# Copyright (c) 2024 Radio Astronomy Software Group
# Licensed under the 2-clause BSD License
"""Tests for apply_uvflag function."""
import numpy as np
import pytest
from pyuvdata import UVFlag
from pyuvdata.utils import apply_uvflag
@pytest.mark.filterwarnings("ignore:The shapes of several attributes will be changing")
@pytest.mark.filterwarnings("ignore:Fixing auto-correlations to be be real-only,")
@pytest.mark.filterwarnings("ignore:The uvw_array does not match the expected values")
def test_apply_uvflag(uvcalibrate_uvdata_oldfiles):
# load data and insert some flags
uvd = uvcalibrate_uvdata_oldfiles
uvd.flag_array[uvd.antpair2ind(9, 20)] = True
# load a UVFlag into flag type
uvf = UVFlag(uvd)
uvf.to_flag()
# insert flags for 2 out of 3 times
uvf.flag_array[uvf.antpair2ind(9, 10)[:2]] = True
# apply flags and check for basic flag propagation
uvdf = apply_uvflag(uvd, uvf, inplace=False)
assert np.all(uvdf.flag_array[uvdf.antpair2ind(9, 10)][:2])
# test inplace
uvdf = uvd.copy()
apply_uvflag(uvdf, uvf, inplace=True)
assert np.all(uvdf.flag_array[uvdf.antpair2ind(9, 10)][:2])
# test flag missing
uvf2 = uvf.select(bls=uvf.get_antpairs()[:-1], inplace=False)
uvdf = apply_uvflag(uvd, uvf2, inplace=False, flag_missing=True)
assert np.all(uvdf.flag_array[uvdf.antpair2ind(uvf.get_antpairs()[-1])])
uvdf = apply_uvflag(uvd, uvf2, inplace=False, flag_missing=False)
assert not np.any(uvdf.flag_array[uvdf.antpair2ind(uvf.get_antpairs()[-1])])
# test force polarization
uvdf = uvd.copy()
uvdf2 = uvd.copy()
uvdf2.polarization_array[0] = -6
uvdf += uvdf2
uvdf = apply_uvflag(uvdf, uvf, inplace=False, force_pol=True)
assert np.all(uvdf.flag_array[uvdf.antpair2ind(9, 10)][:2])
with pytest.raises(
ValueError, match="Input uvf and uvd polarizations do not match"
):
apply_uvflag(uvdf, uvf, inplace=False, force_pol=False)
# test unflag first
uvdf = apply_uvflag(uvd, uvf, inplace=False, unflag_first=True)
assert np.all(uvdf.flag_array[uvdf.antpair2ind(9, 10)][:2])
assert not np.any(uvdf.flag_array[uvdf.antpair2ind(9, 20)])
# convert uvf to waterfall and test
uvfw = uvf.copy()
uvfw.to_waterfall(method="or")
uvdf = apply_uvflag(uvd, uvfw, inplace=False)
assert np.all(uvdf.flag_array[uvdf.antpair2ind(9, 10)][:2])
assert np.all(uvdf.flag_array[uvdf.antpair2ind(9, 20)][:2])
assert np.all(uvdf.flag_array[uvdf.antpair2ind(20, 22)][:2])
# test mode exception
uvfm = uvf.copy()
uvfm.mode = "metric"
with pytest.raises(ValueError, match="UVFlag must be flag mode"):
apply_uvflag(uvd, uvfm)
# test polarization exception
uvd2 = uvd.copy()
uvd2.polarization_array[0] = -6
uvf2 = UVFlag(uvd)
uvf2.to_flag()
uvd2.polarization_array[0] = -8
with pytest.raises(
ValueError, match="Input uvf and uvd polarizations do not match"
):
apply_uvflag(uvd2, uvf2, force_pol=False)
# test time and frequency mismatch exceptions
uvf2 = uvf.select(frequencies=uvf.freq_array[:2], inplace=False)
with pytest.raises(
ValueError, match="UVFlag and UVData have mismatched frequency arrays"
):
apply_uvflag(uvd, uvf2)
uvf2 = uvf.copy()
uvf2.freq_array += 1.0
with pytest.raises(
ValueError, match="UVFlag and UVData have mismatched frequency arrays"
):
apply_uvflag(uvd, uvf2)
uvf2 = uvf.select(times=np.unique(uvf.time_array)[:2], inplace=False)
with pytest.raises(
ValueError, match="UVFlag and UVData have mismatched time arrays"
):
apply_uvflag(uvd, uvf2)
uvf2 = uvf.copy()
uvf2.time_array += 1.0
with pytest.raises(
ValueError, match="UVFlag and UVData have mismatched time arrays"
):
apply_uvflag(uvd, uvf2)
# assert implicit broadcasting works
uvf2 = uvf.select(frequencies=uvf.freq_array[:1], inplace=False)
uvd2 = apply_uvflag(uvd, uvf2, inplace=False)
assert np.all(uvd2.get_flags(9, 10)[:2])
uvf2 = uvf.select(times=np.unique(uvf.time_array)[:1], inplace=False)
uvd2 = apply_uvflag(uvd, uvf2, inplace=False)
assert np.all(uvd2.get_flags(9, 10))
