""" The Spatial Reference class, represensents OGR Spatial Reference objects. Example: >>> from django.contrib.gis.gdal import SpatialReference >>> srs = SpatialReference('WGS84') >>> print(srs) GEOGCS["WGS 84", DATUM["WGS_1984", SPHEROID["WGS 84",6378137,298.257223563, AUTHORITY["EPSG","7030"]], TOWGS84[0,0,0,0,0,0,0], AUTHORITY["EPSG","6326"]], PRIMEM["Greenwich",0, AUTHORITY["EPSG","8901"]], UNIT["degree",0.01745329251994328, AUTHORITY["EPSG","9122"]], AUTHORITY["EPSG","4326"]] >>> print(srs.proj) +proj=longlat +ellps=WGS84 +datum=WGS84 +no_defs >>> print(srs.ellipsoid) (6378137.0, 6356752.3142451793, 298.25722356300003) >>> print(srs.projected, srs.geographic) False True >>> srs.import_epsg(32140) >>> print(srs.name) NAD83 / Texas South Central """ from ctypes import byref, c_char_p, c_int # Getting the error checking routine and exceptions from django.contrib.gis.gdal.base import GDALBase from django.contrib.gis.gdal.error import SRSException from django.contrib.gis.gdal.prototypes import srs as capi #### Spatial Reference class. #### class SpatialReference(GDALBase): """ A wrapper for the OGRSpatialReference object. According to the GDAL Web site, the SpatialReference object "provide[s] services to represent coordinate systems (projections and datums) and to transform between them." """ #### Python 'magic' routines #### def __init__(self, srs_input=''): """ Creates a GDAL OSR Spatial Reference object from the given input. The input may be string of OGC Well Known Text (WKT), an integer EPSG code, a PROJ.4 string, and/or a projection "well known" shorthand string (one of 'WGS84', 'WGS72', 'NAD27', 'NAD83'). """ buf = c_char_p('') srs_type = 'user' if isinstance(srs_input, basestring): # Encoding to ASCII if unicode passed in. if isinstance(srs_input, unicode): srs_input = srs_input.encode('ascii') try: # If SRID is a string, e.g., '4326', then make acceptable # as user input. srid = int(srs_input) srs_input = 'EPSG:%d' % srid except ValueError: pass elif isinstance(srs_input, (int, long)): # EPSG integer code was input. srs_type = 'epsg' elif isinstance(srs_input, self.ptr_type): srs = srs_input srs_type = 'ogr' else: raise TypeError('Invalid SRS type "%s"' % srs_type) if srs_type == 'ogr': # Input is already an SRS pointer. srs = srs_input else: # Creating a new SRS pointer, using the string buffer. srs = capi.new_srs(buf) # If the pointer is NULL, throw an exception. if not srs: raise SRSException('Could not create spatial reference from: %s' % srs_input) else: self.ptr = srs # Importing from either the user input string or an integer SRID. if srs_type == 'user': self.import_user_input(srs_input) elif srs_type == 'epsg': self.import_epsg(srs_input) def __del__(self): "Destroys this spatial reference." if self._ptr: capi.release_srs(self._ptr) def __getitem__(self, target): """ Returns the value of the given string attribute node, None if the node doesn't exist. Can also take a tuple as a parameter, (target, child), where child is the index of the attribute in the WKT. For example: >>> wkt = 'GEOGCS["WGS 84", DATUM["WGS_1984, ... AUTHORITY["EPSG","4326"]]') >>> srs = SpatialReference(wkt) # could also use 'WGS84', or 4326 >>> print(srs['GEOGCS']) WGS 84 >>> print(srs['DATUM']) WGS_1984 >>> print(srs['AUTHORITY']) EPSG >>> print(srs['AUTHORITY', 1]) # The authority value 4326 >>> print(srs['TOWGS84', 4]) # the fourth value in this wkt 0 >>> print(srs['UNIT|AUTHORITY']) # For the units authority, have to use the pipe symbole. EPSG >>> print(srs['UNIT|AUTHORITY', 1]) # The authority value for the untis 9122 """ if isinstance(target, tuple): return self.attr_value(*target) else: return self.attr_value(target) def __str__(self): "The string representation uses 'pretty' WKT." return self.pretty_wkt #### SpatialReference Methods #### def attr_value(self, target, index=0): """ The attribute value for the given target node (e.g. 'PROJCS'). The index keyword specifies an index of the child node to return. """ if not isinstance(target, basestring) or not isinstance(index, int): raise TypeError return capi.get_attr_value(self.ptr, target, index) def auth_name(self, target): "Returns the authority name for the given string target node." return capi.get_auth_name(self.ptr, target) def auth_code(self, target): "Returns the authority code for the given string target node." return capi.get_auth_code(self.ptr, target) def clone(self): "Returns a clone of this SpatialReference object." return SpatialReference(capi.clone_srs(self.ptr)) def from_esri(self): "Morphs this SpatialReference from ESRI's format to EPSG." capi.morph_from_esri(self.ptr) def identify_epsg(self): """ This method inspects the WKT of this SpatialReference, and will add EPSG authority nodes where an EPSG identifier is applicable. """ capi.identify_epsg(self.ptr) def to_esri(self): "Morphs this SpatialReference to ESRI's format." capi.morph_to_esri(self.ptr) def validate(self): "Checks to see if the given spatial reference is valid." capi.srs_validate(self.ptr) #### Name & SRID properties #### @property def name(self): "Returns the name of this Spatial Reference." if self.projected: return self.attr_value('PROJCS') elif self.geographic: return self.attr_value('GEOGCS') elif self.local: return self.attr_value('LOCAL_CS') else: return None @property def srid(self): "Returns the SRID of top-level authority, or None if undefined." try: return int(self.attr_value('AUTHORITY', 1)) except (TypeError, ValueError): return None #### Unit Properties #### @property def linear_name(self): "Returns the name of the linear units." units, name = capi.linear_units(self.ptr, byref(c_char_p())) return name @property def linear_units(self): "Returns the value of the linear units." units, name = capi.linear_units(self.ptr, byref(c_char_p())) return units @property def angular_name(self): "Returns the name of the angular units." units, name = capi.angular_units(self.ptr, byref(c_char_p())) return name @property def angular_units(self): "Returns the value of the angular units." units, name = capi.angular_units(self.ptr, byref(c_char_p())) return units @property def units(self): """ Returns a 2-tuple of the units value and the units name, and will automatically determines whether to return the linear or angular units. """ if self.projected or self.local: return capi.linear_units(self.ptr, byref(c_char_p())) elif self.geographic: return capi.angular_units(self.ptr, byref(c_char_p())) else: return (None, None) #### Spheroid/Ellipsoid Properties #### @property def ellipsoid(self): """ Returns a tuple of the ellipsoid parameters: (semimajor axis, semiminor axis, and inverse flattening) """ return (self.semi_major, self.semi_minor, self.inverse_flattening) @property def semi_major(self): "Returns the Semi Major Axis for this Spatial Reference." return capi.semi_major(self.ptr, byref(c_int())) @property def semi_minor(self): "Returns the Semi Minor Axis for this Spatial Reference." return capi.semi_minor(self.ptr, byref(c_int())) @property def inverse_flattening(self): "Returns the Inverse Flattening for this Spatial Reference." return capi.invflattening(self.ptr, byref(c_int())) #### Boolean Properties #### @property def geographic(self): """ Returns True if this SpatialReference is geographic (root node is GEOGCS). """ return bool(capi.isgeographic(self.ptr)) @property def local(self): "Returns True if this SpatialReference is local (root node is LOCAL_CS)." return bool(capi.islocal(self.ptr)) @property def projected(self): """ Returns True if this SpatialReference is a projected coordinate system (root node is PROJCS). """ return bool(capi.isprojected(self.ptr)) #### Import Routines ##### def import_epsg(self, epsg): "Imports the Spatial Reference from the EPSG code (an integer)." capi.from_epsg(self.ptr, epsg) def import_proj(self, proj): "Imports the Spatial Reference from a PROJ.4 string." capi.from_proj(self.ptr, proj) def import_user_input(self, user_input): "Imports the Spatial Reference from the given user input string." capi.from_user_input(self.ptr, user_input) def import_wkt(self, wkt): "Imports the Spatial Reference from OGC WKT (string)" capi.from_wkt(self.ptr, byref(c_char_p(wkt))) def import_xml(self, xml): "Imports the Spatial Reference from an XML string." capi.from_xml(self.ptr, xml) #### Export Properties #### @property def wkt(self): "Returns the WKT representation of this Spatial Reference." return capi.to_wkt(self.ptr, byref(c_char_p())) @property def pretty_wkt(self, simplify=0): "Returns the 'pretty' representation of the WKT." return capi.to_pretty_wkt(self.ptr, byref(c_char_p()), simplify) @property def proj(self): "Returns the PROJ.4 representation for this Spatial Reference." return capi.to_proj(self.ptr, byref(c_char_p())) @property def proj4(self): "Alias for proj()." return self.proj @property def xml(self, dialect=''): "Returns the XML representation of this Spatial Reference." return capi.to_xml(self.ptr, byref(c_char_p()), dialect) class CoordTransform(GDALBase): "The coordinate system transformation object." def __init__(self, source, target): "Initializes on a source and target SpatialReference objects." if not isinstance(source, SpatialReference) or not isinstance(target, SpatialReference): raise TypeError('source and target must be of type SpatialReference') self.ptr = capi.new_ct(source._ptr, target._ptr) self._srs1_name = source.name self._srs2_name = target.name def __del__(self): "Deletes this Coordinate Transformation object." if self._ptr: capi.destroy_ct(self._ptr) def __str__(self): return 'Transform from "%s" to "%s"' % (self._srs1_name, self._srs2_name)