Skip to content

Commit

Permalink
Removed spheroidal gridding routines.
Browse files Browse the repository at this point in the history
  • Loading branch information
iancze committed Dec 23, 2023
1 parent 6c12f59 commit 2004997
Show file tree
Hide file tree
Showing 5 changed files with 2 additions and 1,017 deletions.
1 change: 0 additions & 1 deletion .coveragerc
Original file line number Diff line number Diff line change
@@ -1,7 +1,6 @@
[run]
omit =
venv/*
src/mpol/spheroidal_gridding.py
relative_files = True


Expand Down
1 change: 1 addition & 0 deletions docs/changelog.md
Original file line number Diff line number Diff line change
Expand Up @@ -4,6 +4,7 @@

## v0.2.1

- Removed custom `spheroidal_gridding` routines, tests, and the `UVDataset` object that used them. These have been superseded by the TorchKbNuFFT package. For reference, the old routines (including the tricky `corrfun` math) is preserved in a Gist [here](https://gist.github.com/iancze/f3d2769005a9e2c6731ee6977f166a83).
- Changed API of {class}`~mpol.fourier.NuFFT`. Previous signature took `uu` and `vv` points at initialization (`__init__`), and the `.forward` method took only an image cube. This behaviour is preserved in a new class {class}`~mpol.fourier.NuFFTCached`. The updated signature of {class}`~mpol.fourier.NuFFT` *does not* take `uu` and `vv` at initialization. Rather, its `forward` method is modified to take an image cube and the `uu` and `vv` points. This allows an instance of this class to be used with new `uu` and `vv` points in each forward call. This follows the standard expectation of a layer (e.g., a linear regression function predicting at new `x`) and the pattern of the TorchKbNuFFT package itself. It is expected that the new `NuFFT` will be the default routine and `NuFFTCached` will only be used in specialized circumstances (and possibly deprecated/removed in future updates). Changes implemented by [#232](https://github.com/MPoL-dev/MPoL/pull/232).
- Moved "Releasing a new version of MPoL" from the wiki to the Developer Documentation ({ref}`releasing-new-version-label`).

Expand Down
102 changes: 1 addition & 101 deletions src/mpol/datasets.py
Original file line number Diff line number Diff line change
Expand Up @@ -12,7 +12,7 @@
from mpol.coordinates import GridCoords
from mpol.exceptions import WrongDimensionError

from . import spheroidal_gridding, utils
from . import utils
from .constants import *
from .utils import loglinspace

Expand Down Expand Up @@ -160,106 +160,6 @@ def ground_mask(self) -> torch.Tensor:
"""
return utils.packed_cube_to_ground_cube(self.mask)


# custom dataset loader
class UVDataset(torch_ud.Dataset):
r"""
Container for loose interferometric visibilities.
Args:
uu (2d numpy array): (nchan, nvis) length array of u spatial frequency coordinates. Units of [:math:`\mathrm{k}\lambda`]
vv (2d numpy array): (nchan, nvis) length array of v spatial frequency coordinates. Units of [:math:`\mathrm{k}\lambda`]
data_re (2d numpy array): (nchan, nvis) length array of the real part of the visibility measurements. Units of [:math:`\mathrm{Jy}`]
data_im (2d numpy array): (nchan, nvis) length array of the imaginary part of the visibility measurements. Units of [:math:`\mathrm{Jy}`]
weights (2d numpy array): (nchan, nvis) length array of thermal weights. Units of [:math:`1/\mathrm{Jy}^2`]
cell_size (float): the image pixel size in arcsec. Defaults to None, but if both `cell_size` and `npix` are set, the visibilities will be pre-gridded to the RFFT output dimensions.
npix (int): the number of pixels per image side (square images only). Defaults to None, but if both `cell_size` and `npix` are set, the visibilities will be pre-gridded to the RFFT output dimensions.
device (torch.device) : the desired device of the dataset. If ``None``, defalts to current device.
If both `cell_size` and `npix` are set, the dataset will be automatically pre-gridded to the RFFT output grid. This will greatly speed up performance.
If you have just a single channel, you can pass 1D numpy arrays for `uu`, `vv`, `weights`, `data_re`, and `data_im` and they will automatically be promoted to 2D with a leading dimension of 1 (i.e., ``nchan=1``).
"""

def __init__(
self,
uu: NDArray[floating[Any]],
vv: NDArray[floating[Any]],
weights: NDArray[floating[Any]],
data_re: NDArray[floating[Any]],
data_im: NDArray[floating[Any]],
cell_size: float | None = None,
npix: int | None = None,
device: torch.device | str | None = None,
**kwargs,
):
# ensure that all vectors are the same shape
if not all(
array.shape == uu.shape for array in [vv, weights, data_re, data_im]
):
raise WrongDimensionError("All dataset inputs must be the same shape.")

if uu.ndim == 1:
uu = np.atleast_2d(uu)
vv = np.atleast_2d(vv)
data_re = np.atleast_2d(data_re)
data_im = np.atleast_2d(data_im)
weights = np.atleast_2d(weights)

if np.any(weights <= 0.0):
raise ValueError("Not all thermal weights are positive, check inputs.")

self.nchan = uu.shape[0]
self.gridded = False

if cell_size is not None and npix is not None:
(
uu,
vv,
grid_mask,
weights,
data_re,
data_im,
) = spheroidal_gridding.grid_dataset(
uu,
vv,
weights,
data_re,
data_im,
cell_size,
npix,
)

# grid_mask (nchan, npix, npix//2 + 1) bool: a boolean array the same size as the output of the RFFT
# designed to directly index into the output to evaluate against pre-gridded visibilities.
self.grid_mask = torch.tensor(grid_mask, dtype=torch.bool, device=device)
self.cell_size = cell_size * arcsec # [radians]
self.npix = npix
self.gridded = True

self.uu = torch.tensor(uu, dtype=torch.double, device=device) # klambda
self.vv = torch.tensor(vv, dtype=torch.double, device=device) # klambda
self.weights = torch.tensor(
weights, dtype=torch.double, device=device
) # 1/Jy^2
self.re = torch.tensor(data_re, dtype=torch.double, device=device) # Jy
self.im = torch.tensor(data_im, dtype=torch.double, device=device) # Jy

# TODO: store kwargs to do something for antenna self-cal

def __getitem__(self, index: int) -> tuple[torch.Tensor, ...]:
return (
self.uu[index],
self.vv[index],
self.weights[index],
self.re[index],
self.im[index],
)

def __len__(self) -> int:
return len(self.uu)


class Dartboard:
r"""
A polar coordinate grid relative to a :class:`~mpol.coordinates.GridCoords` object, reminiscent of a dartboard layout. The main utility of this object is to support splitting a dataset along radial and azimuthal bins for k-fold cross validation.
Expand Down
Loading

0 comments on commit 2004997

Please sign in to comment.