# Licensed under a 3-clause BSD style license - see LICENSE.rst
import abc
import json
import numpy as np
from astropy.io import fits
from .core import Map
from .hpx import HpxConv, HpxGeom
from .utils import find_bands_hdu, find_bintable_hdu
__all__ = ["HpxMap"]
[docs]class HpxMap(Map):
"""Base class for HEALPIX map classes.
Parameters
----------
geom : `~gammapy.maps.HpxGeom`
HEALPix geometry object.
data : `~numpy.ndarray`
Data array.
meta : `dict`
Dictionary to store meta data.
unit : `~astropy.units.Unit`
The map unit
"""
[docs] @classmethod
def create(
cls,
nside=None,
binsz=None,
nest=True,
map_type="hpx",
frame="icrs",
data=None,
skydir=None,
width=None,
dtype="float32",
region=None,
axes=None,
meta=None,
unit="",
):
"""Factory method to create an empty HEALPix map.
Parameters
----------
nside : int or `~numpy.ndarray`
HEALPix NSIDE parameter. This parameter sets the size of
the spatial pixels in the map.
binsz : float or `~numpy.ndarray`
Approximate pixel size in degrees. An NSIDE will be
chosen that correponds to a pixel size closest to this
value. This option is superseded by nside.
nest : bool
True for HEALPix "NESTED" indexing scheme, False for "RING" scheme.
frame : {"icrs", "galactic"}, optional
Coordinate system, either Galactic ("galactic") or Equatorial ("icrs").
skydir : tuple or `~astropy.coordinates.SkyCoord`
Sky position of map center. Can be either a SkyCoord
object or a tuple of longitude and latitude in deg in the
coordinate system of the map.
map_type : {'hpx', 'hpx-sparse'}
Map type. Selects the class that will be used to
instantiate the map.
width : float
Diameter of the map in degrees. If None then an all-sky
geometry will be created.
axes : list
List of `~MapAxis` objects for each non-spatial dimension.
meta : `dict`
Dictionary to store meta data.
unit : str or `~astropy.units.Unit`
The map unit
Returns
-------
map : `~HpxMap`
A HPX map object.
"""
from .hpxnd import HpxNDMap
hpx = HpxGeom.create(
nside=nside,
binsz=binsz,
nest=nest,
frame=frame,
region=region,
axes=axes,
skydir=skydir,
width=width,
)
if cls.__name__ == "HpxNDMap":
return HpxNDMap(hpx, dtype=dtype, meta=meta, unit=unit)
elif map_type == "hpx":
return HpxNDMap(hpx, dtype=dtype, meta=meta, unit=unit)
else:
raise ValueError(f"Unrecognized map type: {map_type!r}")
[docs] @classmethod
def from_hdulist(cls, hdu_list, hdu=None, hdu_bands=None, format=None):
"""Make a HpxMap object from a FITS HDUList.
Parameters
----------
hdu_list : `~astropy.io.fits.HDUList`
HDU list containing HDUs for map data and bands.
hdu : str
Name or index of the HDU with the map data. If None then
the method will try to load map data from the first
BinTableHDU in the file.
hdu_bands : str
Name or index of the HDU with the BANDS table.
format : str, optional
FITS format convention. By default files will be written
to the gamma-astro-data-formats (GADF) format. This
option can be used to write files that are compliant with
format conventions required by specific software (e.g. the
Fermi Science Tools). The following formats are supported:
- "gadf" (default)
- "fgst-ccube"
- "fgst-ltcube"
- "fgst-bexpcube"
- "fgst-srcmap"
- "fgst-template"
- "fgst-srcmap-sparse"
- "galprop"
- "galprop2"
Returns
-------
hpx_map : `HpxMap`
Map object
"""
if hdu is None:
hdu_out = find_bintable_hdu(hdu_list)
else:
hdu_out = hdu_list[hdu]
if hdu_bands is None:
hdu_bands = find_bands_hdu(hdu_list, hdu_out)
hdu_bands_out = None
if hdu_bands is not None:
hdu_bands_out = hdu_list[hdu_bands]
if format is None:
format = HpxConv.identify_hpx_format(hdu_out.header)
hpx_map = cls.from_hdu(hdu_out, hdu_bands_out, format=format)
# exposure maps have an additional GTI hdu
if format == "fgst-bexpcube" and "GTI" in hdu_list:
hpx_map.unit = "cm2 s"
return hpx_map
[docs] def to_hdulist(self, hdu="SKYMAP", hdu_bands=None, sparse=False, format="gadf"):
"""Convert to `~astropy.io.fits.HDUList`.
Parameters
----------
hdu : str
The HDU extension name.
hdu_bands : str
The HDU extension name for BANDS table.
sparse : bool
Set INDXSCHM to SPARSE and sparsify the map by only
writing pixels with non-zero amplitude.
format : str, optional
FITS format convention. By default files will be written
to the gamma-astro-data-formats (GADF) format. This
option can be used to write files that are compliant with
format conventions required by specific software (e.g. the
Fermi Science Tools). The following formats are supported:
- "gadf" (default)
- "fgst-ccube"
- "fgst-ltcube"
- "fgst-bexpcube"
- "fgst-srcmap"
- "fgst-template"
- "fgst-srcmap-sparse"
- "galprop"
- "galprop2"
Returns
-------
hdu_list : `~astropy.io.fits.HDUList`
"""
if self.geom.axes:
hdu_bands_out = self.geom.to_bands_hdu(
hdu=hdu_bands, hdu_skymap=hdu, format=format
)
hdu_bands = hdu_bands_out.name
else:
hdu_bands_out = None
hdu_bands = None
hdu_out = self.to_hdu(
hdu=hdu, hdu_bands=hdu_bands, sparse=sparse, format=format
)
hdu_out.header["META"] = json.dumps(self.meta)
hdu_out.header["BUNIT"] = self.unit.to_string("fits")
hdu_list = fits.HDUList([fits.PrimaryHDU(), hdu_out])
if self.geom.axes:
hdu_list.append(hdu_bands_out)
return hdu_list
[docs] @abc.abstractmethod
def to_wcs(
self,
sum_bands=False,
normalize=True,
proj="AIT",
oversample=2,
width_pix=None,
hpx2wcs=None,
):
"""Make a WCS object and convert HEALPIX data into WCS projection.
Parameters
----------
sum_bands : bool
Sum over non-spatial axes before reprojecting. If False
then the WCS map will have the same dimensionality as the
HEALPix one.
normalize : bool
Preserve integral by splitting HEALPIX values between bins?
proj : str
WCS-projection
oversample : float
Oversampling factor for WCS map. This will be the
approximate ratio of the width of a HPX pixel to a WCS
pixel. If this parameter is None then the width will be
set from ``width_pix``.
width_pix : int
Width of the WCS geometry in pixels. The pixel size will
be set to the number of pixels satisfying ``oversample``
or ``width_pix`` whichever is smaller. If this parameter
is None then the width will be set from ``oversample``.
hpx2wcs : `~HpxToWcsMapping`
Set the HPX to WCS mapping object that will be used to
generate the WCS map. If none then a new mapping will be
generated based on ``proj`` and ``oversample`` arguments.
Returns
-------
map_out : `~gammapy.maps.WcsMap`
WCS map object.
"""
pass
[docs] @abc.abstractmethod
def to_swapped(self):
"""Return a new map with the opposite scheme (ring or nested).
Returns
-------
map : `~HpxMap`
Map object.
"""
pass
[docs] @abc.abstractmethod
def to_ud_graded(self, nside, preserve_counts=False):
"""Upgrade or downgrade the resolution of the map to the chosen nside.
Parameters
----------
nside : int
NSIDE parameter of the new map.
preserve_counts : bool
Choose whether to preserve counts (total amplitude) or
intensity (amplitude per unit solid angle).
Returns
-------
map : `~HpxMap`
Map object.
"""
pass
[docs] def to_hdu(self, hdu=None, hdu_bands=None, sparse=False, format=None):
"""Make a FITS HDU with input data.
Parameters
----------
hdu : str
The HDU extension name.
hdu_bands : str
The HDU extension name for BANDS table.
sparse : bool
Set INDXSCHM to SPARSE and sparsify the map by only
writing pixels with non-zero amplitude.
format : {'fgst-ccube', 'fgst-template', 'gadf', None}, optional
FITS format convention. If None this will be set to the
default convention of the map.
Returns
-------
hdu_out : `~astropy.io.fits.BinTableHDU` or `~astropy.io.fits.ImageHDU`
Output HDU containing map data.
"""
hpxconv = HpxConv.create(format)
hduname = hpxconv.hduname if hdu is None else hdu
hduname_bands = hpxconv.bands_hdu if hdu_bands is None else hdu_bands
header = self.geom.to_header(format=format)
if self.geom.axes:
header["BANDSHDU"] = hduname_bands
if sparse:
header["INDXSCHM"] = "SPARSE"
cols = []
if header["INDXSCHM"] == "EXPLICIT":
array = self.geom._ipix
cols.append(fits.Column("PIX", "J", array=array))
elif header["INDXSCHM"] == "LOCAL":
array = np.arange(self.data.shape[-1])
cols.append(fits.Column("PIX", "J", array=array))
cols += self._make_cols(header, hpxconv)
return fits.BinTableHDU.from_columns(cols, header=header, name=hduname)