import copy
import numpy as np
from astropy import units as u
from astropy.coordinates import SkyCoord
__all__ = ["MapCoord"]
def skycoord_to_lonlat(skycoord, frame=None):
"""Convert SkyCoord to lon, lat, frame.
Returns
-------
lon : `~numpy.ndarray`
Longitude in degrees.
lat : `~numpy.ndarray`
Latitude in degrees.
"""
if frame:
skycoord = skycoord.transform_to(frame)
return skycoord.data.lon.deg, skycoord.data.lat.deg, skycoord.frame.name
[docs]class MapCoord:
"""Represents a sequence of n-dimensional map coordinates.
Contains coordinates for 2 spatial dimensions and an arbitrary
number of additional non-spatial dimensions.
For further information see :ref:`mapcoord`.
Parameters
----------
data : `dict` of `~numpy.ndarray`
Dictionary of coordinate arrays.
frame : {"icrs", "galactic", None}
Spatial coordinate system. If None then the coordinate system
will be set to the native coordinate system of the geometry.
match_by_name : bool
Match coordinates to axes by name?
If false coordinates will be matched by index.
"""
def __init__(self, data, frame=None, match_by_name=True):
if "lon" not in data or "lat" not in data:
raise ValueError("data dictionary must contain axes named 'lon' and 'lat'.")
self._data = {k: np.atleast_1d(v) for k, v in data.items()}
self._frame = frame
self._match_by_name = match_by_name
def __getitem__(self, key):
if isinstance(key, str):
return self._data[key]
else:
return list(self._data.values())[key]
def __setitem__(self, key, value):
# TODO: check for broadcastability?
self._data[key] = value
def __iter__(self):
return iter(self._data.values())
@property
def ndim(self):
"""Number of dimensions."""
return len(self._data)
@property
def shape(self):
"""Coordinate array shape."""
arrays = [_ for _ in self._data.values()]
return np.broadcast(*arrays).shape
@property
def size(self):
return np.prod(self.shape)
@property
def lon(self):
"""Longitude coordinate in degrees."""
return self._data["lon"]
@property
def lat(self):
"""Latitude coordinate in degrees."""
return self._data["lat"]
@property
def theta(self):
"""Theta co-latitude angle in radians."""
theta = u.Quantity(self.lat, unit="deg", copy=False).to_value("rad")
return np.pi / 2.0 - theta
@property
def phi(self):
"""Phi longitude angle in radians."""
phi = u.Quantity(self.lon, unit="deg", copy=False).to_value("rad")
return phi
@property
def frame(self):
"""Coordinate system (str)."""
return self._frame
@property
def match_by_name(self):
"""Boolean flag: axis lookup by name (True) or index (False)."""
return self._match_by_name
@property
def skycoord(self):
return SkyCoord(self.lon, self.lat, unit="deg", frame=self.frame)
@classmethod
def _from_lonlat(cls, coords, frame=None, axis_names=None):
"""Create a `~MapCoord` from a tuple of coordinate vectors.
The first two elements of the tuple should be longitude and latitude in degrees.
Parameters
----------
coords : tuple
Tuple of `~numpy.ndarray`.
Returns
-------
coord : `~MapCoord`
A coordinates object.
"""
if axis_names is None:
axis_names = [f"axis{idx}" for idx in range(len(coords) - 2)]
if isinstance(coords, (list, tuple)):
coords_dict = {"lon": coords[0], "lat": coords[1]}
for name, c in zip(axis_names, coords[2:]):
coords_dict[name] = c
else:
raise ValueError("Unrecognized input type.")
return cls(coords_dict, frame=frame, match_by_name=False)
@classmethod
def _from_tuple(cls, coords, frame=None, axis_names=None):
"""Create from tuple of coordinate vectors."""
if isinstance(coords[0], (list, np.ndarray)) or np.isscalar(coords[0]):
return cls._from_lonlat(coords, frame=frame, axis_names=axis_names)
elif isinstance(coords[0], SkyCoord):
lon, lat, frame = skycoord_to_lonlat(coords[0], frame=frame)
coords = (lon, lat) + coords[1:]
return cls._from_lonlat(coords, frame=frame, axis_names=axis_names)
else:
raise TypeError(f"Type not supported: {type(coords)!r}")
@classmethod
def _from_dict(cls, coords, frame=None):
"""Create from a dictionary of coordinate vectors."""
if "lon" in coords and "lat" in coords:
return cls(coords, frame=frame)
elif "skycoord" in coords:
lon, lat, frame = skycoord_to_lonlat(coords["skycoord"], frame=frame)
coords_dict = {"lon": lon, "lat": lat}
for k, v in coords.items():
if k == "skycoord":
continue
coords_dict[k] = v
return cls(coords_dict, frame=frame)
else:
raise ValueError("coords dict must contain 'lon'/'lat' or 'skycoord'.")
[docs] @classmethod
def create(cls, data, frame=None, axis_names=None):
"""Create a new `~MapCoord` object.
This method can be used to create either unnamed (with tuple input)
or named (via dict input) axes.
Parameters
----------
data : tuple, dict, `~gammapy.maps.MapCoord` or `~astropy.coordinates.SkyCoord`
Object containing coordinate arrays.
frame : {"icrs", "galactic", None}, optional
Set the coordinate system for longitude and latitude. If
None longitude and latitude will be assumed to be in
the coordinate system native to a given map geometry.
axis_names : list of str
Axis names use if a tuple is provided
Examples
--------
>>> from astropy.coordinates import SkyCoord
>>> from gammapy.maps import MapCoord
>>> lon, lat = [1, 2], [2, 3]
>>> skycoord = SkyCoord(lon, lat, unit='deg')
>>> energy = [1000]
>>> c = MapCoord.create((lon,lat))
>>> c = MapCoord.create((skycoord,))
>>> c = MapCoord.create((lon,lat,energy))
>>> c = MapCoord.create(dict(lon=lon,lat=lat))
>>> c = MapCoord.create(dict(lon=lon,lat=lat,energy=energy))
>>> c = MapCoord.create(dict(skycoord=skycoord,energy=energy))
"""
if isinstance(data, cls):
if data.frame is None or frame == data.frame:
return data
else:
return data.to_frame(frame)
elif isinstance(data, dict):
return cls._from_dict(data, frame=frame)
elif isinstance(data, (list, tuple)):
return cls._from_tuple(data, frame=frame, axis_names=axis_names)
elif isinstance(data, SkyCoord):
return cls._from_tuple((data,), frame=frame, axis_names=axis_names)
else:
raise TypeError(f"Unsupported input type: {type(data)!r}")
[docs] def to_frame(self, frame):
"""Convert to a different coordinate frame.
Parameters
----------
frame : {"icrs", "galactic"}
Coordinate system, either Galactic ("galactic") or Equatorial ("icrs").
Returns
-------
coords : `~MapCoord`
A coordinates object.
"""
if frame == self.frame:
return copy.deepcopy(self)
else:
lon, lat, frame = skycoord_to_lonlat(self.skycoord, frame=frame)
data = copy.deepcopy(self._data)
if isinstance(self.lon, u.Quantity):
lon = u.Quantity(lon, unit="deg", copy=False)
if isinstance(self.lon, u.Quantity):
lat = u.Quantity(lat, unit="deg", copy=False)
data["lon"] = lon
data["lat"] = lat
return self.__class__(data, frame, self._match_by_name)
[docs] def apply_mask(self, mask):
"""Return a masked copy of this coordinate object.
Parameters
----------
mask : `~numpy.ndarray`
Boolean mask.
Returns
-------
coords : `~MapCoord`
A coordinates object.
"""
try:
data = {k: v[mask] for k, v in self._data.items()}
except IndexError:
data = {}
for name, coord in self._data.items():
if name in ["lon", "lat"]:
data[name] = np.squeeze(coord)[mask]
else:
data[name] = np.squeeze(coord, axis=-1)
return self.__class__(data, self.frame, self._match_by_name)
@property
def flat(self):
"""Return flattened, valid coordinates"""
coords = self.broadcasted
is_finite = np.isfinite(coords[0])
return coords.apply_mask(is_finite)
@property
def broadcasted(self):
"""Return broadcasted coords"""
vals = np.broadcast_arrays(*self._data.values(), subok=True)
data = dict(zip(self._data.keys(), vals))
return self.__class__(
data=data, frame=self.frame, match_by_name=self._match_by_name
)
[docs] def copy(self):
"""Copy `MapCoord` object."""
return copy.deepcopy(self)
def __repr__(self):
return (
f"{self.__class__.__name__}\n\n"
f"\taxes : {list(self._data.keys())}\n"
f"\tshape : {self.shape[::-1]}\n"
f"\tndim : {self.ndim}\n"
f"\tframe : {self.frame}\n"
)