSVG')
	CENTROID = get_func('Centroid')
	DIFFERENCE = get_func('Difference')
	DISTANCE = get_func('Distance')
	DISTANCE_SPHERE = get_func('distance_sphere')
	DISTANCE_SPHEROID = get_func('distance_spheroid')
	ENVELOPE = get_func('Envelope')
	EXTENT = get_func('extent')
	GEOM_FROM_TEXT = get_func('GeomFromText')
	GEOM_FROM_WKB = get_func('GeomFromWKB')
	INTERSECTION = get_func('Intersection')
	LENGTH = get_func('Length')
	LENGTH_SPHEROID = get_func('length_spheroid')
	MAKE_LINE = get_func('MakeLine')
	MEM_SIZE = get_func('mem_size')
	NUM_GEOM = get_func('NumGeometries')
	NUM_POINTS = get_func('npoints')
	PERIMETER = get_func('Perimeter')
	POINT_ON_SURFACE = get_func('PointOnSurface')
	SCALE = get_func('Scale')
	SYM_DIFFERENCE = get_func('SymDifference')
	TRANSFORM = get_func('Transform')
	TRANSLATE = get_func('Translate')

	# Special cases for union and KML methods.
	if MINOR_VERSION1 < 3:
	UNIONAGG = 'GeomUnion'
	UNION = 'Union'
	else:
	UNIONAGG = 'ST_Union'
	UNION = 'ST_Union'

	if MINOR_VERSION1 == 1:
	ASKML = False
	else:
	raise NotImplementedError('PostGIS versions < 1.0 are not supported.')

	#### Classes used in constructing PostGIS spatial SQL ####
	class PostGISOperator(SpatialOperation):
	"For PostGIS operators (e.g. `&&`, `~`)."
	def __init__(self, operator):
	super(PostGISOperator, self).__init__(operator=operator, beg_subst='%s %s %%s')

	class PostGISFunction(SpatialFunction):
	"For PostGIS function calls (e.g., `ST_Contains(table, geom)`)."
	def __init__(self, function, **kwargs):
	super(PostGISFunction, self).__init__(get_func(function), **kwargs)

	class PostGISFunctionParam(PostGISFunction):
	"For PostGIS functions that take another parameter (e.g. DWithin, Relate)."
	def __init__(self, func):
	super(PostGISFunctionParam, self).__init__(func, end_subst=', %%s)')

	class PostGISDistance(PostGISFunction):
	"For PostGIS distance operations."
	dist_func = 'Distance'
	def __init__(self, operator):
	super(PostGISDistance, self).__init__(self.dist_func, end_subst=') %s %s',
	operator=operator, result='%%s')

	class PostGISSpheroidDistance(PostGISFunction):
	"For PostGIS spherical distance operations (using the spheroid)."
	dist_func = 'distance_spheroid'
	def __init__(self, operator):
	# An extra parameter in `end_subst` is needed for the spheroid string.
	super(PostGISSpheroidDistance, self).__init__(self.dist_func,
	beg_subst='%s(%s, %%s, %%s',
	end_subst=') %s %s',
	operator=operator, result='%%s')

	class PostGISSphereDistance(PostGISFunction):
	"For PostGIS spherical distance operations."
	dist_func = 'distance_sphere'
	def __init__(self, operator):
	super(PostGISSphereDistance, self).__init__(self.dist_func, end_subst=') %s %s',
	operator=operator, result='%%s')

	class PostGISRelate(PostGISFunctionParam):
	"For PostGIS Relate(<geom>, <pattern>) calls."
	pattern_regex = re.compile(r'^[012TF\*]{9}$')
	def __init__(self, pattern):
	if not self.pattern_regex.match(pattern):
	raise ValueError('Invalid intersection matrix pattern "%s".' % pattern)
	super(PostGISRelate, self).__init__('Relate')

	#### Lookup type mapping dictionaries of PostGIS operations. ####

	# PostGIS-specific operators. The commented descriptions of these
	# operators come from Section 6.2.2 of the official PostGIS documentation.
	POSTGIS_OPERATORS = {
	# The "&<" operator returns true if A's bounding box overlaps or
	# is to the left of B's bounding box.
	'overlaps_left' : PostGISOperator('&<'),
	# The "&>" operator returns true if A's bounding box overlaps or
	# is to the right of B's bounding box.
	'overlaps_right' : PostGISOperator('&>'),
	# The "<<" operator returns true if A's bounding box is strictly
	# to the left of B's bounding box.
	'left' : PostGISOperator('<<'),
	# The ">>" operator returns true if A's bounding box is strictly
	# to the right of B's bounding box.
	'right' : PostGISOperator('>>'),
	# The "&<\|" operator returns true if A's bounding box overlaps or
	# is below B's bounding box.
	'overlaps_below' : PostGISOperator('&<\|'),
	# The "\|&>" operator returns true if A's bounding box overlaps or
	# is above B's bounding box.
	'overlaps_above' : PostGISOperator('\|&>'),
	# The "<<\|" operator returns true if A's bounding box is strictly
	# below B's bounding box.
	'strictly_below' : PostGISOperator('<<\|'),
	# The "\|>>" operator returns true if A's bounding box is strictly
	# above B's bounding box.
	'strictly_above' : PostGISOperator('\|>>'),
	# The "~=" operator is the "same as" operator. It tests actual
	# geometric equality of two features. So if A and B are the same feature,
	# vertex-by-vertex, the operator returns true.
	'same_as' : PostGISOperator('~='),
	'exact' : PostGISOperator('~='),
	# The "@" operator returns true if A's bounding box is completely contained
	# by B's bounding box.
	'contained' : PostGISOperator('@'),
	# The "~" operator returns true if A's bounding box completely contains
	# by B's bounding box.
	'bbcontains' : PostGISOperator('~'),
	# The "&&" operator returns true if A's bounding box overlaps
	# B's bounding box.
	'bboverlaps' : PostGISOperator('&&'),
	}

	# For PostGIS >= 1.2.2 the following lookup types will do a bounding box query
	# first before calling the more computationally expensive GEOS routines (called
	# "inline index magic"):
	# 'touches', 'crosses', 'contains', 'intersects', 'within', 'overlaps', and
	# 'covers'.
	POSTGIS_GEOMETRY_FUNCTIONS = {
	'equals' : PostGISFunction('Equals'),
	'disjoint' : PostGISFunction('Disjoint'),
	'touches' : PostGISFunction('Touches'),
	'crosses' : PostGISFunction('Crosses'),
	'within' : PostGISFunction('Within'),
	'overlaps' : PostGISFunction('Overlaps'),
	'contains' : PostGISFunction('Contains'),
	'intersects' : PostGISFunction('Intersects'),
	'relate' : (PostGISRelate, basestring),
	}

	# Valid distance types and substitutions
	dtypes = (Decimal, Distance, float, int, long)
	def get_dist_ops(operator):
	"Returns operations for both regular and spherical distances."
	return (PostGISDistance(operator), PostGISSphereDistance(operator), PostGISSpheroidDistance(operator))
	DISTANCE_FUNCTIONS = {
	'distance_gt' : (get_dist_ops('>'), dtypes),
	'distance_gte' : (get_dist_ops('>='), dtypes),
	'distance_lt' : (get_dist_ops('<'), dtypes),
	'distance_lte' : (get_dist_ops('<='), dtypes),
	}

	if GEOM_FUNC_PREFIX == 'ST_':
	# The ST_DWithin, ST_CoveredBy, and ST_Covers routines become available in 1.2.2+
	POSTGIS_GEOMETRY_FUNCTIONS.update(
	{'coveredby' : PostGISFunction('CoveredBy'),
	'covers' : PostGISFunction('Covers'),
	})
	DISTANCE_FUNCTIONS['dwithin'] = (PostGISFunctionParam('DWithin'), dtypes)

	# Distance functions are a part of PostGIS geometry functions.
	POSTGIS_GEOMETRY_FUNCTIONS.update(DISTANCE_FUNCTIONS)

	# Any other lookup types that do not require a mapping.
	MISC_TERMS = ['isnull']

	# These are the PostGIS-customized QUERY_TERMS -- a list of the lookup types
	# allowed for geographic queries.
	POSTGIS_TERMS = POSTGIS_OPERATORS.keys() # Getting the operators first
	POSTGIS_TERMS += POSTGIS_GEOMETRY_FUNCTIONS.keys() # Adding on the Geometry Functions
	POSTGIS_TERMS += MISC_TERMS # Adding any other miscellaneous terms (e.g., 'isnull')
	POSTGIS_TERMS = dict((term, None) for term in POSTGIS_TERMS) # Making a dictionary for fast lookups

	# For checking tuple parameters -- not very pretty but gets job done.
	def exactly_two(val): return val == 2
	def two_to_three(val): return val >= 2 and val <=3
	def num_params(lookup_type, val):
	if lookup_type in DISTANCE_FUNCTIONS and lookup_type != 'dwithin': return two_to_three(val)
	else: return exactly_two(val)

	#### The `get_geo_where_clause` function for PostGIS. ####
	def get_geo_where_clause(table_alias, name, lookup_type, geo_annot):
	"Returns the SQL WHERE clause for use in PostGIS SQL construction."
	# Getting the quoted field as `geo_col`.
	geo_col = '%s.%s' % (qn(table_alias), qn(name))
	if lookup_type in POSTGIS_OPERATORS:
	# See if a PostGIS operator matches the lookup type.
	return POSTGIS_OPERATORS[lookup_type].as_sql(geo_col)
	elif lookup_type in POSTGIS_GEOMETRY_FUNCTIONS:
	# See if a PostGIS geometry function matches the lookup type.
	tmp = POSTGIS_GEOMETRY_FUNCTIONS[lookup_type]

	# Lookup types that are tuples take tuple arguments, e.g., 'relate' and
	# distance lookups.
	if isinstance(tmp, tuple):
	# First element of tuple is the PostGISOperation instance, and the
	# second element is either the type or a tuple of acceptable types
	# that may passed in as further parameters for the lookup type.
	op, arg_type = tmp

	# Ensuring that a tuple _value_ was passed in from the user
	if not isinstance(geo_annot.value, (tuple, list)):
	raise TypeError('Tuple required for `%s` lookup type.' % lookup_type)

	# Number of valid tuple parameters depends on the lookup type.
	nparams = len(geo_annot.value)
	if not num_params(lookup_type, nparams):
	raise ValueError('Incorrect number of parameters given for `%s` lookup type.' % lookup_type)

	# Ensuring the argument type matches what we expect.
	if not isinstance(geo_annot.value[1], arg_type):
	raise TypeError('Argument type should be %s, got %s instead.' % (arg_type, type(geo_annot.value[1])))

	# For lookup type `relate`, the op instance is not yet created (has
	# to be instantiated here to check the pattern parameter).
	if lookup_type == 'relate':
	op = op(geo_annot.value[1])
	elif lookup_type in DISTANCE_FUNCTIONS and lookup_type != 'dwithin':
	if geo_annot.geodetic:
	# Geodetic distances are only availble from Points to PointFields.
	if geo_annot.geom_type != 'POINT':
	raise TypeError('PostGIS spherical operations are only valid on PointFields.')
	if geo_annot.value[0].geom_typeid != 0:
	raise TypeError('PostGIS geometry distance parameter is required to be of type Point.')
	# Setting up the geodetic operation appropriately.
	if nparams == 3 and geo_annot.value[2] == 'spheroid': op = op[2]
	else: op = op[1]
	else:
	op = op[0]
	else:
	op = tmp
	# Calling the `as_sql` function on the operation instance.
	return op.as_sql(geo_col)
	elif lookup_type == 'isnull':
	# Handling 'isnull' lookup type
	return "%s IS %sNULL" % (geo_col, (not geo_annot.value and 'NOT ' or ''))

	raise TypeError("Got invalid lookup_type: %s" % repr(lookup_type))